СПОСОБ РАБОТЫ ТОПЛИВНОЙ ФОРСУНКИ

Изобретение может быть использовано в системах топливоподачи двигателей внутреннего сгорания. В одном примере система топливной форсунки включает в себя иглу 205 форсунки со штифтом 210 форсунки с криволинейным топливным каналом 204 неравномерной ширины по внешней окружности штифта 210 форсунки, гидравлически соединенным по длине криволинейного топливного канала 204 с топливной емкостью 212 внутри штифта форсунки. Привод 202, соединенный с иглой 205 форсунки, может последовательно перемещать и позиционировать иглу 205 форсунки так, чтобы устанавливать гидравлическое соединение между криволинейным топливным каналом 204 и одним или более сопловыми отверстиями 230-245 топливной форсунки в каждом положении. Продолжительность гидравлического соединения в каждом положении основана на ширине криволинейного топливного канала и может определять объем топлива, выпускаемого только из этих сопловых отверстий, тем самым уменьшая взаимодействие струи топлива и увеличивая степень распыливания струи топлива ...

УПРАВЛЯЮЩЕЕ УСТРОЙСТВО ДЛЯ ДВИГАТЕЛЕЙ С НАДДУВОМ

Изобретение может быть использовано в управляющих устройствах для управления величиной требуемого крутящего момента в двигателях внутреннего сгорания с наддувом. Управляющее устройство (100) для двигателя с наддувом выполнено с возможностью управления приводным устройством впускного клапана двигателя, позволяющим изменять выбор момента для закрытия впускного клапана, дроссельной заслонкой этого двигателя и воздушным нагнетателем этого двигателя. Управляющее устройство (100) содержит блок (110) расчета целевого количества воздуха в цилиндре, блок расчета целевого количества воздуха, проходящего через впускной клапан, блок определения рабочего параметра приводного устройства впускного клапана и блок определения рабочего параметра дроссельной заслонки (10). Блок (110) расчета целевого количества воздуха в цилиндре рассчитывает количество воздуха, необходимого для реализации требуемой величины крутящего момента. Блок расчета целевого количества воздуха, проходящего через впускной клапан, рассчитывает ...

СПОСОБ РАБОТЫ ДВИГАТЕЛЯ С НАДДУВОМ (ВАРИАНТЫ) И СИСТЕМА ДВИГАТЕЛЯ

Изобретение относится к системам и способам для улучшения продувки топливных паров из адсорбера топливных паров. Предлагаются системы и способы для управления операцией продувки адсорбера топливных паров в двигателе с наддувом. Один способ содержит продувку накопленных топливных паров из адсорбера (122) топливных паров на вход компрессора (114) через эжектор (180) при обходе продувочного клапана (164) адсорбера, при этом эжектор соединен по текучей среде с адсорбером топливных паров посредством отдельного канала (121), установленного выше по потоку от продувочного клапана адсорбера, при этом эжектирующий поток через эжектор может регулироваться посредством отсечного клапана (185). Отсечной клапан может регулироваться на основе того, работает двигатель с наддувом или нет. Технический результат – улучшение продувки топливных паров из адсорбера топливных паров. 3 н. и 17 з.п. ф-лы, 7 ил.

СПОСОБ И УСТРОЙСТВО ДЛЯ ПОЛУЧЕНИЯ ВЫСОТНОЙ ПОПРАВКИ

Изобретение относится к автомобилям и, более конкретно, к способу и устройству для определения высотной поправки. Технический результат заключается в обеспечении точности определения высотной поправки для электронного блока управления с учетом сложных реальных условий движения автомобиля. Предложен способ получения высотной поправки, включающий: получение начальной величины самонастраивающегося фильтра для получения высотной поправки, когда в двигателе транспортного средства происходит заданное событие, включающее выключение мощности, включение мощности и неожидаемое падение мощности; оценку выполнения транспортным средством заданного условия включения режима самонастройки в соответствии с числом оборотов двигателя, скоростью транспортного средства и информацией о состоянии заданных устройств; включение самонастраивающегося фильтра для получения высотной поправки, когда транспортным средством выполняется заданное условие включения режима самонастройки; определение входной величины самонастраивающегося ...

СПОСОБ (ВАРИАНТЫ) И СИСТЕМА ДЛЯ ОЦЕНКИ ВНЕШНЕГО ДАВЛЕНИЯ ПРИ ПОМОЩИ КИСЛОРОДНОГО ДАТЧИКА

Изобретение относится к способам и системам для использования зависимости показаний кислородного датчика от давления для оценки внешнего давления для двигателя. Впускной или выпускной кислородный датчик используют для оценки внешнего давления посредством приложения опорного напряжения к датчику в период, когда частота вращения двигателя в гибридном автомобиле уменьшается, и корректируют показания датчика для компенсации эффектов разбавления вследствие влажности окружающей среды. Значение оцененного внешнего давления используют для исправления или подтверждения значения давления, оцененного при помощи других источников данных, таких как другие датчики давления или модель давления, а также используют для настройки производительности двигателя. 3 н. и 17 з.п. ф-лы, 6 ил.

СПОСОБ И СИСТЕМА ДЛЯ ВПРЫСКА ВОДЫ В ДВИГАТЕЛЬ

Изобретение может быть использовано в двигателях внутреннего сгорания. Предлагаются способы для достоверной самодиагностики системы впрыска воды, производящей впрыск воды в двигатель в соответствии с условиями работы двигателя, такими как детонация, причем систему впрыска воды наполняют вручную или путем сбора воды на борту транспортного средства. По ошибке впрыска воды, определенной по изменению заданного набора параметров работы двигателя во время линейного изменения впрыска воды при выбранных условиях работы, может быть выявлено наличие закупоривания в водяном тракте. Последующий впрыск воды может быть скорректирован соответствующим образом в зависимости от степени закупоривания. Изобретение позволяет повысить достоверность выявления неисправности (например, закупоривания) в системе подачи воды, что способствует повышению точности регулирования впрыска воды в двигатель, улучшению эксплуатационных показателей двигателя и снижению вероятности возникновения неисправности в двигателе из-за ...

ОЦЕНИВАНИЕ ТЕМПЕРАТУРЫ ЭЛЕКТРИЧЕСКОГО ПРИВОДА

Изобретение может быть использовано в двигателях внутреннего сгорания с наддувом. Способ управления приводом электрической перепускной заслонки (26) турбонагнетателя в двигателе (10) внутреннего сгорания, имеющем контроллер (12), снабженный компьютерно-читаемым носителем (106), заключается в том, что определяют требуемое положение перепускной заслонки (26) посредством контроллера (12). Настраивают электродвигатель (150) в ответ на требуемое положение перепускной заслонки (26), определенное посредством контроллера (12). При настройке электродвигатель (150) дополнительно реагирует на любое одно из определения во время выбранных условий, отклонения перепускной заслонки (26) от требуемого положения посредством по меньшей мере одного полного полуоборота электродвигателя (150), и указания температуры электродвигателя (150), определенной на основании сопротивления обмотки, усредненного за полные пол-оборота во время отклонения посредством контроллера (12). Раскрыты варианты способа управления ...

СПОСОБ ДИАГНОСТИКИ РАБОТЫ ПРОДУВОЧНОГО ВЕНТИЛЯ ФИЛЬТРА ТОПЛИВНЫХ ПАРОВ

Объектом изобретения является способ диагностики работы продувочного вентиля фильтра топливных паров двигателя внутреннего сгорания, при этом указанный способ, осуществляемый во время продувки, содержит следующие этапы, на которых: а) обнаруживают в момент t0, что продувочный вентиль открыт, b) осуществляют в момент t2 принудительное закрывание указанного вентиля, с) измеряют давление P1m во впускном коллекторе и вычисляют соответствующее моделированное давление P1с в момент t1 между моментом t0 и моментом t2, d) измеряют давление коллектора P2m и вычисляют соответствующее моделированное давление P2с в момент t3 после момента t2, е) вычисляют отклонение Е1 между P1m и P1с и вычисляют отклонение Е2 между P2m и P2с, f) вычисляют критерий С = Е1 - Е2, g) диагностируют нарушение работы указанного продувочного вентиля, если критерий С меньше заранее определенного порогового значения Cs. 2 н. и 11 з.п. ф-лы, 2 ил.

Система и способ (варианты) для эксплуатации топливоподкачивающего насоса

Изобретение может быть использовано в системах топливоподачи двигателей внутреннего сгорания. Предложены способы и системы для эксплуатации топливоподкачивающего насоса топливной системы двигателя. В одном примере способа, при включении питания топливоподкачивающего насоса из выключенного состояния, ограничивают напряжение топливоподкачивающего насоса до нижнего первого уровня. Согласно способу поддерживают напряжение топливоподкачивающего насоса на нижнем первом уровне в течение некоторого периода времени перед тем, как повысить напряжение топливоподкачивающего насоса выше первого уровня. Изобретение позволяет уменьшить скачки напряжения при включении топливоподкачивающего насоса, а также уменьшить скачки давления в топливной рампе и ведущей к ней топливной линии и ошибки дозирования топлива за счет постепенного повышения давления топлива в топливных линиях, что способствует улучшению эксплуатационных показателей двигателя. 3 н. и 17 з.п. ф-лы, 9 ил.

СПОСОБ ЭКСПЛУАТАЦИИ ДВИГАТЕЛЯ (ВАРИАНТЫ)

Изобретение может быть использовано в системах управления двигателем внутреннего сгорания. Предложены способы эксплуатации двигателя, согласно которым при работе двигателя, в зависимости от запроса на включение впрыска газообразного топлива, задерживают включение впрыска газообразного топлива до тех пор, пока давление во впускном воздушном коллекторе не достигнет определенного порогового значения, и затем включают впрыск газообразного топлива, когда давление во впускном воздушном коллекторе достигнет порогового значения. С помощью предложенных способов достигается снижение перепада давлений на газовой форсунке между давлением в газовой топливной рампе и давлением во впускном воздушном коллекторе, что необходимо для обеспечения стабильного открытия газовой форсунки без увеличения напряжения, подаваемого на газовую форсунку. Изобретение позволяет обеспечить стабильность работы газовой форсунки и, таким образом, достижение необходимых эксплуатационных характеристик двигателя. 2 н. и 8 з.п.

СПОСОБ УПРАВЛЕНИЯ ВОССТАНОВЛЕНИЕМ ДИЗЕЛЬНОГО САЖЕВОГО ФИЛЬТРА (ДСФ) В СИСТЕМЕ ДИЗЕЛЬНОГО ДВИГАТЕЛЯ

Предложен способ восстановления дизельного сажевого фильтра (ДСФ) в системе дизельного двигателя, который имеет линию всасывания и линию вывода и рассчитан на подвпрыск или вторичный впрыск определенных количеств топлива в камеру сгорания для повышения температуры выхлопных газов двигателя, при этом на упомянутой линии вывода двигателя расположен дизельный сажевый фильтр (ДСФ), включающий стадии, на которых выявляют неисправное состояние системы двигателя и, если такое неисправное состояние не является опасным, измеряют заряд всасываемого воздуха и, если такой заряд всасываемого воздуха является приемлемым, осуществляют процесс восстановление упомянутого дизельного сажевого фильтра (ДСФ). Техническим результатом является уменьшение числа отказов, частоты замены фильтра. 2 н. и 2 з.п. ф-лы, 1 ил.

УСТРОЙСТВО ДЛЯ ОБЕСПЕЧЕНИЯ ПРИТОЧНЫМ ГАЗОМ ПОРШНЕВОГО ДВИГАТЕЛЯ ВНУТРЕННЕГО СГОРАНИЯ С ТУРБОНАДДУВОМ

Изобретение относится к двигателестроению, в частности к устройствам для обеспечения приточным газом для поршневого двигателя. Изобретение позволяет создать устройство для обеспечения приточным газом двигателей внутреннего сгорания с турбонаддувом, которое выполнено в виде отдельного модуля с соответствующими присоединениями, и может быть оптимально оборудовано трубопроводными средствами для приточного газа. Устройство для обеспечения приточным газом для поршневого двигателя внутреннего сгорания с турбонаддувом включает присоединение для сжатого воздуха с устройством для регулирования количества, выходящее сбоку в имеющую форму трубы внутреннюю полость, а также расположенную во внутренней полости с возможностью регулирования заслонку для регулирования потока, причем внутренняя полость ограничена от наддувочного воздуха турбокомпрессора, работающего на отработавших газах первым концевым присоединением для впуска и торцевым концевым присоединением для выпуска. Трубопроводные средства для ...

СПОСОБ (ВАРИАНТЫ) УПРАВЛЕНИЯ ДАВЛЕНИЕМ НАДДУВА В ДВИГАТЕЛЕ И СИСТЕМА ДВИГАТЕЛЯ

Изобретение может быть использовано в двигателях внутреннего сгорания с наддувом. Способ для двигателя (10) с наддувом заключается в том, что осуществляют обход первого компрессора (110), расположенного выше по потоку, и направляют поток сжатого воздуха к поршневому двигателю (10) через второй компрессор (114), расположенный ниже по потоку. В качестве реакции на перерегулирование давления наддува, регулируют частоту вращения первого компрессора (110). Раскрыты вариант способа для двигателя с наддувом и система двигателя. Технический результат заключается в ускорении регулирования давления наддувочного воздуха и в уменьшении избыточной выработки крутящего момента двигателя. 3 н. и 17 з.п. ф-лы, 5 ил.

СПОСОБ И УСТРОЙСТВО ДЛЯ РЕГУЛИРОВАНИЯ ДАВЛЕНИЯ НАДДУВА В ДВИГАТЕЛЕ ВНУТРЕННЕГО СГОРАНИЯ С НАГНЕТАТЕЛЕМ СИСТЕМЫ ВОЛНОВОГО НАДДУВА

Предложены способ и устройство для регулирования давления наддува в двигателе (39) внутреннего сгорания с нагнетателем (1) системы волнового наддува, при котором нагнетатель (1) системы волнового наддува имеет ячеистый ротор (8), проходящий за один оборот по меньшей мере два цикла компрессии, причем поток (4с) отходящих газов высокого давления разделяют на первый и второй частичные потоки (4d, 4е) отходящих газов высокого давления, причем в первом цикле компрессии к ячеистому ротору (8) подводят поток (2с) свежего воздуха, а также первый частичный поток (4d) отходящих газов высокого давления и отводят от ячеистого ротора (8) первый поток (3с) сжатого свежего воздуха и поток (5е) отходящих газов низкого давления, а во втором цикле компрессии к ячеистому ротору (8) подводят поток (2с) свежего воздуха, а также второй частичный поток (4е) отходящих газов высокого давления и отводят от ячеистого ротора (8) второй поток (3d) сжатого свежего воздуха и поток (5е) отходящих газов низкого давления ...

ТРАНСПОРТНОЕ СРЕДСТВО, УПРАВЛЯЮЩЕЕ УСТРОЙСТВО И СПОСОБ УПРАВЛЕНИЯ ФАЗОВЫМ ПОЛОЖЕНИЕМ КУЛАЧКОВОГО РАСПРЕДЕЛИТЕЛЬНОГО ВАЛА

Изобретение относится к двигателю внутреннего сгорания, в частности к управляющему устройству для управления фазовым положением кулачкового распределительного вала. Технический результат заключается в повышении эффективности управления фазовым положением кулачкового распределительного вала. Предложено управляющее устройство (SG) для управления фазовым положением первого кулачкового распределительного вала двигателя внутреннего сгорания, содержащее: первый датчик (KG1) параметрической поверхности для определения динамического заданного фазового положения (dSP1) первого кулачкового распределительного вала; второй датчик (KG2) параметрической поверхности для определения статического заданного фазового положения (sSP1) первого кулачкового распределительного вала; и первый интерполятор (IP1) для определения исправленного заданного фазового положения (kSP1) первого кулачкового распределительного вала на основании определяемого первым датчиком (KG1) параметрической поверхности динамического заданного ...

СИСТЕМА УПРАВЛЕНИЯ КЛАПАНОМ РЕГУЛЯТОРА ДАВЛЕНИЯ НАДДУВА

... 1. Система управления клапаном регулятора давления наддува, содержащая:модуль обратной связи, содержащий первый внешний контур, причем приводимый в действие, если нет в распоряжении обратной связи с датчика клапана регулятора давления наддува, причем модуль обратной связи выполнен с возможностью приема разности между требуемым давлением на впуске дросселя и фактическим давлением на впуске дросселя, и с возможностью вывода ошибки рабочего цикла;модуль прямой связи, выполненный с возможностью формирования рабочего цикла на основании требуемого давления на впуске дросселя; иблок суммирования, выполненный с возможностью формирования скорректированного рабочего цикла на основании разницы между рабочим циклом и ошибкой рабочего цикла, при этом скорректированный рабочий цикл отправляется на привод, функционально присоединенный к клапану регулятора давления наддува.2. Система по п. 1, в которой модуль обратной связи содержит второй внешний контур и внутренний контур, причем второй внешний контур ...

ЭЛЕКТРОННАЯ СИСТЕМА ВПРЫСКА ТОПЛИВА ДЛЯ ДВИГАТЕЛЯ С ВОСПЛАМЕНЕНИЕМ ОТ СЖАТИЯ И БЛОЧНЫЙ СИЛОВОЙ УЗЕЛ

Электронная система впрыска топлива для обеспечения переменного регулирования впрыска для двигателя с воспламенением от сжатия, имеющего рабочий объем каждого цилиндра по крайней мере 5,5 л, содержит индивидуальные механизмы подачи топлива, как, например, топливный насос, имеющий камеру нагнетания топлива постоянного объема, и топливные форсунки для каждого соответствующего цилиндра, а также имеется генератор регулирующего сигнала, например многоканальное оптическое кодирующее устройство, соединенное с кулачковым валом, для выработки регулирующего сигнала и индекс-сигнала цилиндра. Изобретение содержит также электронное регулирующее устройство, например большое число индивидуальных контроллеров, реагирующих на входные сигналы различных датчиков, к которым относятся регулирующий сигнал и индекс-сигнал цилиндра для электронного управления индивидуальными механизмами подачи топлива. Последние срабатывают на выходные сигналы от контроллера и обеспечивают объемный расход топлива в диапазоне ...

СПОСОБ И СИСТЕМА ДЛЯ УПРАВЛЕНИЯ ЗАПУСКОМ ДВИГАТЕЛЯ ВНУТРЕННЕГО СГОРАНИЯ

Изобретение относится к системам управления запуском двигателей внутреннего сгорания. Технический результат - обеспечение дроссельного регулирования путем создания отрицательного давления на впуске при одновременной подаче соответствующего объема всасываемого воздуха. Двигатель внутреннего сгорания имеет дроссель для управления объемом всасываемого воздуха и выполняет запуск через проворачивание. Переключатель стартера определяет инициирование проворачивания, и датчик угла поворота коленчатого вала определяет число оборотов двигателя. Контроллер приводит в действие дроссель в закрытой позиции наряду с инициированием проворачивания. Контроллер может получать как отрицательное давление на впуске для стимуляции испарения топлива, так и объем всасываемого воздуха, необходимый для того, чтобы поддерживать частоту вращения на холостом ходу, посредством подсчета числа тактов или числа оборотов двигателя внутреннего сгорания от инициирования проворачивания и открытия дросселя из закрытой позиции ...

СИСТЕМА И СПОСОБ УПРАВЛЕНИЯ ВПРЫСКОМ ТОПЛИВА В ДВИГАТЕЛЕ ВНУТРЕННЕГО СГОРАНИЯ

... 1. Система впрыска топлива под высоким давлением для управления впрыском топлива в двигателе внутреннего сгорания, имеющем блок цилиндров с одним или более цилиндров, в которые впрыскивается топливо, при этом система впрыска топлива содержит: ! топливный насос высокого давления, сообщающийся по текучей среде с топливным баком; ! топливный аккумулятор, сообщающийся по текучей среде с топливным насосом высокого давления; ! одну или более форсунок, сообщающихся по текучей среде с топливным аккумулятором, при этом каждая из топливных форсунок сообщается по текучей среде с соответствующим цилиндром, в котором удерживается поршень; ! при этом одна или более форсунок имеют клапан, который открывается или закрывается в зависимости от электрических импульсов; ! устройство управления, электрически связанное с одной или более форсунок и топливным насосом высокого давления, генерирующее один или более первых сигналов, в зависимости от которых клапан в форсунке открывается или закрывается, и один или ...

ОЦЕНИВАНИЕ ТЕМПЕРАТУРЫ ЭЛЕКТРИЧЕСКОГО ПРИВОДА

... 1. Способ, состоящий в том, что:настройку электродвигателя для расположения перепускной заслонки для отработавших газов в требуемом положении перепускной заслонки для отработавших газов, тогда как, во время выбранных условий, отклонение от требуемого положения на по меньшей мере один полный полуоборот двигателя и указание температуры двигателя на основании сопротивления обмотки, усредненного за полные пол-оборота.2. Способ по п. 1, дополнительно состоящий в том, что компенсируют изменение наддува, обусловленное отклонением, посредством настройки впускного дросселя.3. Способ по п. 1, в котором выбранные условия включают в себя максимальный наддув, при котором перепускная заслонка для отработавших газов установлена в полностью закрытом положении.4. Способ по п. 1, в котором выбранные условия включают в себя минимальный наддув, при котором перепускная заслонка для отработавших газов установлена в полностью открытом положении.5. Способ по п. 1, в котором, во время выбранных условий, требуемое ...

СПОСОБ ОПРЕДЕЛЕНИЯ СТЕПЕНИ ПОДАЧИ ВЫХЛОПНЫХ ГАЗОВ, РЕЦИРКУЛИРУЕМЫХ НА ВХОД ЦИЛИНДРА ДВИГАТЕЛЯ ВНУТРЕННЕГО СГОРАНИЯ, И ДВИГАТЕЛЬ, В КОТОРОМ ПРИМЕНЯЮТ УКАЗАННЫЙ СПОСОБ

... 1. Способ определения степени подачи рециркулируемых выхлопных газов EGR (txegr_cyl(t)), на входе цилиндра (10) двигателя внутреннего сгорания в момент t, при этом указанные выхлопные газы направляют в рециркуляционный канал (14), соединяющий выхлопную магистраль двигателя (200) с его впускной магистралью (100), при этом указанная степень подачи EGR равна соотношению между расходом рециркулируемых выхлопных газов и общим расходом газов во впускной магистрали (100) в заданной точке впускной магистрали (100) и в рассматриваемый момент, согласно которому:a) определяют в какой момент http://t_int.ro, предшествующий моменту t, газ, который поступает на вход цилиндра в момент t, был введен во впускную магистраль (100),b) определяют степень подачи EGR (txegr_adm(t_intro)) на выходе рециркуляционного трубопровода (14) во впускную магистраль (100) в момент http://t_int.ro,c) определяют степень подачи EGR (txegr_cyl(t)) на входе цилиндра (10) в момент t в зависимости от степени подачи EGR (txegr_adm ...

СПОСОБ И СИСТЕМА (ВАРИАНТЫ) РЕГУЛИРОВАНИЯ ТЕМПЕРАТУРЫ УСТРОЙСТВА СОЗДАНИЯ ДАВЛЕНИЯ НАДДУВА ТРАНСПОРТНОГО СРЕДСТВА И ТРАНСПОРТНОЕ СРЕДСТВО, СОДЕРЖАЩЕЕ ТАКУЮ СИСТЕМУ

Способ и система регулирования температуры устройства создания давления наддува для транспортного средства, при этом способ содержит: определение температурного сдвига ΔΤ, на который может быть повышен предварительно определенный предел Tрабочей температуры устройства создания давления наддува, причем температурный сдвиг ΔΤ является функцией предварительно определенного максимального температурного сдвига ∆Tи динамического коэффициента SF пересчета. 3 н. и 12 з.п. ф-лы, 5 ил.

СПОСОБ И УСТРОЙСТВО ДЛЯ РЕГУЛИРОВАНИЯ МОМЕНТА ЗАЖИГАНИЯ

... 1. Устройство для регулирования момента зажигания двигателя, содержащее: счетно-решающий прибор для расчета момента зажигания, используемый для добавления переменной составляющей к заданному моменту зажигания и расчета конечного момента зажигания двигателя; счетно-решающий прибор для расчета среднего эффективного давления, который используется для расчета среднего эффективного давления в цилиндре, регистрируемого в момент конечного зажигания; МВТ счетно-решающий прибор для получения характеристической кривой момента зажигания, которая определяет связь между средним эффективным давлением и переменной составляющей, и определения оптимального момента зажигания по характеристической кривой; и контроллер для регулирования заданного момента зажигания и обеспечения сходимости заданного момента зажигания к оптимальному моменту зажигания. 2. Устройство по п.1, в котором характеристическая кривая выражается функцией, имеющей в качестве входного параметра переменную составляющую и в качестве выходного ...

ОБЩИЙ ЗАПОРНЫЙ КЛАПАН ДЛЯ ВАКУУМНОГО ПРИВОДА ПРИ НИЗКИХ НАГРУЗКАХ ДВИГАТЕЛЯ И ВАКУУМА ПРОДУВКИ ТОПЛИВНЫХ ПАРОВ ПРИ ФОРСИРОВАНИИ ДВИГАТЕЛЯ

СИСТЕМА РЕЦИРКУЛЯЦИИ ВЫХЛОПНЫХ ГАЗОВ

... 1. Система для рециркуляции выхлопных газов, которая включает в себя впускной коллектор, канал рециркуляции выхлопных газов, соединенный с впускным коллектором, который имеет клапан рециркуляции выхлопных газов, а также корпус датчика, соединенный непосредственно с впускным коллектором и имеющий чувствительный элемент для измерения абсолютного давления и чувствительный элемент для измерения дифференциального давления, которые имеют общее соединение с впускным коллектором.2. Система по п. 1, которая дополнительно содержит диафрагму, которая расположена ниже по потоку от клапана, причем чувствительный элемент для измерения дифференциального давления соединен с областью выше по потоку от диафрагмы с помощью отдельного соединения, где общее соединение включает в себя внутренний коллектор, расположенный внутри корпуса датчика, соединяющего чувствительный элемент для измерения абсолютного давления с чувствительным элементом для измерения дифференциального давления, а внутренний коллектор имеет ...

СПОСОБ ДИАГНОСТИКИ ВАКУУМНОГО ПРИВОДА

СПОСОБ И СИСТЕМА ДЛЯ ОЦЕНКИ ЗАРЯДА ВОЗДУХА

Способ (варианты) и система для оценки давления отработавших газов с помощью датчика кислорода с переменным напряжением

СПОСОБ ОЦЕНКИ КОНЦЕНТРАЦИИ КИСЛОРОДА В ДВИГАТЕЛЯХ ВНУТРЕННЕГО СГОРАНИЯ

... 1. Способ оценки концентрации кислорода в двигателе внутреннего сгорания, содержащем впускной коллектор, выхлопной коллектор, систему рециркуляции выхлопных газов (РВГ), дроссельный клапан, датчик массы воздуха для измерения потока свежего воздуха (), входящего во впускной коллектор через дроссельный клапан, множество цилиндров, причем способ отличается тем, что: ! оценивают полный поток газа (), входящий в цилиндры; ! вычисляют поток газа РВГ (); ! вычисляют долю воздуха (f_air_em) в газе, протекающем в выхлопном коллекторе; ! вычисляют массу воздуха (mim_air), входящего в цилиндры, на основе доли воздуха (f_air_em) в выхлопном коллекторе, полного потока газа (), входящего в цилиндры, потока газа РВГ () и потока свежего воздуха (); ! вычисляют полную массу (mim) во впускном коллекторе на основе потока свежего воздуха (), потока газа РВГ () и полного потока газа (), входящего в цилиндры; ! вычисляют долю воздуха (fair_im) во впускном коллекторе на основе массы воздуха (mim_air), входящего ...

СПОСОБ И УСТРОЙСТВО ДЛЯ УПРАВЛЕНИЯ СИСТЕМОЙ ПРИВОДА ТРАНСПОРТНОГО СРЕДСТВА С ИМЕЮЩИМ НАДДУВ ДВИГАТЕЛЕМ ВНУТРЕННЕГО СГОРАНИЯ

СИСИТЕМА И СПОСОБ ДЛЯ УЛУЧШЕНИЯ ОТКЛЮЧЕНИЯ ЦИЛИНДРОВ

Способ работы двигателя в сборе

СПОСОБ (ВАРИАНТЫ) И СИСТЕМА КОНТРОЛЯ ПРЕЖДЕВРЕМЕННОГО ЗАЖИГАНИЯ

СИСТЕМА И СПОСОБ (ВАРИАНТЫ) ЭКСПЛУАТАЦИИ ЛАЗЕРНОГО ДАТЧИКА ДАВЛЕНИЯ

СПОСОБ (ВАРИАНТЫ) И СИСТЕМА ДЛЯ РЕГУЛИРОВАНИЯ ВПРЫСКА ВОДЫ В ДВИГАТЕЛЬ

СПОСОБ ОПРЕДЕЛЕНИЯ РАСХОДА ВОЗДУХА НА ВХОДЕ В ДВИГАТЕЛЬ ВНУТРЕННЕГО СГОРАНИЯ И ДВИГАТЕЛЬ ВНУТРЕННЕГО СГОРАНИЯ

... 1. Способ определения расхода воздуха на входе в двигатель внутреннего сгорания, оснащенный системой впуска воздуха, причем указанная система содержит клапанные средства для регулирования указанного расхода воздуха, отличающийся тем, что включает следующие стадии: ! реализация первого и второго алгоритмов для определения соответственно первого и второго значений расхода воздуха на входе в указанный двигатель и ! выбор первого или второго значения расхода воздуха на основании предварительно установленного критерия выбора. ! 2. Способ по п.1, отличающийся тем, что выбор первого или второго значения расхода воздуха выполняют на основании давления воздуха на входе клапанных средств и давления воздуха на выходе клапанных средств. ! 3. Способ по п.2, отличающийся тем, что выбор первого или второго значения расхода воздуха выполняют на основании соотношения между давлениями на входе и на выходе клапанных средств. ! 4. Способ по п.3, отличающийся тем, что выбор первого или второго значения расхода ...

СПОСОБ И СИСТЕМА ДЛЯ СМЯГЧЕНИЯ ПОСЛЕДСТВИЙ НЕИСПРАВНОСТИ ДРОССЕЛЯ

СПОСОБ ДИАГНОСТИКИ НЕИСПРАВНОСТЕЙ РЕГУЛЯТОРА ДАВЛЕНИЯ ОТРАБОТАВШИХ ГАЗОВ И СООТВЕТСТВУЮЩЕЕ УСТРОЙСТВО ДИАГНОСТИКИ

... 1. Способ диагностики неисправностей регулятора давления отработавших газов, обеспечиваемого в системе отработавших газов, соединенной с двигателем внутреннего сгорания с турбонаддувом, включающий:а) задание торможения двигателем;б) измерение обратного давления в системе отработавших газов с помощью датчика обратного давления при задании торможения двигателем;в) измерение давления наддува с помощью датчика давления наддува при задании торможения двигателем;г) сравнение измеренного обратного давления и измеренного давления наддува с хранящимися значениями обратного давления и давления наддува для определения неисправности регулятора давления или датчика обратного давления.2. Способ диагностики по п.1, в котором датчик обратного давления устанавливают между регулятором давления отработавших газов и турбоагрегатом.3. Способ диагностики по п.1, в котором датчик обратного давления устанавливают в коллекторе отработавших газов, по потоку выше турбоагрегата.4. Способ диагностики по п.1, в котором ...

СПОСОБЫ ДЛЯ ДВИГАТЕЛЯ, ВКЛЮЧАЮЩЕГО В СЕБЯ ИЗБИРАТЕЛЬНО ВЫВОДИМЫЙ ИЗ РАБОТЫ ЦИЛИНДР, И СООТВЕТСТВУЮЩАЯ СИСТЕМА

... 1. Способ для двигателя, включающего в себя избирательно выводимый из работы цилиндр, содержащий этап, на котором:уменьшают количество топлива, впрыскиваемого форсункой впрыска во впускной канал, при этом увеличивают количество топлива, впрыскиваемого форсункой непосредственного впрыска, перед выводом из работы цилиндра.2. Способ по п. 1, в котором количество топлива, впрыскиваемого форсункой впрыска во впускной канал, является по существу нулевым.3. Способ по п. 2, дополнительно содержащий этап, на котором прекращают топливоснабжение через форсунку непосредственного впрыска, когда величина лужицы топлива во впускном канале цилиндра полностью израсходована.4. Способ по п. 3, в котором величина лужицы топлива во впускном канале цилиндра оценивается на основании одного или более из потока воздуха, количества топлива, впрыскиваемого форсункой впрыска во впускной канал цилиндра, давления во впускном коллекторе и температуры впускного коллектора.5. Способ по п. 3, дополнительно содержащий этап ...

ДВИГАТЕЛЬ ВНУТРЕННЕГО СГОРАНИЯ, В ЧАСТНОСТИ ГАЗОВЫЙ ДВИГАТЕЛЬ, ДЛЯ ТРАНСПОРТНОГО СРЕДСТВА

... 1. Двигатель внутреннего сгорания для транспортного средства, содержащийрасположенный в подводе массового потока воздуха по потоку перед устройством (8) для подмешивания топлива охладитель (6) наддувочного воздуха, иизмерительное устройство для определения массового потока (3) воздуха,отличающийся тем, чтоизмерительное устройство имеет систему датчиков (19, 20) для измерения потери давления в охладителе (6) наддувочного воздуха иизмерительное устройство содержит дополнительно вычислительный блок (21) в качестве оценочного блока, с помощью которого в хранящейся в нем модели охладителя наддувочного воздуха, в которой охладитель (6) наддувочного воздуха образует геометрически постоянный дроссель для проходящего массового потока (3) воздуха, по меньшей мере из измеренной с помощью системы датчиков (19, 20) потери давления обеспечивается возможность вычисления массового потока (3) воздуха.2. Двигатель внутреннего сгорания по п. 1, отличающийся тем, что система датчиков для измерения потери давления ...

Steuerungsvorrichtung für eine Brennkraftmaschine mit einem variablen Ventiltrieb zur Veränderung der Öffnungs- und Schließcharakteristik des Einlassventils und/oder Auslassventils

Steuerungsvorrichtung für eine Brennkraftmaschine (10), mit: einem variablen Ventiltrieb (38, 42) zum Öffnen und Schließen wenigstens eines Einlassventils (36) oder eines Auslassventils (40), und einem Ansaugsteuerungsmechanismus (22) zum Steuern des Ansaugluftvolumens (GA), das in eine Ansaugleitung strömt, und eine Steuereinrichtung (50) zum Steuern des variablen Ventiltriebs (38, 42) so, dass das Moment der Brennkraftmaschine (10) ansteigt, wenn die Brennkraftmaschinendrehzahl (NE) unter eine gewünschte Drehzahl fällt, dadurch gekennzeichnet, dass die Steuereinrichtung (50) den Ansaugsteuerungsmechanismus (22) so steuert, dass das Ansaugluftvolumen (GA) zunimmt, wenn die Brennkraftmaschinendrehzahl (NE) unter die gewünschte Drehzahl fällt und gleichzeitig der Ansaugleitungsdruck (PM) gleich oder kleiner ist als ein vorgegebener Druck (α).

VERFAHREN ZUR STEUERUNG EINER BRENNKRAFTMASCHINE MIT DIREKTEINSPRITZUNG

Verfahren und Vorrichtung zur Bestimmung einer Zylinderluftladung für eine Brennkraftmaschine

Ein Verfahren zum Schätzen einer Zylinderluftladung für eine Brennkraftmaschine umfasst, dass ein erster volumetrischer Wirkungsgrad bestimmt wird, die einem Kraftmaschinenbetrieb mit einem geöffneten Abgasrückführungsventil entspricht, dass ein zweiter volumetrischer Wirkungsgrad bestimmt wird, die einem Kraftmaschinenbetrieb mit einem geschlossenen Abgasrückführungsventil entspricht, und dass eine Zylinderluftladung unter Verwendung eines gewählten aus den ersten und zweiten volumetrischen Wirkungsgraden bestimmt wird.

Kraftstoffzufuhrsystem für eine Brennkraftmaschine

Kraftstoffdampfzufuhrsystem, das zum Zuführen von Kraftstoffdampf zu einer Brennkraftmaschine mit innerer Verbrennung (E) mit einem Ansaugkanal (21, 22, 23, 24) ausgebildet ist, mit:einem Behälter (30), der zum Speichern des Kraftstoffdampfs ausgebildet ist;einem Spülkanal (36), der sich von dem Behälter (30) zu dem Ansaugkanal (21, 22, 23, 24) der Brennkraftmaschine mit innerer Verbrennung (E) erstreckt, wobei der Spülkanal (36) ein Strömen des in dem Behälter (30) gespeicherten Kraftstoffdampfs durch den Spülkanal (36) zu der Brennkraftmaschine mit innerer Verbrennung (E) ermöglicht;einem Spülventil (31V), das in dem Spülkanal (36) angeordnet ist, wobei das Spülventil (31V) so ausgebildet ist, dass es zum Regulieren einer Strömungsrate des von dem Behälter (30) zu dem Ansaugkanal (21, 22, 23, 24) strömenden Kraftstoffdampfs bewegbar ist;einem Rückschlagventil (32V), das in dem Spülkanal zwischen dem Spülventil (31V) und dem Ansaugkanal (21, 22, 23, 24) angeordnet ist, wobei das Rückschlagventil ...

Kraftstoffzufuhr-Steuer/Regel-System für Brennkraftmaschinen

VERFAHREN UND SYSTEM ZUR EINSTELLUNG VON MOTORDROSSELKLAPPEN

Es wird ein Motorsystem und -verfahren zum Betrieb eines Motors mit einer zentralen Drosselklappe und einer Einzeldrosselklappe offenbart. In einem Beispiel werden die zentrale Drosselklappe und die Einzeldrosselklappe zur Verbesserung von Übergängen zwischen Drosselklappensteuermodi eingestellt. Der Lösungsansatz kann für turboaufgeladene Motoren besonders vorteilhaft sein.

Verfahren und Vorrichtung zur Adaption von Signalen eines Sauerstoffsensors im Luftzufuhrkanal einer Brennkraftmaschine

Die Erfindung betrifft ein Verfahren zur Auswertung von Signalen eines Sauerstoffsensors im Luftzufuhrkanal einer Brennkraftmaschine, wobei der Luftzufuhrkanal über eine Abgasrückführung, welche mindestens ein Abgasrückführungsventil aufweist, mit einem Abgaskanal der Brennkraftmaschine verbunden ist und der Sauerstoffsensor im Luftzufuhrkanal stromabwärts der Abgasrückführ-Einleitung angeordnet ist, wobei das Sensorsignal in Abhängigkeit von einer Kenngröße oder mehreren Kenngrößen korrigiert wird, die die Abhängigkeit des Sensorsignals von der Sauerstoffkonzentration oder einer damit korrelierenden Größe und/oder von weiteren physikalischen Größen beschreiben. Erfindungsgemäß ist vorgesehen, dass an einem oder mehreren Betriebspunkten der Brennkraftmaschine bei geschlossenem Abgasrückführventil Ausgangssignale der Sauerstoffsensors sowie weitere Betriebspunktparameter erfasst und gespeichert werden und daraus eine Adaption der Kenngrößen des Sauerstoffsensors unter der Annahme, dass die ...

VERFAHREN ZUM ERMITTELN EINES MEßWERTES EINES EINLASSKRÜMMERDRUCKS

Ein Verfahren zur Verbesserung der Meßwertermittlung eines Drosselklappedrucksensors. In einem Beispiel wird der Drosselklappedrucksensor während eines Zylinderzyklus mehrmals abgetastet, und verschiedene Motorbetriebsbedingungen werden anhand ausgewählter Meßwertermittlungen bestimmt. Das Verfahren kann Motor-Luft-Kraftstoff-Steuerung sowie Motordiagnose verbessern.

Steuervorrichtung für Verbrennungsmotor und Verfahren zum Steuern eines Verbrennungsmotors

Steuervorrichtung für einen Verbrennungsmotor, mit:einem Leerlaufstopp-Steuerabschnitt (30) zum Stoppen einer Kraftstoffeinspritzung, ansprechend auf eine Erzeugung einer Automatikstopp-Anforderung zum Stoppen des Verbrennungsmotors (1) und zum Neustarten des Verbrennungsmotors (1), ansprechend auf eine Erzeugung einer Neustart-Anforderung; undeinem Luftansauggrößen-Steuerabschnitt (30) zum Einstellen einer Steuergröße eines Ansaug-Systems zum Steuern einer Luftansauggröße des Verbrennungsmotors (1), sodass die Luftansauggröße ungefähr zu Null wird, wenn ein Ansaugleitungsdruck des Verbrennungsmotors (1) zum Zeitpunkt der Erzeugung der Automatikstopp-Anforderung höher als ein vorbestimmter Druck ist, und zum Einstellen der Steuergröße des Ansaug-Systems, sodass die Luftansauggröße größer als die Luftansauggröße zum Zeitpunkt der Erzeugung der Automatikstopp-Anforderung wird, bis der Ansaugleitungsdruck gleich dem vorbestimmten Druck wird und dann die Luftansauggröße ungefähr zu Null wird ...

CONTROL CIRCUIT FOR REGULATING AN INJECTION PUMP FOR DIESEL ENGINES

Detektion einer Reversion auf der Grundlage von Lesewerten eines Luftmassenstromsensors

Ein Kraftmaschinensystem enthält einen Luftmassenstromsensor und einen Krümmerabsolutdrucksensor, der ausgestaltet ist, um während eines Ereignisses ein Echtzeit-MAP-Signal bereitzustellen. Der Luftmassenstromsensor ist ausgestaltet, um einen Satz von Luftmassenstromlesewerten auf der Grundlage eines Luftstroms durch den Luftmassenstromsensor während des Ereignisses zu erzeugen. Der Satz von Luftmassenstromlesewerten weist einen Maximalwert und einen Minimalwert auf. Ein Controller ist ausgestaltet, um ein Verfahren zum Detektieren einer Reversion in dem Luftstrom auszuführen. Das Verfahren umfasst, dass dann, wenn die Änderungsrate in dem Echtzeit-MAP-Signal kleiner als der vorbestimmte transiente Schwellenwert (T0) ist, ein Deltafaktor (D) als die Differenz zwischen dem Maximalwert und dem Minimalwert eingestellt wird. Eine Reversion wird zumindest teilweise auf der Grundlage einer Größe des Deltafaktors (D) detektiert.

Steuergerät für eine Brennkraftmaschine

Steuergerät für eine Brennkraftmaschine (10), die folgendes aufweist: einen Innenzylinderdrucksensor zum Ausgeben eines Innenzylinderdruckerfassungswerts eines vorbestimmten Zylinders an einem vorbestimmten Kurbelwinkel in der Brennkraftmaschine (10); ein Innenzylinderdruckerfassungsmittel zum Erfassen von Innenzylinderdruckerfassungswerten P1 und P2 an vorbestimmten Kurbelwinkeln 1 und 2 während einem adiabatischen Kompressionstakt des vorbestimmten Zylinders ab der Schließzeitgebung eines Einlassventils bis zur Zündzeitgebung unter Verwendung des Innenzylinderdrucksensors (34); ein Absolutdruckkorrekturwertberechnungsmittel, das einen Absolutdruckkorrekturwert Pr gemäß folgender Gleichung berechnet Pr = (P2V2 P1V1 )/(V1 V2 )wobei ein Innenzylindervolumen des vorbestimmten Zylinders an dem Kurbelwinkel 1 den Wert V1 hat, ein Innenzylindervolumen des vorbestimmten Zylinders an dem Kurbelwinkel 2 den Wert V2 hat, ein Isentropenkoeffizient des Innenzylindergases in dem vorbestimmten Zylinder ...

Ziel-Kompressorverhältnis- und Ziel-Verbrennungsgasverhältniserzeugung bei der Diesel-Luftaufladungs-Mehrgrößensteuerung

Ein Steuermodul enthält ein Modul für dynamische Zielauswahl, das dafür konfiguriert ist, einen Einlasskrümmerdruck-Sollwert und einen gemessenen Einlasskrümmerdruck zu empfangen, zwischen dem Einlasskrümmerdruck-Sollwert und dem gemessenen Einlasskrümmerdruck zu wählen und auf der Grundlage der Auswahl einen gewählten Einlasskrümmerdruck-Sollwert auszugeben. Ein Mehrgrößensteuermodul ist dafür konfiguriert, wenigstens einen Zielsollwert zu empfangen, der auf dem gewählten Einlasskrümmerdruck-Sollwert beruht, und den Betrieb eines Luftaufladungssystems eines Fahrzeugs auf der Grundlage des wenigstens einen Zielsollwerts zu steuern.

Verwaltung von Zündungsbruchteilen bei der Zündungsauslassungs-Motorsteuerung

In verschiedenen beschriebenen Ausführungsformen wird Zündungsauslassungssteuerung verwendet, um eine gewünschte Motorleistung zu liefern. Eine Steuereinrichtung bestimmt einen Zündungsauslassungs-Zündungsbruchteil und (gegebenenfalls) zugeordnete Motoreinstellungen, die zum Liefern einer angeforderten Leistung geeignet sind. In einem Aspekt wird der Zündungsbruchteil aus einer Menge verfügbarer Zündungsbruchteile ausgewählt, wobei die Menge verfügbarer Zündungsbruchteile als Funktion der Motordrehzahl variiert, so dass bei höheren Motordrehzahlen mehr Zündungsbruchteile verfügbar sind als bei niedrigeren Motordrehzahlen. Sodann dirigiert die Steuereinrichtung die Zündungen auf eine Zündungsauslassungs-Weise, die den ausgewählten Bruchteil der Zündungen liefert. In anderen Ausführungsformen ist die Zündungsauslassungs-Steuereinrichtung dazu angeordnet, einen Basis-Zündungsbruchteil zu wählen, der eine sich wiederholende Zündzykluslänge hat, die sich bei der gegenwärtigen Motordrehzahl mindestens ...

Drucksensorvorrichtung

Drucksensorvorrichtung, mit: einem Drucksensor (1), um einen Druck von einem Fluid zur Messung zu erfassen, und einem Sensorbehälter (2), um darin den Drucksensor (1) unterzubringen, wobei der Sensorbehälter (2) eine Basis (10) und ein Gehäuse (11) umfasst, wobei die Basis (10) eine Bodenwand und zumindest eine Seitenwand umfasst und der Drucksensor (1) in dem Gehäuse (11) des Sensorbehälters (2) angeordnet ist, dadurch gekennzeichnet, dass der Sensorbehälter (2) mit einer Druckeinlassöffnung (13) eines Rohrs (12), wodurch das Fluid zur Messung strömt, direkt verbunden ist, und wobei der Sensorbehälter (2) eine Wand (17) aufweist, zur Begrenzung eines zweiten Fachs (16), das sich gegenüber der Druckeinlassöffnung (13) befindet, und eines ersten Fachs (15), das eine Druckeinführungsöffnung (14), zur Einführung des Fluids zur Messung, das durch die Druckeinlassöffnung (13) in den Drucksensor (1) abgeschieden ist, aufweist, wobei das zweite Fach (16) und das erste Fach (15) Seite an Seite ...

Drosselsteuersystem und -Verfahren für Verbrennungsmotoren zum Verringern von Drosseloszillationen

Drosselsteuersystem, das umfasst: ein Druckvergleichsmodul (52), das einen Einlassdruck stromaufwärts eines Drosselkörpers (22) und einen Auslassdruck stromabwärts des Drosselkörpers (22) ermittelt; und ein Drosselklappen-Steuermodul (54), das eine Position einer Drosselklappe (24) basierend auf dem Einlassdruck und dem Auslassdruck steuert, wobei das Drosselklappen-Steuermodul (54) die Position der Drosselklappe (24) basierend auf dem Einlassdruck, dem Auslassdruck, einem gewünschten Luftmassendruck (MAP) und einem Turbo-Basisdruck steuert, wenn ein Motor (12) gestartet wird, wobei das Drosselklappen-Steuermodul (54) die Drosselklappe (24) aus einer weit offenen Position in eine gewünschte Drosselposition bewegt, wenn der gewünschte MAP nicht größer als der Turbo-Basisdruck ist oder wenn eine Differenz zwischen dem Einlassdruck und dem Auslassdruck gleich einem zweiten Schwellenwert oder größer als dieser ist, oder wobei das Drosselklappen-Steuermodul (54) die Drosselklappe (24) aus einer ...

Verfahren und eine Vorrichtung zur Regelung eines Kraftstoff-Luft-Gemischs einer mit gasförmigem Kraftstoff betriebenen Brennkraftmaschine

Verfahren zur Regelung eines Kraftstoff-Luft-Gemischs einer mit gasförmigem Kraftstoff betriebenen Brennkraftmaschine in Abhängigkeit eines jeweiligen Betriebszustands, bei dem der Kraftstoff in einem Gas-Luft-Mischer mit von der Brennkraftmaschine (1) angesaugter Brennluft gemischt und der Brennkraftmaschine (1) zugeführt wird, dadurch gekennzeichnet, dass als Gas-Luft-Mischer ein Venturi-Mischer (2) verwendet wird, dass am Gas-Luft-Mischer (2) eine dem diesen durchsetzenden Luftmassenstrom entsprechende Ist-Druckdifferenz Δpist gemessen und mit einer für den jeweiligen Betriebszustand der Brennkraftmaschine (1) vorgegebenen Soll-Druckdifferenz Δpsoll verglichen wird, dass die Soll-Druckdifferenz Δpsoll in Abhängigkeit von einer Leistungsanforderung der Brennkraftmaschine vorgegeben wird, dass die Soll-Druckdifferenz Δpsoll weiterhin in Abhängigkeit eines Absolutdrucks pabs am Venturi-Mischer (2), insbesondere in Abhängigkeit eines Absolutdrucks pabs der zugeführten Brennluft und in Abhängigkeit ...

Determining gas mixture composition in combustion chamber of internal combustion engine with exhaust gas feedback, involves determining state parameters with physically based models

The method involves determining suitable state parameters of the internal combustion engine using suitable physically based models that simulate the behavior of the internal combustion engine in relation to the state parameters to be determined. The composition and mass of the gas mixture in the combustion chamber are determined using the physically based model. An Independent claim is also included for a control system for an internal combustion engine with exhaust gas feedback.

Internal combustion engine regulator computes desired choke angle based on required air throughput rate (based on required torque) and desired induction pressure (based on desired air throughput rate)

The regulator has a device for computing required indicated torque based on the gas pedal position and similar, a device for computing a required air throughput rate based on the required torque or similar and a device for computing the desired suction pressure based on the desired air throughput rate or similar. The desired choke angle is computed based on the required air throughput rate and the desired induction pressure The engine has a demand choke angle computation device (5) and a choke flap controller (6). The regulator has a device (1) for computing the required indicated torque to be produced by internal combustion engine combustion based on the gas pedal position and similar, a device (2) for computing a required air throughput rate based on the required torque or similar and a device (4) for computing the desired induction pressure based on the desired air throughput rate or similar. The desired choke angle is computed based on the required air throughput rate and the desired ...

System und Verfahren für den Betriebsartübergang für einen sequentiellen Zweistufenreihen-Turbolader

Ein Verfahren zum Steuern eines Reihenturboladers für einen Motor und ein Steuersystem für denselben enthält ein Ladedruckbestimmungsmodul, das einen ersten vorhergesagten Ladedruck für eine erste Position einer Turbine mit variabler Geometrie bestimmt, wenn ein Hochdruckturbinen-Umgehungsventil in einer offenen Position ist. Das Ladedruckbestimmungsmodul bestimmt einen zweiten Ladedruck für eine zweite Position der variablen Geometrie, wenn das Hochdruckturbinen-Umgehungsventil in der offenen Position ist. Ein Modul für den gewünschten Ladedruck bestimmt einen gewünschten Ladedruck. Ein Vergleichsmodul bestimmt, wann das Signal für den gewünschten Ladedruck zwischen dem ersten vorhergesagten Ladedruck und dem zweiten vorhergesagten Ladedruck liegt. Ein Umgehungsventilsteuermodul schließt das Hochdruckturbinen-Umgehungsventil, wenn das Signal für den gewünschten Ladedruck zwischen dem ersten vorhergesagten Ladedruck und dem zweiten vorhergesagten Ladedruck liegt.

Motordrehmoment-Steuersysteme mit linearer Transformation und Verfahren für Drehmomentzunahmeanforderungen

Ein Verfahren zum Betreiben eines Motors eines Fahrzeugs umfasst das Erzeugen einer ersten Drehmomentanforderung. Das Verfahren umfasst das Erzeugen einer zweiten Drehmomentanforderung, die größer ist als die erste Drehmomentanforderung und auf dieser basiert, das Erhöhen eines Ausgangsdrehmoments des Motors auf der Basis der zweiten Drehmomentanforderung mit einer ersten Rate und während einer ersten Periode und das Erhöhen des Ausgangsdrehmoments des Motors auf der Basis der ersten Drehmomentanforderung mit einer zweiten Rate und während einer zweiten Periode. Die erste Periode ist von der zweiten Periode verschieden und liegt vor dieser und die erste Rate ist größer als die zweite Rate.

Nutzung von Motorparametern für Kondensationsverhinderungsstrategien

Es werden eine Steuerung und ein Verfahren für einen Verbrennungsmotor mit einem Abgasrezirkulationssystem angegeben, um eine kritische Temperatur (Taupunkt) für einen Einlasskrümmer anzugeben, bei der beim Eintritt in die Abgasrezirkulation eine Kondensation auftreten würde. Die Steuerung berechnet die kritische Einlasskrümmungstemperatur (IMT_Critical) als Funktion von vorbestimmten festgestellten oder angenommenen Werten, indem sie eine Gleichung verarbeitet, in deren Variablen die Werte eingesetzt werden. Die Steuerung veranlasst Anpassungen an den Betrieb des Abgasrezirkulationssystems in Reaktion auf die Berechnung, vorzugsweise nachdem die tatsächliche Einlasskrümmertemperatur den Wert IMT_Critical für eine vorbestimmte Zeitdauer überschritten hat.

Verfahren und Einrichtung zur adaptiven feed-forward-Steuerung der Kraftstoffförderung

System und Verfahren zur optimalen Brennstoffversorgung eines Motors

Ein Verfahren zur optimalen Brennstoffzufuhr eines Motors ist offenbart. Das Verfahren enthält das Bestimmen einer Menge von Restgasanteilen in jedem Zylinder unter einer Mehrzahl von Zylindern in dem Motor. Außerdem enthält das Verfahren das Bestimmen einer Einlassverteilertemperatur und/oder einer Abgasverteilertemperatur, eines Einlassverteilerdrucks und/oder eines Abgasverteilerdrucks und einer Menge eines ersten Brennstoffs, der in jeden Zylinder eingespritzt wird, und das Berechnen eine charakteristischen Temperatur von jedem Zylinder basierend auf der Menge von Restgasanteilen, der Einlassverteiler- und/ Abgasverteiler-Temperatur und -druck und der Menge des ersten Brennstoffs. Das Verfahren enthält außerdem das Ermitteln einer Substitutionsrate des ersten Brennstoffs für jeden Zylinder basierend auf der charakteristischen Temperatur und das Steuern der Menge des ersten Brennstoffs und/oder einer Menge eines zweiten Brennstoffs, die in jeden Zylinder basierend auf der Substitutionsrate ...

KRÜMMERVOLUMENBESTIMMUNG BASIEREND AUF EINER PUMPFREQUENZ

Verfahren und Systeme zum Bestimmen einer Zylinderluftladung basierend auf einem Ladekrümmervolumen eines Motors sind bereitgestellt. In einem Beispiel kann ein Verfahren das Auslösen eines Kompressorpumpereignisses und das Aktualisieren des Ladekrümmervolumens als Reaktion auf eine Differenz zwischen einem Ist-Pumpdruck und einem Soll-Pumpdruck umfassen. Das Verfahren umfasst ferner das Bestimmen der Zylinderluftladung basierend auf dem aktualisierten Ladekrümmervolumen.

Verfahren zur Überprüfung der Funktion eines Drucksensors im Luft-Ansaugtrakt oder Abgas-Auslasstrakt eines Verbrennungsmotors im Betrieb und Motor-Steuerungseinheit

Verfahren zur Überprüfung der Funktion eines Drucksensors (44) im Luft-Ansaugtrakt (20) oder Abgas-Auslasstrakt (30) eines Verbrennungsmotors (1) im Betrieb, wobei- dynamische Druckschwingungen der Ansaugluft im Luft-Ansaugtrakt (20) oder des Abgases im Abgas-Auslasstrakt (30) des betreffenden Verbrennungsmotors (1) im Betrieb mittels des betreffenden Drucksensors (44) gemessen werden und daraus ein entsprechendes Druckschwingungssignal (DS_S) erzeugt wird; und- wobei auf Basis des Druckschwingungssignals (DS_S) mit Hilfe Diskreter-Fourier-Transformation (DFT), für mehrere ausgesuchte Signalfrequenzen (SF1...X) jeweils ein Wert eines bestimmten Betriebscharakteristikums (BChk_W1...X) des Verbrennungsmotors (1) ermittelt wird und Abweichungswerte (Aw_W1...Y) der für unterschiedliche Signalfrequenzen (SF1...X) ermittelten Werte des Betriebscharakteristikums (BChk_W1...X) voneinander ermittelt werden;- wobei die einwandfreie Funktion des Drucksensors (44) bestätigt wird (DSens=ok), wenn keiner ...

Abgassteuerungssystem eines Verbrennungsmotors und Steuerungsverfahren eines Abgassteuerungssystems eines Verbrennungsmotors

Abgassteuerungssystem eines Verbrennungsmotors (1) mit einem AGR-Gerät (20), einem Dreiwege-Katalysator (6) und einer elektronischen Steuerungseinheit (10). Die elektronische Steuerungseinheit (10) ist konfiguriert, um das Luft-Kraftstoff-Verhältnis von einem in den Dreiwege-Katalysator einströmenden Abgas derart zu steuern, dass das Luft-Kraftstoff-Verhältnis, verglichen mit dem Luft-Kraftstoff-Verhältnis wenn die AGR-Steuerung nicht während der Ausführung der Kraftstoff-Absperr-Steuerung ausgeführt wird, ein höheres Luft-Kraftstoff-Verhältnis in einem Bereich des fetten Luft-Kraftstoff-Verhältnisses ist, wenn die elektronische Steuerungseinheit eine AGR-Steuerung während einer Ausführung einer Kraftstoff-Absperr-Steuerung ausführt und dann den Anfettungsvorgang ausführt, nachdem die Ausführung der Kraftstoff-Absperr-Steuerung endet.

Systeme und Verfahren zum Moduswechsel für einen sequentiellen Turbolader

Ein System für einen sequentiellen Turbolader enthält ein Moduswahlmodul, ein Vorwärtsschub-Wahlmodul und ein Regelkreismodul. Das Moduswahlmodul erzeugt ein Kontrollmodussignal auf der Grundlage eines Motordrehzahlsignals, eines Motordrehmomentsignals und eines Motormodussignals. Das Kontrollmodussignal zeigt einen Steuerungsmodus oder einen Regelungsmodus an. Das Vorwärtsschub-Wahlmodul ermittelt einen Vorwärtsschubwert auf der Grundlage des Kontrollmodussignals, des Motordrehzahlsignals und des Motordrehmomentsignals. Das Regelkreismodul ermittelt einen Regelungswert auf der Grundlage des Vorwärtsschubwerts und/oder eines Steuerungssignals für eine Turbine mit variabler Geometrie (VGT) und/oder eines Fehlersignals; und auf der Grundlage eines Umgehungsventil-Steuerungssignals (BPV-Steuerungssignals) und des Fehlersignals, wenn das Kontrollmodussignal vom Steuerungsmodus in den Regelungsmodus wechselt.

KATALYSATORERWÄRMUNG MIT ABGASGEGENDRUCK

Es werden Ausführungsformen zum Steuern eines Abgasgegendruckventils bereitgestellt. In einem Beispiel umfasst ein Verfahren zum Betreiben eines Motors das Schließen eines Abgasgegendruckventils als Reaktion auf eine Komponententemperatur, Einstellen eines Einlass- und/oder Ablassventilbetriebs als Reaktion auf das Schließen des Abgasgegendruckventils zum Reduzieren der zylinderinternen Abgasrückführung (EGR) und, während des Schließens des Abgasgegendruckventils, Anzeigen einer Verschlechterung eines Abgasgegendrucksystems, wenn ein bestimmter Motorbetriebsparameter konstant bleibt. Auf diese Weise kann eine Verschlechterung des Abgasgegendrucksystems bei gleichzeitiger Aufrechterhaltung der Verbrennungsstabilität diagnostiziert werden.

VERFAHREN FÜR DIE DIAGNOSE EINER KRAFTMASCHINE

Es wird ein Verfahren zum Betreiben einer Kraftmaschine in Reaktion auf eine Position eines Ladedrucksteuerventils angegeben. In einem Beispiel stellt das Verfahren einen Aktor ein, um die Wahrscheinlichkeit einer Fehlzündung in einem Kraftmaschinenzylinder in Reaktion auf die Position des Ladedrucksteuerventils zu verringern. Auf diese Weise ist es möglich, einen Kraftmaschinenbetrieb für variierende Kraftmaschinenbetriebsbedingungen einzustellen.

Automobile direct fuel injection engine operating method has throttle in air intake line adjusted for reducing combustion air quantity dependent on engine load or pressure increase in reduced pressure reservoir for servo devices

The engine operating method is used for a direct fuel injection engine which has a reduced pressure reservoir for one or more servo devices, coupled to the engine air intake line (1) supplying the combustion air to the engine combustion chamber, with the throttle adjusted for reducing the quantity of combustion air, in dependence on the position of the accelerator pedal or upon reaching a pressure increase threshold for the reduced pressure reservoir. Also included are Independent claims for the following; (a) a control element for an engine control device; (b) an engine control device; and (c) an automobile engine.

Verfahren zum Steuern oder/und Regeln der Laserzündung einer Brennkraftmaschine

Verfahren zum Steuern und/oder Regeln der Zündung eines zündfähigen Gemischs in einem Brennraum einer Brennkraftmaschine, bei der im Brennraum (3) eine zündfähige Gemischwolke gebildet wird und die eine Laserzündvorrichtung (8) zum Erzeugen mindestens eines Laserstrahles sowie verstellbare Fokussiermittel zum Fokussieren des Laserstrahls auf einen variablen Zündort im Brennraum (3) aufweist, bei welchem Verfahren der Brennpunkt (13) des Laserstrahles im Betrieb der Brennkraftmaschine in Abhängigkeit von mindestens einem die Lage der Gemischwolke im Brennraum (3) beeinflussenden Betriebsparameter der Brennkraftmaschine gesteuert oder/und geregelt wird.

Exhaust gas pressure determination method for use in exhaust gas tract of e.g. diesel engine, involves determining input variables respectively correlated with gas reference temperature of turbo charger and differential pressure at filter

The method involves determining an input variable correlated with an injection quantity of an internal-combustion engine (10) is determined. Another input variable correlated with a mass flow in an exhaust gas recirculation (34) from an exhaust gas tract (12) into a suction tract (16) is determined. Third and fourth input variables respectively correlated with exhaust gas reference temperature of an exhaust gas turbo charger (30) and a differential pressure at a particle filter (32) are determined. An exhaust pressure (P3) is determined based on the input variables.

Kaltstartemmissionsstrategie für Hybridfahrzeuge

Ein Maschinensteuermodul umfasst ein Maschinenstartmodul, das mit einem Elektromotor kommuniziert, um eine Brennkraftmaschine zu betreiben, die M Kraftstoffinjektoren umfasst, und das bestimmt, ob ein Krümmerdruck unter einer Krümmerdruckschwelle liegt. Ein Aufwärmmodul kommuniziert mit den M Kraftstoffinjektoren, um Kraftstoff in N von M der Kraftstoffinjektoren einzuspritzen, wenn der Krümmerdruck kleiner ist als die Krümmerdruckschwelle. N und M sind ganze Zahlen und N ist kleiner als M.

Motorsteuer/regelverfahren

Aufgabe: Ein Motorsteuer/regelverfahren bereitzustellen, welches in der Lage ist, die Periode vom Anlassstart zu verkürzen, bis die Kraftstoffeinspritzsteuerung/regelung auf der Basis eines Motoransaugdrucks ermöglicht ist. Mittel zur Lösung: In einem Motorsteuer/regelverfahren zur Durchführung einer Taktbestimmung für eine Mehrzahl von Zylindern aus einer von einem Pb-Sensor (4) erfassten künstlichen Krümmerdruckwellenform (Pb) werden die Werte eines Ansaugdrucks in den jeweiligen Anlassstufen von einem Zeitpunkt an gepuffert, wenn das Anlassen des Motors gestartet wird und die Taktbestimmung wird vorläufig zu einem Zeitpunkt festgelegt, wenn sich die Kurbelwelle um 720° gedreht hat, von einem Zeitpunkt, wenn eine Kurbelreferenzposition festgelegt ist. Zu der Zeit der vorläufigen Festlegung werden die gepufferten erfassten Werte von dem Ansaugdruck mit vorläufigen Zyklusstufen (720°-Stufe) in Beziehung gebracht, welche sich bei der vorläufigen Festlegung herausgestellt haben. Dementsprechend ...

Verfahren und Vorrichtung zur Motorabgasmessung

Verfahren zur Bestimmung der spezifischen Stickoxid(NOx)-Emission als Abgas-Kennzahl eines Verbrennungsmotors, wobei der Stickoxid-Massenstrom (3) als erste Betriebs-Kenngröße und die Motor-Abgabeleistung (2) als zweite Betriebs-Kenngröße bestimmt werden, der Stickoxid-Massenstrom (3) und die Motor-Abgabeleistung (2) aus jeweils mindestens einer von der Betriebs-Kenngröße abweichenden Messgröße abgeleitet werden und die Abgas-Kennzahl als Quotient aus dem korrigierten Stickoxid-Massenstrom (3) und der Motor-Abgabeleistung (2) berechnet wird.

Verfahren zur Regelung eines stationären Gasmotors

Die Erfindung schlägt ein Verfahren zur Regelung eines stationären Gasmotors (1) vor, bei dem eine Drehzahl-Regelabweichung aus einer Soll-Drehzahl (nSL) sowie einer Ist-Drehzahl (nIST) berechnet wird, aus der Drehzahl-Regelabweichung über einen Drehzahlregler als Stellgröße ein Soll-Moment bestimmtrom bestimmt wird, bei dem ein Gemisch-Drosselklappenwinkel (DKW1, DKW2) zum Festlegen eines Gemisch-Volumenstroms sowie eines Ist-Gemischdrucks (p1(IST), p2(IST)) in einem Receiverrohr (12, 13) vor den Einlassventilen des Gasmotors (1) in Abhängigkeit des Soll-Volumenstroms festgelegt wird und bei dem ein Gas-Drosselklappenwinkel zum Festlegen eines Gas-Volumenstroms als Gasanteil in einem Gas-Luftgemisch ebenfalls in Abhängigkeit des Soll-Volumenstroms festgelegt wird.

Vorrichtung und Verfahren zur Steuerung eines Verbrennungsmotors

Vorrichtung zur Steuerung eines Verbrennungsmotors (2), bei der ein Lader (7) zur Erhöhung des Drucks einer dem Verbrennungmotor (2) zugeführten Luft vorgesehen ist, bei der ein Katalysator (10) zur Aufbereitung der Abgase des Verbrennungsmotors (2) vorgesehen ist, bei der ein Verbrennungszeitpunkt des Verbrennungsmotors (2) beeinflussbar ist, bei der in Abhängigkeit von einer Temperatur des Katalysators (10) zur Heizung des Katalysators (10) auf eine Betriebstemperatur der Lader (7) aktiviert wird, bei welcher der Verbrennungszeitpunkt in Richtung spät verschoben wird, wobei es sich um einen Verbrennungsmotor (2) mit Fremdzündung handelt, bei dem der Zeitpunkt der Verbrennung durch Erzeugung eines Zündfunkens an einer Zündkerze (3) beeinflußt wird, dadurch gekennzeichnet, dass ein Einspritzventil (4) vorgesehen ist, welches Kraftstoff direkt in einen Verbrennungsraum (14) des Verbrennungsmotors (2) einspritzt, dass ein Einlassventil (5) zwischen dem Brennraum (14) und einem Ansaugkanal ...

Verfahren und Anordnung zur Behandlung der Abgase eines Kraftfahrzeuges

Verfahren zum Freisetzen einer Menge eines Abgasbestandteils, der in einer Emissionsbegrenzungsvorrichtung (36) gespeichert ist, aus der Emissionsbegrenzungsvorrichtung (36), welche das durch eine Brennkraftmaschine erzeugte Abgas aufnimmt, gekennzeichnet durch die Schritte: Erzeugen einer ersten Abgasströmung durch die Emissionsbegrenzungsvorrichtung (36) während einer ersten Zeitdauer, wobei das Abgas fetter als ein stöchiometrisches Luft/Kraftstoffgemisch ist; Erfassen eines charakteristischen Merkmals der ersten Abgasströmung an einer Position (42) innerhalb der Emissionsbegrenzungsvorrichtung (36) zwischen einem stromaufwärtigen Bereich (46) der Emissionsbegrenzungsvorrichtung (36) und einem stromabwärtigen Bereich (48) der Emissionsbegrenzungsvorrichtung (36); und Bestimmen der ersten Zeitdauer auf Basis des erfassten charakteristischen Merkmals.

Vorrichtung zur Abgasreinigung von Kraftmaschinen

Die Durchlässigkeit eines an einer Dieselkraftmaschine 1 angebrachten DPF 21 wird dadurch ermittelt, dass der scheinbare Durchlassflächeninhalt (A) auf der Grundlage einer Differenz der Drücke zwischen der stromaufwärtigen Seite und der stromabwärtigen Seite des DPF 21 und auf der Grundlage von anderen Kraftmaschinendaten berechnet wird, dass ein Alarm zu einem Fahrer auf Grundlage der Ermittlungsergebnisse abgegeben wird und dass der Betriebsmodus umgeschaltet wird, um den DPF 21 wiederherzustellen. Eine durch eine Zerstörung verursachte anormale Vergrößerung des Durchlassflächeninhalts wird genau erfasst, und die PM werden nicht in die Außenluft in langen Zeitperioden aufgrund der Zerstörung des DPF 21 ausgelassen. Des Weiteren kann der DPF 21 zuverlässig ausgebrannt und wiederhergestellt werden, ohne dass der DPF 21 demontiert werden muss oder ohne dass er bei jedem Betriebsmodus der Kraftmaschine 1 in unerwünschter Weise überhitzt wird.

Crankshaft position determination method for multi-cylinder IC engine using evaluation of angle markings in camshaft signal

The method determines the discrete angular position of the crankshaft (10) via a camshaft signal (CAM) having several angle markings for each full rotation of the camshaft (12), corresponding to half the number of engine cylinders (1-4), the latter divided into 2 groups operated in alternation in the combustion sequence. The angle markings are used for providing the crankshaft angular position for each cylinder of one engine cylinder group and the distances between 2 successive angle markings are used for estimating the crankshaft angular positions for the cylinders of the other engine cylinder group.

A combustion engine evaluation unit comprising fault detection system for engine using EGR

Disclosed is a combustion engine evaluation unit which comprises a microcontroller for receiving measurement signals from a gas flow control system of a combustion engine and for outputting a state signal indicating a state of the gas flow control sys­tem. The microcontroller comprises input ports for receiving as first set of measurement signals comprising an intake pressure down­stream of a high pressure exhaust gas recirculation valve, an intake temperature downstream of a high pressure exhaust gas recirculation valve and an intake air flow rate downstream of an air filter. Furthermore, the microcontroller comprises in­put ports for receiving as a second set of measurement sig­nals a motor revolution speed and a flap valve control signal. The microcontroller is adapted to calculate a first set of predicted values by using a gas flow model, based on the first set of measurement signals and to calculate a second set of predicted values by using a nominal model, based on the second ...

A method of operating an internal combustion engine having a turbocharger

A method of operating an internal combustion engine 110 having a turbocharger 230 and an exhaust gas recirculation pipe 500 fluidly connecting an exhaust system 270 to an air intake system 195 upstream of a compressor 240 of the turbocharger 230, the method compris­ing the steps of monitoring a first value of a parameter indicative of the density of a mixture of fresh air and exhaust gas in the air intake system 195, and interrupting a flowing of exhaust gas through the exhaust gas recirculation pipe 500 if the first value is lower than a first reference threshold value thereof. The measured parameter may be pressure, and a Fast Fourier Transform may be performed on the measured values. The invention is intended to control the occurrence of condensation in the intake system, which may damage the turbocharger compressor. Also defined are an internal combustion engine, a computer program, a computer program product, and an electromagnetic signal for the defined method.

Condensation control for internal combustion engine having an exhaust gas recirculation circuit

A system and method for controlling an internal combustion engine to reduce or eliminate formation of EGR condensate is disclosed. Said method comprises monitoring current ambient 200 and engine operating conditions 210 and determining whether conditions are favourable for condensation of the EGR gases 222. If said conditions are favourable the engine is controlled accordingly 228 to avoid condensation; preferably by increasing the intake manifold temperature. The intake manifold temperature may be increased by redirecting some or all of the EGR flow 230 to avoid an EGR cooler. Alternatively, or in combination, some or all of the charge air may be redirected 232 to bypass the charge air cooler and/ or redirected from the outlet of a turbocharger compressor to the intake, effectively increasing the intake air temperature and resulting in a corresponding increase of the intake manifold temperature. Conditions favourable for condensation may be determined based on engine speed and load 214 ...

Control strategy for an engine with a hybrid valvetrain

A method and system for reducing engine emissions

A method and system for improving a purge conversion efficiency of a Lean NOx Trap 72 coupled downstream of a lean-burn internal combustion engine 11 is provided. The method comprises adjusting the purge air-fuel ratio of the LNT 72 based on its temperature and a less rich air-fuel ratio is provided at lower operating temperatures to reduce hydrocarbon emissions since within this temperature range air-fuel ratio does not have a significant affect on NOx emissions. At mid-range operating temperatures, the air-fuel ratio is gradually decreased so that the mixture becomes more rich to reduce NOx emissions and finally, at high operating temperatures, HC and NOx emissions are reduced, and therefore, the purge air-fuel is kept at a constant more rich value. This method improves emission control and fuel economy during purge.

Vehicle exhaust gas recirculating system with detection of pressure sensor de terioration.

A method and apparatus for controlling an engine coupled to an EGR system, including two pressure sensors 206, 207. The EGR system may contain an orifice 205 disposed in the EGR tubing, with a first pressure sensor 206 coupled to an air intake manifold 44 of the engine and preferably located upstream of the orifice. A second pressure sensor 207 is coupled to the EGR system and is preferably located downstream of the orifice. The method determines whether at least one sensor has degraded, and resulting in a positive determination, the EGR system is disabled. The controller 12 utilises the non degraded pressure sensor to determine the engine's operation, such as an air/fuel ratio. Preferably the pressure sensors are used to measure absolute pressure and EGR pressure relative to atmospheric pressure. The controller may adjust the fuel injection amount based on an estimated atmospheric pressure. The vehicle may be a hybrid vehicle.

Система двигателя

1. Система двигателя, содержащая:двигатель, содержащий впуск и выпуск;турбонагнетатель для подачи подвергнутого наддуву заряда воздуха в двигатель, причем турбонагнетатель включает в себя турбину с приводом от выхлопных газов и впускной компрессор;регулятор давления наддува, присоединенный в параллель турбине;непрерывно регулируемый клапан рециркуляции, присоединенный в параллель компрессору;дроссель, присоединенный к впуску ниже по потоку от компрессора; иконтроллер с машиночитаемыми командами для:осуществления работы системы двигателя в первом режиме, в котором положение регулятора давления наддува, впускного дросселя и положение клапана рециркуляции регулируются для обеспечения требуемого давления наддува на основании требования крутящего момента водителя; иосуществления работы системы двигателя во втором режиме, в котором регулируется только положение регулятора давления наддува и впускного дросселя для обеспечения требуемого давления наддува на основании требования крутящего момента водителя.2. Система по п. 1, в которой контроллер выполнен с возможностью осуществления работы системы двигателя в первом режиме в ответ на отсутствие указания ухудшения работы клапана рециркуляции и осуществления работы системы двигателя во втором режиме в ответ на указание ухудшения работы клапана рециркуляции.3. Система по п. 1, в которой при работе системы двигателя в первом режиме положение регулятора давления наддува регулируется с более высокой регулировкой коэффициента передачи, а при работе системы двигателя во втором режиме положение регулятора давления наддува регулируется с более низкой регул� РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 145 314 U1 (51) МПК F02B 37/16 (2006.01) F02D 23/00 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ТИТУЛЬНЫЙ (21)(22) Заявка: ЛИСТ ОПИСАНИЯ ПОЛЕЗНОЙ МОДЕЛИ К ПАТЕНТУ 2014109740/06, 13.03.2014 (24) Дата начала отсчета срока действия патента: 13.03.2014 (72) Автор(ы): ЯНКОВИЧ Мрдьян Я. (US), БАКЛЕНД Джулия Хелен (US) 14.03. ...

Система двигателя

1. Система двигателя, содержащая:устройство сжатия, содержащее компрессор, расположенный во впускном канале;первый дроссель, расположенный ниже по потоку от компрессора во впускном канале;второй дроссель, расположенный выше по потоку от компрессора во впускном канале;контроллер, содержащий процессор и машиночитаемое запоминающее устройство, содержащее команды, исполняемые процессором, дляоткрывания второго дросселя для повышения давления на впуске первого дросселя при переходном состоянии, когда требуемое давление во впускном коллекторе больше, чем давление на впуске дросселя у первого дросселя, если падение давления на втором дросселе больше, чем пороговое значение давления.2. Система двигателя по п. 1, дополнительно содержащая:систему регулируемой установки фаз клапанного распределения;при этом машиночитаемое запоминающее устройство дополнительно содержит команды, исполняемые процессором для:регулировки системы регулируемой установки фаз клапанного распределения для уменьшения внутреннего захватывания EGR в цилиндрах двигателя при переходном состоянии, когда требуемое абсолютное давление во впускном коллекторе больше, чем давление на впуске дросселя, если коэффициент наполнения цилиндров меньше, чем пороговое значение коэффициента наполнения.3. Система двигателя по п. 1, дополнительно содержащая:систему LP-EGR для подачи LP-EGR из выпускного канала во впускной канал выше по потоку от компрессора;при этом машиночитаемое запоминающее устройство дополнительно содержит команды, исполняемые процессором для:уменьшения потока LP-EGR при переходном состоянии, когда требуемое абсолютное давление во впуск� РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 152 593 U1 (51) МПК F02D 23/00 (2006.01) F02D 43/00 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ТИТУЛЬНЫЙ (21)(22) Заявка: ЛИСТ ОПИСАНИЯ ПОЛЕЗНОЙ МОДЕЛИ К ПАТЕНТУ 2014120400/06, 20.05.2014 (24) Дата начала отсчета срока действия патента: 20.05.2014 Приоритет(ы): (30) Конвенционный приоритет: (45) Опубликовано: ...

Deterioration determination apparatus for airflow meter and deterioration determination method

When a deterioration determination apparatus determines a degree of deterioration in characteristics of an airflow meter, a driving condition of an engine is maintained at a specified condition in which intake air flow rate is greater than a specified value. A measurement error of the airflow meter is computed based on an intake air flow rate measured with the airflow meter. The degree of deterioration due to stain is determined based on the measurement error.

Control device for turbocharged engine

An object of the present invention is to provide a control device for a turbocharged engine capable of accurately estimating the revolution speed of a turbine without using additional components for directly detecting the turbine revolution speed, and by accurately estimating the turbine revolution speed, capable of accurately keeping the turbine revolution speed at an allowed value or below and preventing excessive rotation. The control device for a turbocharged engine includes a turbocharger having a compressor disposed in an intake passage of an engine, and a turbine disposed in an exhaust passage of the engine, a fuel injection amount control unit for controlling a fuel injection amount to the engine according to an operating state of the engine, and a turbine revolution speed estimation unit for determining by calculations an estimated value of a revolution speed of the turbine from the operating state of the engine. When the estimated value of the turbine revolution speed exceeds a predetermined allowed value, the fuel injection control unit controls the fuel injection amount such that the estimated value of the turbine revolution speed becomes equal to or less than the allowed value.

System for diagnosing error conditions of a gas flow control system for diesel engines

A combustion engine evaluation unit is provided that includes, but is not limited to a microcontroller receiving measurement signals from a gas flow control system and outputting a state signal of the gas flow control system. The microcontroller includes, but is not limited to input ports for receiving as first set of measurement signals. Furthermore, the microcontroller includes, but not limited to input ports for receiving as a second set of measurement signals. The microcontroller is configured to calculate a first set of predicted values with a gas flow model based on the first set of measurement signals and calculate a second set of predicted values with a nominal model based on the second set of measurement signals. The microcontroller is also configured to generate the state signal based on a comparison of the first set of predicted values with the second set of predicted values.

Method for operating a turbocharger arrangement and control unit for a turbocharger arrangement

A method for operating a turbocharger arrangement of an internal combustion engine, the turbocharger arrangement comprising a low-pressure and a high-pressure turbocharging stage arranged sequentially, the low-pressure turbo-charging stage comprising a low-pressure turbine with a sensorless low-pressure turbine bypass valve, is provided. The method comprises evaluating at least one sensor signal of the turbocharger arrangement for detecting a failure mode of the sensorless low-pressure turbine bypass valve. In this way, the low-pressure turbine bypass valve may be monitored for degradation without utilizing a position sensor.

System and method for cam phaser control in an engine

A control system for an engine includes a position determination module and a position control module. The position determination module determines a first cam phaser position for starting the engine prior to engine shut down, and determines a second cam phaser position for starting the engine while the engine is shut down. The position control module adjusts a cam phaser to the first cam phaser position at engine shut down. The position control module adjusts the cam phaser from the first cam phaser position to the second cam phaser at engine start up when a difference between the first cam phaser position and the second cam phaser position is greater than a predetermined difference. A method for controlling an engine is also provided.

Internal Combustion Engine Control Device

An internal combustion engine control device is provided which can accurately estimate intake pipe temperature behavior during transient time even in an internal combustion engine embedded with a variable valve or a turbocharger. The internal combustion engine control device estimates transient behavior of the intake pipe temperature, on the basis of a flow rate (dGafs/dt) of gas flowing into the intake pipe, a flow rate (dGcyl/dt) of gas flowing from the intake pipe, an intake pipe pressure Pin, and a temporal changing rate (dPin/dt) of the intake pipe pressure. The device performs knocking control during transient time, on the basis of the estimated transient behavior of the intake pipe temperature.

System and method to estimate intake charge temperature for internal combustion engines

An engine includes an intake manifold mixing an intake air flow and an exhaust gas recirculation flow to provide an intake charge flow. A method to estimate an intake charge temperature of the intake charge includes monitoring system conditions for the engine, determining an effect of the mixing upon a specific heat coefficient of the intake charge flow based upon the monitored system conditions, estimating the intake charge temperature based upon the effect of the mixing upon the specific heat coefficient of the intake charge flow and the monitored system conditions, and controlling the engine based upon the estimated intake charge temperature.

Method and system for adjusting port throttles

An engine system and method for improving engine starting are disclosed. In one example, two engine cylinder port throttles are adjusted differently during engine starting. The system and method may improve engine torque control during an engine start.

NOx EMISSION ESTIMATION METHOD AND ARRANGEMENT

A NO x emission estimation method and arrangement for a diesel engine for estimating the amount of NO x generated in a combustion chamber of the diesel engine. The method comprises the steps of: providing values for speed and load by measuring the engine speed and the fuel injection amount; providing a base NO x value from an engine speed-load resolved reference NO x map; defining and providing emission influencing input parameters by measuring corresponding signal values; calculating a deviation between at least one emission influencing input parameter and a speed-load resolved reference value for the at least one emission influencing input parameter; multiplying the calculated deviation with an individual value from an individual speed-load resolved weight map for the at least one emission influencing input parameter, thereby creating an emission influencing input parameter related correction for the at least one emission influencing input parameter; adding and summarizing the at least one emission influencing input parameter related correction to the base NO x value and thereby obtaining an estimated NO x mass flow value.

Control device for internal combustion engine

The present invention relates to a control device for an internal combustion engine including: a first control subject 52 and a second control subject 35 D respectively capable of directly controlling a first control amount Regr and a second control amount Pim interacting with each other; a means for setting a target value of the first control amount as a first target control amount and setting a target value of the second control amount as a second target control amount; and a means for controlling the first control amount at the first target control amount and controlling the second control amount at the second target control amount. Further, in the present invention, a first target control amount TRegr is set as the target value of the first control amount capable of controlling the first control amount with a predetermined followability taking account of at least one of a first operation speed Krie, Krde as the operation speed of the first control subject and a degree of influence Ksee of the first control subject on the first control amount and at least one of a second operation speed Kriv, Krdv as the operation speed of the second control subject and a degree of influence Ksev of the second control subject on the first control amount.

Sensor device for detecting a flow property of a fluid medium

A sensor device for detecting at least one flow property of a fluid medium. The sensor device includes at least one sensor housing, in which at least one electronic module having at least one flow sensor for detecting the flow property is accommodated. The electronic module is at least partially accommodated in at least one electronic space. Furthermore, at least one pressure sensor and at least one humidity sensor are accommodated inside the sensor housing. The pressure sensor and also the humidity sensor are at least partially accommodated in at least one sensor space, which is designed separately from the electronic space.

Control device for internal combustion engine with supercharger

An object of the present invention is to prevent hunting of a throttle in a region in which a throttle upstream pressure and a throttle downstream pressure become substantially equal to each other in an internal combustion engine with a supercharger. For this purpose, a control device for an internal combustion engine with a supercharger provided by the present invention processes a signal of a throttle opening which is calculated by using a formula of throttling when a ratio of the throttle upstream pressure and the throttle downstream pressure has a value close to 1, and controls an operation of the throttle with the throttle opening the change speed of which is lessened as a target throttle opening.

System and method for preventing misfire during engine startup

A system according to the principles of the present disclosure includes a stop-start module and a throttle control module. The stop-start module stops an engine when a driver depresses a brake pedal while an ignition system is on and the engine is idling. The throttle control module selectively opens a throttle valve when fuel injection in the engine is stopped while the ignition system is on based on engine speed and a manifold pressure within an intake manifold. The stop-start module starts the engine when the driver releases the brake pedal.

METHOD AND SYSTEM FOR DIAGNOSING MISFIRE OF ENGINE

A system for diagnosing a misfire of an engine includes a sensing unit including at least one sensor for detecting at least one detection value associated with an operation of the engine, and an electronic control unit configured to determine whether a misfire of the engine due to exhaust valve leakage has occurred based on the detection values from the sensing unit, and perform an operation corresponding to the misfire due to exhaust valve leakage when the misfire due to exhaust valve leakage has occurred, wherein the electronic control unit a misfire code for exhaust valve leakage in a memory when the misfire due to exhaust valve leakage has occurred. 1. A system for diagnosing a misfire of an engine , comprising:a sensing unit including at least one sensor for detecting at least one detection value associated with an operation of the engine; andan electronic control unit configured to determine whether a misfire of the engine due to exhaust valve leakage has occurred based on the detection values from the sensing unit, and perform an operation corresponding to the misfire due to exhaust valve leakage when the misfire due to exhaust valve leakage has occurred,wherein the electronic control unit stores a misfire code for exhaust valve leakage in a memory when the misfire due to exhaust valve leakage has occurred.2. The system of claim 1 , wherein the electronic control unit is configured to:detect an output torque drop of the engine;control the engine by an optimal air/fuel ratio when the output torque drop of the engine is detected;count an output torque drop of the engine while controlling the engine by the optimal air/fuel ratio; anddetermine whether the misfire due to exhaust valve leakage has occurred when the output torque drop count is above a predetermined number.3. The system of claim 2 , wherein the misfire code for exhaust valve leakage comprises information on a misfire occurrence driving point where the misfire due to exhaust valve leakage has occurred ...

Charge-flow adjustment in closed-loop exhaust temperature control on dual fuel engines

Methods and systems of controlling operation of a dual fuel engine are provided, comprising determining a target exhaust temperature, sensing an actual exhaust temperature, determining an exhaust temperature deviation by comparing the actual exhaust temperature to the target exhaust temperature, comparing the exhaust temperature deviation to a threshold, adjusting at least one of an intake throttle, a wastegate, a compressor bypass valve, an exhaust throttle, a VGT and engine valve timing when the exhaust temperature deviation exceeds the threshold to control charge-flow to the engine, and continuing the adjusting until the exhaust temperature deviation is less than the threshold.

INTERNALLY COOLED HIGH COMPRESSION LEAN-BURNING INTERNAL COMBUSTION ENGINE

An internally cooled internal combustion piston engine and method of operating a piston engine is provided, with the combination of liquid water injection, higher compression ratios than conventional engines, and leaner air fuel mixtures than conventional engines. The effective compression ratio of the engines herein is greater than 13:1. The engines may employ gasoline or natural gas and use spark ignition, or the engines may employ a diesel-type fuel and use compression ignition. The liquid water injection provides internal cooling, reducing or eliminating the heat rejection to the radiator, reduces engine knock, and reduces NOx emissions. The method of engine operation using internal cooling with liquid water injection, high compression ratio and lean air fuel mixture allow for more complete and efficient combustion and therefore better thermal efficiency as compared to conventional engines. 125-. (canceled) This application is a continuation application of co-pending U.S. patent application Ser. No. 14/949,523 filed Nov. 23, 2015, which is a continuation application of U.S. patent application Ser. No. 14/598,935 filed Jan. 16, 2015, now U.S. Pat. No. 9,194,339 issued Nov. 24, 2015, which is a continuation application of U.S. patent application Ser. No. 13/444,533 filed Apr. 11, 2012, now U.S. Pat. No. 8,935,996 issued Jan. 20, 2015, which has been filed as U.S. Reissue patent application Ser. No. 15/410,356 filed Jan. 19, 2017, which application claims priority under 35 U.S.C. § 119(e) of U.S. Provisional Patent Application No. 61/474,240, filed Apr. 11, 2011, the disclosure of which is hereby incorporated by reference in its entirety.The present disclosure pertains to the field of internal combustion engines, including engines for motor vehicles, railways, ships, aircraft, or electrical power generation.This disclosure pertains to internal combustion engines that operate far more efficiently than conventional engines. The principles set forth herein can be used ...

Method for diagnosing leakage of fuel vapor purge system

A method for diagnosing leakage of a fuel vapor dual purge system is provided. The method includes determining whether an operation region of a vehicle is an operation region in which a turbocharger is operated and adjusting a flow amount of intake air flowing into the turbocharger according to an operation region in which the turbocharger is operated. A hydrocarbon collecting amount of a canister connecting fuel vapor generated in the fuel tank is calculated and a flow amount of the fuel vapor passing first and second purge lines is adjusted. A leak of the fuel vapor is diagnosed in the first purge line and the second purge line.

OPTIMIZED FUEL MANAGEMENT SYSTEM FOR DIRECT INJECTION ETHANOL ENHANCEMENT OF GASOLINE ENGINES

Fuel management system for enhanced operation of a spark ignition gasoline engine. Injectors inject an anti-knock agent such as ethanol directly into a cylinder. It is preferred that the direct injection occur after the inlet valve is closed. It is also preferred that stoichiometric operation with a three way catalyst be used to minimize emissions. In addition, it is also preferred that the anti-knock agents have a heat of vaporization per unit of combustion energy that is at least three times that of gasoline. 121-. (canceled)22. A fuel management system for a spark ignition engine , comprising:a first fueling system that uses direct injection;a second fueling system that uses port fuel injection; anda three-way catalyst configured to reduce emissions from the spark ignition engine,wherein the fuel management system is configured to provide fueling in a first torque range, the first torque range being a first range of torque values at which both the first fueling system and the second fueling system are operable throughout the first range of torque values,wherein the fuel management system is further configured such that a fraction of fueling provided by the first fueling system is higher at a highest value of torque in the first torque range than in a lowest value of torque in the first torque range,wherein the fuel management system is further configured to provide fueling in a second torque range, the second torque range being a second range of torque values at which the second fueling system is operable throughout the second range of torque values and the first fueling system is not operable throughout the second range of torque values,wherein the fuel management system is further configured such that when the system provides fueling at a torque value that exceeds the second range of torque values, the spark ignition engine is operated in the first torque range,wherein the fuel management system is further configured to increase the fraction of fueling provided ...

Engine system

An engine system includes an intake pipe, an exhaust pipe, an exhaust gas recirculation (EGR) pipe, an injection amount deriver, and a fuel injector. The intake pipe is configured to direct intake air into a combustion chamber of an engine. The exhaust pipe is configured to receive exhaust gas discharged from the combustion chamber. The EGR pipe is coupled to the exhaust pipe and the intake pipe and configured to recirculate the exhaust gas into the intake pipe as EGR gas. The injection amount deriver is configured to derive a target injection amount of fuel using a mass of air contained in the EGR gas or a mass of fuel contained in the EGR gas and using a preset target air excess coefficient. The fuel injector is configured to inject an amount of fuel corresponding to the target injection amount derived by the injection amount deriver into the combustion chamber.

ENGINE WITH EXHAUST TURBOCHARGER

An engine with an exhaust turbocharger includes: an exhaust bypass passage connected to an exhaust passage and bypassing a turbine of the exhaust turbocharger; a waste gate valve configured to open and close the exhaust bypass passage; a throttle valve disposed in an intake passage; a first pressure sensor and a second pressure sensor disposed upstream and downstream of the throttle valve in the intake passage; and a valve open-close control unit configured to calculate a pressure difference on the basis of pressure values detected by the first pressure sensor and the second pressure sensor, close the waste gate valve if the pressure difference is smaller than a threshold which is set in advance, and open the waste gate valve if the pressure difference is greater than the threshold. 14-. (canceled)5. An engine with an exhaust turbocharger , comprising:an exhaust bypass passage connected from an inlet of the exhaust turbocharger in an exhaust passage to an outlet of the exhaust turbocharger, bypassing a turbine of the exhaust turbocharger;a waste gate valve configured to regulate an engine output by opening and closing the exhaust bypass passage;a throttle valve disposed in an intake passage between the exhaust turbocharger and the engine and configured to control an intake amount to the engine; anda valve open-close control unit configured to calculate a pressure difference across the throttle valve, close the waste gate valve if the calculated pressure difference is smaller than a threshold which is set in advance, and open the waste gate valve if the calculated pressure difference is greater than the threshold,wherein the threshold is set to be constant in a region where an engine load is high, and is set to be a threshold greater than the constant threshold in a region where the engine load is low.6. The engine with an exhaust turbocharger according to claim 5 ,wherein the valve open-close control unit is configured to control an opening degree of the waste gate ...

Engine control device

An engine includes a dynamo-electric machine which generates electricity by the rotation of the engine; a secondary battery which stores electricity generated by the dynamo-electric machine; an electric supercharger including an electric compressor for supercharging intake air into combustion chambers; and a mechanical supercharger including an exhaust turbine configured to be driven by exhaust gas in the exhaust passage, and a mechanical compressor configured to supercharge intake air into the combustion chamber. An ECU (50) includes a remaining charge detector for detecting the remaining amount of charge of the secondary battery; and a supercharge control means for adjusting the ratio between a supercharging pressure by the electric supercharger and a supercharging pressure by the mechanical supercharger according to the remaining amount of charge of the secondary battery.

Evap system with valve to improve canister purging

Systems and methods are provided for an evaporative emissions control system. In one example, a system for an engine may comprise a fuel vapor canister, a mixing valve positioned in a fresh air line upstream of the vapor canister, and an actuator physically coupled to the mixing valve for adjusting a position of the mixing valve to increase turbulence in air entering the vapor canister. The position of the mixing valve may be adjusted to increase an amount of turbulence in air entering the fuel vapor canister.

ON-BOARD DIAGNOSTICS OF A TURBOCHARGER SYSTEM

A turbocharger system () of a combustion engine () comprises a turbocharger turbine () operable by exhaust gases, a valve () configured to control gas flow of pressurized gas from a pressurized gas reservoir () to the turbocharger turbine (), and a sensor (). Turbocharger system operation comprises injecting a test pulse of pressurized gas from the pressurized gas reservoir () to drive the turbocharger turbine () by means of controlling the valve (), detecting an impact of injected pressurized gas on the turbocharger turbine () by means of the sensor (), collecting data from the sensor (), and diagnosing the turbocharger system () by evaluating an operational response of the turbocharger turbine () as a result of the injected test pulse of pressurized gas, based on the collected data. 2. A method according to claim 1 , characterized by that the step of evaluating the operational response of the turbocharger turbine comprises the further step ofcomparing the data collected after the test pulse has been injected to data collected before the test pulse is injected.3. (canceled)5. A method according to claim 4 , characterized by the further steps of when a current delay time has been determined claim 4 ,injecting a control pulse of pressurized gas from the pressurized gas reservoir to drive the turbocharger turbine, wherein the control pulse is longer than the current delay time,detecting impact of injected pressurized gas on the turbocharger turbine by means of the sensor,collecting data from the sensor, andevaluating if the operational response as a result of the injected control pulse indicates that the turbocharger system operates as expected.6. A method according to claim 4 , characterized by the further step ofstoring current delay time as a stored system delay time, whereby stored system delay time is used to optimize operation of the turbocharger system.7. A method according to claim 6 , characterized by the further step ofcorrelating and storing the stored ...

VEHICLE TURBOCHARGER SYSTEMS AND METHODS WITH IMPROVED AFTERTREATMENT ACTIVATION

A turbocharger system for an engine of a vehicle includes a variable geometry turbine configured to receive exhaust gas from the engine. The variable geometry turbine includes adjustable vanes and a vane actuator to adjust the adjustable vanes between at least an open position and a closed position. The turbocharger further includes an intake duct configured to receive intake air; a first compressor rotationally coupled to the variable geometry turbine and fluidly coupled to the intake duct to compress at least a first portion of the intake air; an electric compressor fluidly coupled to the intake duct to selectively compress at least a second portion of the intake air; and a manifold conduit fluidly coupled to the first compressor and the electric compressor and configured to receive and direct the first and second portions of the intake air to a manifold of the engine. 1. A turbocharger system for an engine of a vehicle , comprising:a variable geometry turbine configured to receive exhaust gas from the engine, the variable geometry turbine including adjustable vanes and a vane actuator to adjust the adjustable vanes between at least an open position and a closed position;an intake duct configured to receive intake air;a first compressor rotationally coupled to the variable geometry turbine and fluidly coupled to the intake duct to compress at least a first portion of the intake air;an electric compressor fluidly coupled to the intake duct to selectively compress at least a second portion of the intake air; anda manifold conduit fluidly coupled to the first compressor and the electric compressor and configured to receive and direct the first and second portions of the intake air to a manifold of the engine.2. The turbocharger system of claim 1 , further comprising an electronic control unit configured to control operation of at least the vane actuator and the electric compressor.3. The turbocharger system of claim 2 , wherein the electronic control unit includes a ...

SENSOR ARRANGEMENT OF INTERNAL COMBUSTION ENGINE

A sensor arrangement of an internal combustion engine includes an intake duct including one or more curved parts bent or curved and connecting an intercooler and a throttle; and a pressure sensor provided on the intake duct and configured to detect a pressure in the intake duct. The pressure sensor includes a detector disposed close to an outside curved portion of a curved part. 1. A sensor arrangement of an internal combustion engine comprising:an intake duct including one or more curved parts bent or curved and connecting an intercooler and a throttle; anda pressure sensor provided on the intake duct and configured to detect a pressure in the intake duct,wherein the pressure sensor includes a detector disposed close to an outside curved portion of a curved part.2. The sensor arrangement according to claim 1 ,wherein the curved part at the lowermost downstream position of the intake duct has an outside curved portion and an inside curved portion,wherein the curved part has an imaginary straight line connecting the vertex of the outside curved portion and the vertex of the inside curved portion,wherein the curved part has an imaginary perpendicular bisector of the imaginary straight line, andwherein the pressure sensor includes an detector disposed closer to the outside curved portion than the imaginary perpendicular bisector.3. The sensor arrangement according to claim 2 ,wherein one curved portion of the outside curved portion and the inside curved portion has a constant curvature,wherein said one curved portion has a starting point and an ending point of a curve, andwherein the center point of the starting point and the ending point is set to a reference point of the imaginary straight line.4. The sensor arrangement according to claim 1 ,wherein the detector is provided outside of an outside wall line of a downstream end of the intake duct connected to the throttle.5. The sensor arrangement according to claim 2 ,wherein the detector is provided outside of an ...

A METHOD FOR CONTROLLING AN INTERNAL COMBUSTION ENGINE, A COMPUTER PROGRAM, A COMPUTER READABLE MEDIUM, A CONTROL UNIT, AN INTERNAL COMBUSTION ENGINE, AND A VEHICLE

The invention relates to a method to control an internal combustion engine. The internal combustion engine comprises a cylinder, an exhaust guide arranged to guide an exhaust flow from the cylinder through a turbine, and a bypass guide arranged to bypass a bypass flow from the cylinder past the turbine. The method comprises the step to determine a value of at least one engine operation parameter. The method is characterized by the step to determine a target value of an exhaust performance parameter depending on the determined engine operation parameter value. Further, the method comprises, depending on the determined target exhaust performance parameter value, the step to control the exhaust flow through the exhaust guide and the step to control the bypass flow through the bypass guide. 2. A method according to claim 1 , comprising:determining a current exhaust performance parameter value, andcontrolling the exhaust flow through the exhaust guide depending on a deviation of the determined current exhaust performance parameter value from the determined target exhaust performance parameter value; and/orcontrolling the bypass flow through the bypass guide depending on a deviation of the determined current exhaust performance parameter value from the determined target exhaust performance parameter value.3. A method according to comprising:determining an engine speed value and/or determining an engine load value, anddetermining the target exhaust performance parameter value depending on the determined engine speed value and/or the determined engine load value.4. A method according to comprising:determining a coolant temperature value and/or determining an ambient temperature value and/or determining an exhaust temperature value, andchoosing a value map for determining the target exhaust performance parameter value depending on the determined coolant temperature value and/or the determined ambient temperature value and/or the determined exhaust temperature value, and/ ...

SYSTEM AND METHOD FOR OPERATING AN ENGINE IN A FUEL CUT-OUT MODE

Methods and systems for operating an engine that includes adjustable poppet valve timing and an exhaust gas recirculation valve are described. In one example, the exhaust gas recirculation valve is opened and the timing of the poppet valves is retarded so that an amount of fresh air that is pumped by the engine to an after treatment device may be reduced. 1. An engine operating method , comprising:adjusting intake valve closing timing and closing an exhaust gas recirculation valve of an engine via a controller in response to an engine exiting a fuel cut-out mode.2. The engine method of claim 1 , further comprising adjusting a throttle of the engine in response to exiting the fuel cut-out mode claim 1 , the throttle adjusted to meet a driver demand torque.3. The engine method of claim 1 , where adjusting intake valve closing timing includes advancing intake valve closing timing.4. The engine method of claim 1 , further comprising activating one or more cylinders via injecting fuel to the one or more cylinders in response to the an engine exiting the fuel cut-out mode.5. The engine method of claim 1 , where the exhaust gas recirculation valve is included in a high pressure exhaust gas recirculation system.6. The engine method of claim 1 , where the exhaust gas recirculation valve is included in a low pressure exhaust gas recirculation system.7. The engine method of claim 1 , where the engine exits the fuel cut-out mode in response to a position of a pedal.8. The engine method of claim 1 , where the exhaust gas recirculation valve is partially closed.9. An engine system claim 1 , comprising:an engine including a high pressure exhaust gas recirculation (EGR) valve and poppet valves; anda controller including executable instructions stored in non-transitory memory that cause the controller to close the high pressure EGR valve and adjust timing of the poppet valves in response a pedal being applied while the engine is rotating without being fueled following an engine stop ...

OPTIMIZED FUEL MANAGEMENT SYSTEM FOR DIRECT INJECTION ETHANOL ENHANCEMENT OF GASOLINE ENGINES

Fuel management system for enhanced operation of a spark ignition gasoline engine. Injectors inject an anti-knock agent such as ethanol directly into a cylinder. It is preferred that the direct injection occur after the inlet valve is closed. It is also preferred that stoichiometric operation with a three way catalyst be used to minimize emissions. In addition, it is also preferred that the anti-knock agents have a heat of vaporization per unit of combustion energy that is at least three times that of gasoline. 1. A fuel management system for spark ignition engine where the fuel management system controls fueling from a first fueling system that directly injects fuel into at least one cylinder as a liquid and increases knock suppression by evaporative cooling and from a second fueling system that injects fuel into a region outside of the cylinder;and where there is a range of torque where both fueling systems are used at the same value of manifold pressure;and where a fraction of fuel in the cylinder that is introduced by the first fueling system increases with increasing manifold pressure so as to prevent knock by providing increased knock resistance;and where the fuel management system controls the change in the fraction of fuel introduced by the first fueling system using closed loop control that utilizes a sensor that detects knock and where open loop control is also used;and where the open loop control uses an engine map lookup table;and where open loop control is used during transients.2. The fuel management system of where the maximum knock suppression that is employed is provided by a combination of fueling from the first and second fueling systems.3. The fuel management system of or where use of the second fueling system in addition to the first fueling system is employed to obtain combustion stability.4. The fuel management system of where fuel from the first fueling system is introduced when the engine torque is above a selected value.5. The fuel ...

METHOD OF DETECTING ENGINE TUNING OF VEHICLE

A method of detecting illegal tuning of the vehicle may include obtaining and storing, by a controller, at least one of learning information including a variable value and a control value and engine state information at a time of controlling the vehicle while the vehicle is driven, as a learning value; comparing, by the controller, a learning value, which is newly obtained over time, with a prestored previous learning value; determining, by the controller, that a tuning chip for changing component performance in the vehicle is mounted when the learning value is changed and there remains a difference between the obtained learning value and the prestored previous learning value at a predetermined level or higher for a predetermined period of time; and creating and storing, by the controller, a tuning detection code when it is determined that the tuning chip is mounted. 1. A method of detecting tuning of a vehicle , the method comprising:obtaining and storing, by a controller, at least one of learning information including a variable value and a control value and engine state information at a time of controlling the vehicle while the vehicle is driven, as a learning value;comparing, by the controller, a learning value, which is newly obtained over time, with a prestored previous learning value;determining, by the controller, that a tuning chip for changing component performance in the vehicle is mounted when the learning value is changed and there remains a difference between the obtained learning value and the prestored previous learning value at a predetermined level or higher for a predetermined period of time; andcreating and storing, by the controller, a tuning detection code when it is determined that the tuning chip is mounted.2. The method of claim 1 , wherein the variable value and the control value are a variable value and a control value at a time of controlling a turbocharger and an engine in a turbocharged vehicle claim 1 , and the tuning chip for changing ...

METHOD OF CLEANING A CHARGE AIR COOLER AND AN INTERNAL COMBUSTION ENGINE

The present disclosure relates to a turbocharged internal combustion engine which will flush dirt periodically from the heat exchange surfaces of the LT-charge air cooler by using water condensed on the heat exchange surfaces for the flushing. 114.-. (canceled)15. A method of cleaning a charge air cooler of a turbocharged internal combustion engine , the engine having:a cylinder block with at least one cylinder;at least one cylinder head;an exhaust manifold arranged in connection with the at least one cylinder head;a charge air receiver arranged in connection with the at least one cylinder head;at least one turbocharger with a turbine connected to the exhaust gas manifold and a compressor connected to the charge air receiver;a high temperature (HT-) charge air cooler and a low temperature (LT-) charge air cooler arranged between the compressor and the charge air receiver, the charge air coolers having heat exchange surfaces;the LT-charge air cooler being a part of an LT-cooling liquid circuit having, in addition to the LT-charge air cooler, at least a central cooler and a circulating pump;a control unit for controlling the temperature of the charge air in relation to its dew point, the control unit receiving information on the temperature, pressure and humidity of the charge air; anda first three-way valve provided in the LT-cooling liquid circuit downstream of the LT-charge air cooler, the first three-way valve being configured for receiving commands from the control unit to control flow of cooling liquid from the circulating pump to the central cooler either directly or via the LT-charge air cooler, sending periodically commands to the three-way valve to throttle direct communication from the circulating pump to the central cooler by forcing such an amount of cooling liquid to flow from the central cooler via the circulating pump to the LT-charge air cooler to reduce temperature of heat exchange surfaces of the LT-charge air cooler below the dew point of the ...

Stop control apparatus for internal combustion engine

A stop control apparatus ( 100 ) for an internal combustion engine performs stop control of a three-or-less cylinder internal combustion engine ( 200 ). The stop control apparatus for the internal combustion engine is provided with: a determining device ( 161 ) configured to determine a compression stroke immediately before the internal combustion engine stops; and a throttle valve controlling device ( 168 ) configured to control an opening degree of a throttle valve ( 208 ) to be a predetermined opening degree while an intake valve ( 211 ) is closed in all cylinders, in the compression stroke immediately before the internal combustion engine stops, which is determined by the determining device. This reduces an influence of an intake negative pressure in an intake stroke, and makes it possible to preferably control the crank angle when the engine stops, even in the three-or-less cylinder internal combustion engine.

SYSTEM AND METHOD FOR AVOIDING COMPRESSOR SURGE DURING CYLINDER DEACTIVATION OF A DIESEL ENGINE

A system and method for improving the functioning of a turbocharged diesel engine equipped with a cylinder deactivation system includes detecting when the turbocharged diesel engine is at risk of compressor surge, and then delaying the implementation of the cylinder deactivation. The delay may be a set period of time, or it may be determined by performing a set of instructions effective for estimating changes in intake manifold pressures over time if cylinders are deactivated, and then comparing the intake manifold pressure estimates to acceptable intake manifold pressure information. A formula for performing the required estimates is provided. 1. A method for improving the functioning of a turbocharged diesel engine equipped with a cylinder deactivation system , the method comprising detecting when the turbocharged diesel engine is at risk of compressor surge , and then delaying part or all of the cylinder deactivation until risk of compressor surge is not indicated.2. A method according to wherein said detecting is accomplished by calculating estimates of changes in intake manifold pressure for specific CDA conditions claim 1 , and then comparing those estimates to the compressor surge line for the engine to determine whether deactivation of one or more cylinders will avoid compressor surge.3. A method according to wherein the method further includes moving into cylinder deactivation as quickly as possible while avoiding compressor surge.5. A method according to wherein the engine cylinder deactivation occurs as a series of individual cylinder deactivations until an appropriate number of engine cylinders have been deactivated.6. A method according to wherein the method comprises:detecting when the turbocharged diesel engine is at risk of compressor surge by calculating a first set of estimates of changes in intake manifold pressures over time;comparing the first set of estimates to information regarding the compressor surge conditions of the engine to determine ...

VEHICLE CONTROLLER

A vehicle controller includes a controlling section configured to control a torque applying mechanism. The controlling section is configured to execute a negative torque control by using the torque applying mechanism when execution conditions are satisfied. The execution conditions include a condition that an increase amount per predetermined time of the boost pressure has become greater than a preset boost pressure determination value. The negative torque control is a control to set the rotational torque applied to the crankshaft by the torque applying mechanism to a negative value that is on the negative side of a value immediately before the start of the negative torque control. 1. A vehicle controller configured to control a vehicle , wherein an internal combustion engine including a forced-induction device,', 'a boost pressure sensor that detects, as a boost pressure, a pressure in a section of an intake passage of the internal combustion engine on a downstream side of the forced-induction device, and', 'a torque applying mechanism that applies a rotational to a crankshaft of the internal combustion engine,, 'the vehicle includes'}the controller comprising a controlling section configured to control the torque applying mechanism,the controlling section is configured to execute a negative torque control by using the torque applying mechanism when execution conditions are satisfied, the execution conditions including a condition that an increase amount per predetermined time of the boost pressure has become greater than a preset boost pressure determination value, andthe negative torque control is a control to set the rotational torque applied to the crankshaft by the torque applying mechanism to a negative value that is on a negative side of a value immediately before start of the negative torque control.2. The vehicle controller according to claim 1 , wherein the execution conditions include a condition that an increase amount per predetermined time of an ...

ENGINE CONTROLLER AND ENGINE CONTROL METHOD

A first intake air amount an engine is calculated based on a detected value of an intake air flow rate of an air flowmeter. A second intake air amount is calculated based on any one of a detected value of an intake pipe pressure and a throttle opening degree instead of the detected value of the intake air flow rate. When it is determined that the intake pulsation is not large, a difference amount of the second intake air amount from the first intake air amount is calculated. A corrected second intake air amount, which is a sum of the second intake air amount and the difference amount, is set as an intake air amount calculated value when it is determined that the intake pulsation is large. 1. An engine controller configured to execute:a first intake air amount calculation process for calculating a first intake air amount, which serves as a calculated value of an intake air amount of an engine, based on a detected value of an intake air flow rate of an air flowmeter;a second intake air amount calculation process for calculating a second intake air amount, which serves as a calculated value of an intake air amount of the engine, based on any one of a detected value of an intake pipe pressure and a throttle opening degree instead of the detected value of the intake air flow rate;a determination process for determining whether intake pulsation in an intake passage of the engine is large;a difference amount calculation process for, when determining in the determination process that the intake pulsation is not large, calculating a difference amount of the second intake air amount from the first intake air amount; setting the first intake air amount as an intake air amount calculated value of the engine when determining in the determination process that the intake pulsation is not large, and', 'setting a corrected second intake air amount, which is a sum of the second intake air amount and the difference amount, as the intake air amount calculated value when determining in ...

FUEL SUPPLY CONTROL SYSTEM FOR V-TYPE TWO-CYLINDER GENERAL PURPOSE ENGINE

A fuel supply control system for a V-type two-cylinder general purpose engine according to the present disclosure, in a V-type two-cylinder general purpose engine including one fuel injection valve in a throttle body disposed upstream via an intake manifold connected to a cylinder head of each cylinder, changes an injection frequency or an operation timing of the fuel injection valve in accordance with an engine operation state detected by a detection unit. 1. A fuel supply control system for a V-type two-cylinder general purpose engine , comprising a fuel injection valve in a throttle body disposed upstream via an intake manifold connected to a cylinder head of each cylinder ,wherein, in the fuel supply control system, an injection frequency or an operation timing of the fuel injection valve is changed in accordance with an engine operation state detected by a detection unit.2. The fuel supply control system for a V-type two-cylinder general purpose engine according to claim 1 ,wherein the detection unit to detect the engine operation state includes an intake pressure sensor, an engine rotation sensor, an engine temperature sensor, and an oxygen sensor.3. The fuel supply control system for a V-type two-cylinder general purpose engine according to claim 1 ,wherein in a case where an injection frequency of the fuel injection valve is once or twice, and a shift criteria is shifted from once to twice, an OR condition is applied, andin a case where the injection frequency of the fuel injection valve is shifted from twice to once, an AND condition is applied.4. The fuel supply control system for a V-type two-cylinder general purpose engine according to claim 1 ,wherein in a case where an injection frequency of the fuel injection valve is twice, an injection is performed from an exhaust stroke to an intake stroke of each cylinder, andin a case where an injection frequency of the fuel injection valve is once, the injection starts in the middle of the intake stroke of each ...

CONTROL DEVICE FOR AN INTERNAL COMBUSTION ENGINE

In a control device for an internal combustion engine, when a target pre/post compressor pressure ratio calculated by a target pre/post compressor pressure ratio calculation part is more than a turbine-limit-time pre/post compressor pressure ratio calculated by a turbine-limit-time pre/post compressor pressure ratio calculation part, an upper limit of the target pre/post compressor pressure ratio is limited by the turbine-limit-time pre/post compressor pressure ratio, and a change rate of the target pre/post compressor pressure ratio is limited by a change rate limit value during a change rate limitation period after upper limit limitation processing starts, thereby preventing the target pre/post compressor pressure ratio from being suddenly fluctuated by a sudden fluctuation in a compressor passage flow rate, and suppressing the occurrence of the over rotation of the turbine and the control hunting. 1. A control device for an internal combustion engine , which is configured to control an internal combustion engine provided for a vehicle , a throttle valve, which is provided in an intake passage of the internal combustion engine;', 'an air flow sensor, which is configured to detect an intake air flow rate in the intake passage of the internal combustion engine;', 'a turbocharger, which includes a turbine provided in an exhaust passage of the internal combustion engine, and a compressor provided in the intake passage of the internal combustion engine and configured to rotate integrally with the turbine;', 'an exhaust bypass passage, which is configured to allow an upstream side and a downstream side of the turbine to communicate to each other;', 'a wastegate valve, which is provided in the exhaust bypass passage, and is configured to adjust a flow rate of exhaust gas of the internal combustion engine, which flows through the exhaust bypass passage;', 'an actuator, which is configured to drive the wastegate valve to change an open position of the wastegate valve; and ...

Internal combustion engine control apparatus

Fuel injection control of an internal combustion engine requires an optimized fuel amount that can be burned completely with oxygen in intake air to be supplied, but the oxygen concentration in the atmospheric air is affected by humidity. By separately calculating a dry air flow rate that directly affects the oxygen amount and a humidity flow rate that is a change factor of the oxygen concentration in the intake air of the internal combustion engine, the fuel can be supplied to the cylinder of the internal combustion engine at an optimized air-fuel ratio. In addition, highly precise control involving EGR for flowback of a part of the exhaust gas flowing in the exhaust pipe to the intake pipe can also be achieved.

Internal combustion engine and method to increase the temperature of a liquid in the internal combustion engine

A method, controller, and internal combustion engine including the controller and operable in accordance with the method by: determining a temperature of a working liquid in an engine block circuit ( 31, 35 ) of the internal combustion engine ( 10 ), the working liquid comprising a cooling liquid or a lubrication liquid; operating the internal combustion engine ( 10 ); engaging a thermal load responsive to the temperature of the liquid being below a first temperature threshold, wherein engaging the thermal load comprises at least one of increasing a pumping load of the internal combustion engine ( 10 ), or changing an air/fuel ratio, thereby adding heat to the engine block circuit ( 31, 35 ); controlling the thermal load as a function of the temperature of the liquid; and disengaging at least a portion of the thermal load responsive to the temperature of the liquid being above the low temperature limit.

SYSTEM AND METHOD FOR REDUCING COLD START EMISSIONS OF A MOTOR VEHICLE

The present disclosure provides a system for reducing cold start emissions of a motor vehicle. A brushless DC motor is coupled to an engine for cranking the engine. In response to receiving a cold start signal from a cold start actuator, the motor controller activates the brushless DC motor to crank the engine for a cold start duration and increase fuel pressure. In response to a motor controller receiving an auto start signal from an auto start actuator, the motor controller activates the brushless DC motor to crank the engine for an auto start duration that is shorter than the cold start duration. In response to determining that the cold start duration or the auto start duration has expired, an engine controller activates the fuel delivery system to deliver fuel to the engine. 1. A system for reducing cold start emissions for a motor vehicle , the system comprising:an internal combustion engine;a brushless DC motor coupled to the engine and configured to crank the engine;a fuel delivery system coupled to the engine and configured to deliver fuel to the engine, wherein the engine drives the fuel delivery system to increase the fuel pressure;a cold start actuator configured to generate a cold start signal;an auto start actuator configured to generate an auto start signal;a motor controller coupled to the brushless DC motor, wherein the motor controller is further coupled to the cold start actuator to receive the cold start signal from the cold start actuator, and wherein the motor controller is further coupled to the auto start actuator to receive the auto start signal from the auto start actuator; andan engine controller coupled to the cold start actuator to receive the cold start signal from the cold start actuator, wherein the engine controller is further coupled to the auto start actuator to receive the auto start signal from the auto start actuator, and wherein the engine controller is further coupled to the fuel delivery system;wherein, in response to the ...

ENGINE BRAKE CONTROL ACCORDING TO ENGINE OPERATING PARAMETERS

An engine brake controller may obtain a performance characteristic of an engine. The engine brake controller may determine, based on the performance characteristic of the engine, that engine braking is enabled to control the engine. The engine brake controller may monitor a set of operating parameters of the engine. The engine brake controller may determine that operating values of the set of operating parameters satisfy corresponding thresholds of the set of operating parameters. The engine brake controller may determine, based on the operating values satisfying the corresponding thresholds, an engine braking configuration associated with activating engine braking of a set of cylinders of the engine. The set of cylinders may be a proper subset of a total quantity of cylinders of the engine. The engine brake controller may cause the engine braking to be applied to the set of cylinders to increase a temperature of exhaust gas from the engine. 1. A method , comprising:obtaining a performance characteristic of an engine;determining, based on the performance characteristic of the engine, that engine braking is enabled to control the engine;identifying, based on the performance characteristic, a set of operating parameters of the engine that are associated with the performance characteristic;monitoring the set of operating parameters to obtain operating values;determining that the operating values satisfy corresponding thresholds of the set of operating parameters;{'claim-text': 'wherein the set of cylinders is a proper subset of a total quantity of cylinders of the engine; and', '#text': 'determining, based on the operating values satisfying the corresponding thresholds, an engine braking configuration associated with activating engine braking of a set of cylinders of the engine to increase a temperature of exhaust gas from the engine,'}causing the engine braking to be applied to the set of cylinders to increase the temperature of the exhaust gas from the engine.2. The ...

SYSTEM AND METHOD FOR CONTROLLING COMPRESSOR OF COLD-START VEHICLE

A system for controlling a compressor may include an engine controller that controls a fuel injection amount corresponding to an engine load and an opening amount of a throttle by reflecting a required torque required for an air conditioner (A/C), an operation information detector for detecting operation information according to driving state of the vehicle, a compressor that generates pressure during operation of the A/C, an air conditioner relay which is turned on when the air conditioner operates and is turned off when the A/C is stopped, and a controller which determines an engine negative pressure of an intake manifold, and when the cooling water temperature is lower than the predetermined temperature and the intake manifold pressure is lower than the first threshold value, a cold-start intake manifold negative pressure insufficient event is generated to reduce the A/C duty in accordance with the entry into a negative pressure recovery mode. 1. A system for controlling a compressor of a cold-start vehicle , comprising:an engine control unit (ECU) that controls a fuel injection amount corresponding to an engine load and an opening amount of a throttle according to a required torque required for an air conditioner (A/C);an operation information detector for detecting operation information according to driving state of the cold-start vehicle;a compressor that generates pressure through operation of a piston in a cylinder utilizing power of an engine during operation of the air conditioner;an air conditioner relay which is turned on when the air conditioner operates and is turned off when the air conditioner is stopped in a response to an operation signal of the ECU; anda controller which is connected to the ECU and determines an engine negative pressure of an intake manifold stored in a brake booster at a value obtained by subtracting the engine negative pressure from atmospheric pressure detected by the operation information detector, and when a cooling water ...

SYSTEMS AND METHODS FOR IDENTIFYING A STUCK OPEN EXHAUST GAS RECIRCULATION VALVE

Methods and systems are provided for determining whether an exhaust gas recirculation (EGR) valve is degraded and being held open in a vehicle system. In one example, a method may include, in response to an engine pull-down request, closing a throttle coupled to an intake manifold of the engine, closing the EGR valve, propelling the vehicle via an electric motor, and checking operation of the EGR valve based on both intake manifold pressure and exhaust pressure. For example, if the intake manifold pressure does not decrease by a threshold amount relative to the exhaust pressure, EGR valve degradation may be indicated. 1. A method , comprising:propelling a vehicle by an engine having a throttle coupled to an intake manifold;recirculating a portion of engine exhaust to the intake manifold through an exhaust gas recirculation (EGR) valve; andchecking operation of the EGR valve, based on both intake manifold pressure and exhaust pressure, after closing the throttle and the EGR valve when propelling the vehicle with an electric motor while the engine spins down to rest.2. The method of claim 1 , wherein the checking operation of the EGR valve commences after the vehicle transitions from being propelled by the engine to being propelled by the electric motor and concludes when the engine is at rest.3. The method of claim 2 , further comprising shutting off fuel supplied to the engine during the checking operation of the EGR valve.4. The method of claim 1 , wherein the EGR valve is not coupled to a position sensor.5. The method of claim 1 , wherein the EGR valve is positioned by a stepper motor.6. The method of claim 1 , wherein the checking operation of the EGR valve includes one or more of determining a difference between the intake manifold pressure and the exhaust pressure and determining a ratio of the intake manifold pressure to the exhaust pressure.7. The method of claim 6 , further comprising:in response to one or more of the difference between the intake manifold ...

METHOD AND DEVICE FOR REGULATING THE PRESSURE OF THE COMBUSTION GAS AND/OR EXHAUST GAS OF A MACHINE

A method and a device for regulating the pressure of the combustion gas and/or exhaust gas of a machine, in particular an internal combustion engine. The combustion gas is supplied to the machine via a supply line and is discharged via an exhaust gas line, and the supply line and/or the exhaust gas line has a regulating device, the regulating device delimiting a pressure-regulated section of the supply line and/or the exhaust gas line, and wherein the pressure in each pressure-regulated section is measured at more than one point. 1. A method for regulating pressure of a combustion gas and/or exhaust gas of a machine , the combustion gas being supplied to the machine via a supply line and being discharged via an exhaust gas line , the supply line and/or the exhaust gas line having a regulating device , the regulating device delimiting a pressure-regulated section of the supply line and/or of the exhaust gas line ,whereinin each pressure-regulated section the pressure is measured at more than one point in order to reduce the effects of resonances, fluctuations and pressure waves on the pressure measurement, the pressure in each pressure-regulated section being adjusted on the basis of a weighted arithmetic mean value of the pressures measured at a plurality of points in the pressure-regulated section by regulation of the regulating device.2. The method according to claim 1 , wherein the pressure in each pressure-regulated section is kept substantially constant.3. The method according to claim 1 , wherein the pressure regulation in the pressure-regulated section in question is carried out on a basis of a time mean value of the measured pressures claim 1 , the mean value being formed over a period of time which is equal to or greater than a period of a resonance of a standing pressure wave in the pressure-regulated section in question.4. The method according to claim 1 , wherein the pressure in the pressure-regulated section is measured at exactly three points.5. The ...

SMALL ENGINE CONTROL SYSTEM AND METHOD FOR ENABLING THE USE OF TRADITIONAL CRANKSHAFT

An engine ignition control method and system for controlling ignition timing that computes a predicted crankshaft angular velocity based on prior computed and verified crankshaft angular velocity and acceleration and determines a capture window of the next crankshaft position sensor pickup signal for the verification of the predicted crankshaft angular velocity. The ignition control system also utilizes both crankshaft position pickup signals and the intake manifold air pressure measurements for determining the stroke of the combustion cycle in turn providing more accurately timed signals for the fuel injection and ignition systems. During engine starts, the engine ignition control system performs a series of continuous spark-triggering, determines if each spark-triggering being at the correct or incorrect point in the combustion cycle by detecting if there is any engine acceleration and adjusts the generation of the signal for the next spark-triggering accordingly. 1. A four stroke cycle internal combustion engine , comprising:a single notch crankshaft connected to said piston;a crankshaft position sensor configured to detect the single notch crankshaft rotational movements and generating periodic pickup electrical signals as the single notch crankshaft rotates during a combustion cycle, wherein one crankshaft position sensor pickup electrical signal being generated for each full rotation of the single notch crankshaft;an intake manifold air pressure sensor configured to continuously measure air pressure in an intake manifold in the engine; and continuously receiving the intake manifold air pressure measurements;', 'periodically receiving the crankshaft position sensor pickup electrical signals;', 'verifying a crankshaft angular velocity for each full rotation of the single notch crankshaft using a computed capture window of crankshaft position sensor pickup electrical signal;', 'if the current crankshaft angular velocity is verified, determining a spark advance ...

GAS ENGINE DRIVE SYSTEM AND METHOD OF CONTROLLING GAS ENGINE

A gas engine drive system includes: a gas engine including combustion chamber; a turbocharger including a compressor and turbine; a fuel injection system that injects fuel gas into intake air that is supplied from compressor to combustion chamber via an intake passage; a pressure detector detecting a charge air pressure; a temperature detector detecting the intake air's temperature; and controller controlling the fuel injection system. The controller: when required output decreases, determines the charge air pressure's lean limit based on target injection amount corresponding to required output that has decreased; if the charge air pressure is lower than or equal to the lean limit, decreases fuel injection amount to target injection amount; if the charge air pressure is higher than lean limit, brings fuel injection amount to zero. When the charge air pressure becomes lower than or equal to the lean limit, increases fuel injection amount to target injection amount. 1. A gas engine drive system comprising:a gas engine including a combustion chamber formed by a cylinder and a piston;a turbocharger including a compressor connected to the combustion chamber via an intake passage and a turbine connected to the combustion chamber via an exhaust passage;a fuel injection system that injects a fuel gas into intake air that is supplied from the compressor to the combustion chamber via the intake passage;a pressure detector that detects a charge air pressure that is a pressure of the intake air; anda controller that controls the fuel injection system, the controller calculating a target injection amount of the fuel gas in accordance with a required output, wherein when the required output decreases, determines a lean limit of the charge air pressure based on the target injection amount corresponding to the required output that has decreased;', 'if the charge air pressure detected by the pressure detector is lower than or equal to the lean limit, decreases a fuel injection ...

METHODS AND SYSTEM FOR CONTROLLING ENGINE AIRFLOW WITH AN AUXILIARY THROTTLE ARRANGED IN SERIES WITH A VENTURI AND IN PARALLEL WITH A MAIN INTAKE THROTTLE

Methods and systems are provided for progressively opening and controlling each of a fuel vapor canister purge valve (CPV), an auxiliary throttle coupled in series with a venturi, and a main intake throttle arranged in parallel with the auxiliary throttle in order to deliver a desired intake airflow or manifold vacuum to an engine intake manifold. In one example, a method may include actuating a CPV to supply airflow to the engine via a fuel vapor canister while holding closed a main throttle and an auxiliary throttle arranged in parallel with the main throttle and in series with a venturi. The method further includes progressively opening the CPV, then the auxiliary throttle, and then the main throttle to achieve a desired intake manifold pressure. 1. A method for an engine , comprising:actuating a canister purge valve (CPV) to supply airflow to the engine via a fuel vapor canister while holding closed a main throttle and an auxiliary throttle arranged in parallel with the main throttle and in series with a venturi; andas a desired intake manifold pressure increases, progressively opening the CPV, then the auxiliary throttle, and then the main throttle to achieve the desired intake manifold pressure, wherein the venturi is an ejector, wherein the auxiliary throttle is coupled upstream of a motive flow inlet of the ejector and the CPV is coupled upstream of an entraining inlet of the ejector, and wherein progressively opening the CPV, then the auxiliary throttle, and then the main throttle includes not opening the auxiliary throttle until the CPV is fully open and not opening the main throttle until both the CPV and the auxiliary throttle are fully open.2. The method of claim 1 , wherein the actuating the CPV to supply airflow to the engine via the fuel vapor canister is responsive to an engine idle condition and wherein the desired intake manifold pressure is a desired intake manifold vacuum.3. The method of claim 2 , further comprising claim 2 , in response to an ...

Method for the Combined Identification of Phase Differences of the Inlet Valve Stroke and of the Outlet Valve Stroke

Various embodiments include a method for identifying valve stroke phase differences during operation comprising: measuring dynamic pressure oscillations in the air intake tract; generating a corresponding signal; acquiring a crankshaft phase angle; acquiring the phase position and the amplitude of a signal frequency of the oscillations based on the pressure oscillation using discrete Fourier transformation; acquiring a line of an equal phase position and of equal amplitude of the signal frequency reflecting the inlet and the outlet stroke phase difference using reference lines; acquiring a common intersection point of a line of equal phase position and a line of equal amplitude by projection into a common plane; and determining the stroke phase differences and from the common intersection point. 1. A method for the combined identification of an inlet valve stroke phase difference and of an outlet valve stroke phase difference of a cylinder of a series-production internal combustion engine during operation , the method comprising:measuring dynamic pressure oscillations, assignable to the cylinder, of the intake air in the air intake tract of the respective series-production internal combustion engine during operation;generating a corresponding pressure oscillation signal based on the measured oscillation;acquiring a crankshaft phase angle signal corresponding to the measured oscillations;acquiring the phase position and the amplitude of a respectively selected signal frequency of the measured pressure oscillations in relation to the crankshaft phase angle signal based on the pressure oscillation signal, using discrete Fourier transformation;acquiring, on the basis of the acquired phase position and amplitude of the respective selected signal frequency, in each case a line of an equal phase position and of equal amplitude of the respectively same signal frequency, the line reflecting the inlet valve stroke phase difference and the outlet valve stroke phase difference, ...

RECHARGING MANAGEMENT FOR SKIPPING CYLINDERS

A variety of methods and arrangements are described for managing recharging of cylinders of an internal combustion engine during skip fire operation of the engine. In one method, a maximum allowed deactivation time for a cylinder is determined and the cylinder is recharged before the maximum allowed deactivation time is exceeded.

ENGINE SYSTEM AND METHOD FOR CONTROLLING SAME

In an engine system having a high-pressure stage turbocharger and a low-pressure stage turbocharger provided in series, a control device is configured to perform control such that when switching from multi-stage supercharging Cm to single-stage supercharging Cs, after only the exhaust bypass valve is opened, and thereafter, an intake bypass valve is opened later than at a timing at which the exhaust bypass valve is opened. 1. An engine system including: a plurality of turbochargers arranged in series; an intake bypass passage which bypasses a high-pressure stage compressor of a high-pressure stage turbocharger arranged at a downstream side of an intake passage among the plurality of turbochargers; an intake bypass valve which adjusts a flow rate of intake air passing through the intake air bypass passage; an exhaust bypass passage which bypasses a high-pressure stage turbine of the high-pressure stage turbocharger; and an exhaust bypass valve which adjusts a flow rate of exhaust gas passing through the exhaust bypass passage , comprisinga control device which controls opening-and-closing of the intake valve and the exhaust bypass valve,wherein at a time when both the intake bypass valve and the exhaust bypass valve are opened and supercharging of the high-pressure stage turbocharger is switched to a stopped state from a state where both the intake bypass valve and the exhaust bypass valve are closed and the high-pressure stage turbocharger performs supercharging, the control device performs control such that, after only the exhaust bypass valve is opened, the intake bypass valve is opened later than a timing at which the exhaust bypass valve is opened.2. The engine system according to claim 1 , further comprising:a pressure difference acquisition device which directly or indirectly acquires a pressure difference between a pressure at an upstream side and a pressure at a downstream side of the high-pressure stage compressor in the intake passage,wherein the control ...

CONTROLLER FOR INTERNAL COMBUSTION ENGINE

A controller for an internal combustion engine includes a processing circuit that performs a dither control process on condition that a temperature increase request of a catalyst is made. The processing circuit operates fuel injection valves so that during the dither control process, one or more cylinders are lean combustion cylinders in a first period and another one or more cylinders are rich combustion cylinders and so that the average value of an exhaust gas-fuel ratio is a target air-fuel ratio in a second period including the first period. The dither control process is restricted in a manner that, on condition that the rich process is performed, the degree of richening of the richest exhaust gas-fuel ratio of exhaust gas-fuel ratios in the cylinders is reduced. 1. A controller for an internal combustion engine , wherein the internal combustion engine includes a catalyst configured to purify exhaust gas discharged from a plurality of cylinders , and a plurality of fuel injection valves respectively configured to supply fuel to the plurality of cylinders , and the internal combustion engine is configured to allow oxygen to flow into the catalyst without undergoing a combustion stroke , the controller comprisinga processing circuit configured to perform a dither control process on condition that a temperature increase request of the catalyst is made, wherein the processing circuit operates the fuel injection valves so that during the dither control process, one or more of the plurality of cylinders are lean combustion cylinders and another one or more of the plurality of cylinders are rich combustion cylinders in a first period and so that an average value of an exhaust gas-fuel ratio is a target air-fuel ratio in a second period including the first period, and wherein the lean combustion cylinders are cylinders having a leaner air-fuel ratio than a stoichiometric air-fuel ratio, and the rich combustion cylinders are cylinders having a richer air-fuel ratio than ...

Method for determining the cylinder air-charge of an internal combustion engine in a non-fired operation

A method for determining the cylinder air-charge of an internal combustion engine in a non-fired operation, wherein a method for determining the cylinder air-charge in a fired operation is performed. According to the invention, provision is made that in the method for determining the cylinder air-charge in the fired operation, a correction factor is provided as a function of engine speed and engine load which adjusts the value of the cylinder air-charge determined by the method in the fired operation to the non-fired operation. Thus, the previously known methods can be improved and made more efficient, in particular in view of the deviations of up to 30% between the cylinder air-charge values in the non-fired operation and the modeled values of the fired operation.

ENGINE CONTROLLER, ENGINE CONTROL METHOD, AND MEMORY MEDIUM

An engine controller is provided. A second calculation process calculates an intake air amount without using an output of an air flow meter. A second determination process determines whether an intake air pulsation in an intake passage is great without using the output of the air flow meter. When the intake air pulsation is determined to be great by at least one of a first determination process and the second determination process, a calculation method switching process selects the calculated value of the intake air amount obtained by the second calculation process as a calculated value of the intake air amount used to determine an operation amount of an actuator. 1. An engine controller that controls an operating state of an engine through operation of an actuator provided to the engine , the engine controller is configured to perform:a first calculation process that calculates an intake air amount introduced into a cylinder of the engine, the first calculation process calculating the intake air amount based on an output of an air flow meter that detects an intake air flow rate in an intake passage of the engine;a second calculation process that calculates the intake air amount based on at least one of a detected value of an intake pipe pressure and a throttle opening degree, without using the output of the air flow meter;a first determination process that determines whether an intake air pulsation in the intake passage is great based on the output of the air flow meter;a second determination process that determines whether the intake air pulsation in the intake passage is great based on at least one of the detected value of the intake pipe pressure and the throttle opening degree, without using the output of the air flow meter; and when the intake air pulsation is not determined to be great by both of the first determination process and the second determination process, the calculation method switching process selects the calculated value of the intake air amount ...

ENGINE SYSTEM AND METHOD OF CONTROLLING A TURBOCHARGER AND TURBOCHARGER OF AN ENGINE SYSTEM

An engine system includes an internal combustion engine including an intake manifold having an inlet, variable geometry turbocharger (VGT) including a mechanical compressor having a mechanical compressor outlet fluidically connected to the intake manifold and a turbine, and an electric compressor including an electric compressor outlet fluidically connected to the intake manifold. A first sensor is arranged to detect a first fluid pressure value at the mechanical compressor outlet. A second sensor is arranged to detect a second fluid pressure value at the inlet of the intake manifold. A controller is operatively connected to first sensor and the second sensor. The controller is operable to adjust operation of at least one of the VGT and the electric compressor when one of the first fluid pressure value and the second fluid pressure value reaches a selected value. 1. An engine system comprising:an internal combustion engine including an intake manifold having an inlet;a variable geometry turbocharger (VGT) including a mechanical compressor having a mechanical compressor outlet fluidically connected to the intake manifold and a turbine;an electric compressor including an electric compressor outlet fluidically connected to the intake manifold;a first sensor arranged to detect a first fluid pressure value at the mechanical compressor outlet;a second sensor arranged to detect a second fluid pressure value at the inlet of the intake manifold; anda controller operatively connected to the first sensor and the second sensor, the controller being operable to adjust operation of at least one of the VGT and the electric compressor when one of the first fluid pressure value and the second fluid pressure value reaches a selected value.2. The engine system according to claim 1 , wherein the controller adjusts the VGT when a minimum of the first fluid pressure value and the second fluid pressure value corresponds to the selected value.3. The engine system according to claim 2 , ...

METHOD AND DEVICE FOR OPERATING AN INTERNAL COMBUSTION ENGINE

A method for ascertaining whether a combustion process is being carried out in a cylinder of an internal combustion engine, it being decided whether or not the combustion process is present as a function of a relative angle between a characteristic signature of a variable characterizing a time curve of a state variable of the internal combustion engine and a specifiable crankshaft angle. 114-. (canceled)15. A method for ascertaining whether a combustion process is being carried out in a cylinder of an internal combustion engine , the method comprising:deciding whether the combustion process is present as a function of a relative angle between a characteristic signature of a variable characterizing a time curve of an energy of the internal combustion engine and a specifiable crankshaft angle;wherein the energy includes a kinetic energy given by the rotational movement of the internal combustion engine.16. The method of claim 15 , wherein the characteristic signature is a characteristic value of a time curve of a Fourier component claim 15 , the energy.17. The method of claim 15 , wherein it is decided that the combustion process has taken place if the phase shift is within a specifiable crankshaft angular range around the specifiable crankshaft angle.18. The method of claim 17 , wherein the crankshaft angular range is situated symmetrically about the specifiable crankshaft angle.19. The method of claim 15 , wherein the kinetic energy including a rotational energy of the crankshaft and a kinetic energy of an up-and-down movement of pistons of the internal combustion engine.20. The method of claim 15 , wherein the energy also including a volume work of the gas filling in the cylinder.21. The method of claim 15 , wherein the specifiable crankshaft angle is a top dead center of the cylinder.22. The method of claim 15 , wherein the specifiable crankshaft angle being a value in an interval having an initial value and an end value claim 15 , the initial value being one of ...

ACTIVE COMBUSTION AIR INTAKE SYSTEM FOR TRUCK, TRACTOR, OR BUS VEHICLE

A combustion air intake apparatus for a truck, tractor, or bus vehicle for highway use includes an air deflecting element that is selectively deployable to cause dynamic air pressure created by vehicle motion to increase static air, pressure within the intake apparatus under appropriate conditions. Deployment or retraction of the air deflecting element is responsive to at least one of forward speed of the vehicle, air pressure downstream of an air inlet opening, or throttle position, and may further be responsive to detection of precipitation and/or particulate material. An air deflecting element may include a moveable plate or flap, moveable louvers, or a moveable duct. 1. A combustion air intake apparatus for a truck , tractor , or bus vehicle for highway use , the combustion air intake apparatus comprising:a frame defining an air inlet opening in fluid communication with the combustion air intake apparatus;at least one air deflecting element proximate to the frame, wherein the at least one air deflecting element comprises a retracted position and comprises a deployed position in which the at least one air deflecting element is arranged to deflect air into the air inlet opening while the truck, tractor, or bus vehicle is traveling in a forward direction; anda controller operatively coupled with at least one actuator to selectively deploy or retract the at least one air deflecting element, wherein the controller is configured to control deployment or retraction of the at least one air deflecting element responsive to at least one signal indicative of one or more sensed parameters; andwherein the air inlet opening is open to admit ambient air into the combustion air intake apparatus when the at least one air deflecting element is in the deployed position and when the at least one air deflecting element is in the retracted position.2. The combustion air intake apparatus of claim 1 , wherein the controller is configured to control deployment or retraction of the at ...

Method and Apparatus for Controlling a Two-Stage Air Charging System with Mixed EGR

A two-stage air charging system for an internal combustion engine with mixed exhaust gas recirculation includes a high pressure exhaust gas recirculation loop, a low pressure exhaust gas recirculation loop, an air throttle system, a turbo air charging system, and an electric air charging system. A method to control the system includes monitoring desired operating target commands and operating parameters. Feedback control signals are determined based upon the monitored desired operating target commands and the monitored operating parameters. The two-stage air charging system is controlled based on system control commands for each of the high pressure exhaust gas recirculation loop, the low pressure exhaust gas recirculation loop, the air throttle system, the turbo air charging system and the electric air charging system.

Monitoring and Control System for a Flow Duct

A monitoring and control system for a flow duct and a method for determining a component status of an operational component disposed within a flow passage of the flow duct utilizing the system are provided. In one exemplary aspect, the system includes at least two sensors that are disposed within the flow passage and configured to sense a characteristic of a fluid flowing therethrough. The sensors may be averaging sensors. Each sensor extends circumferentially about an axial centerline defined by the flow duct. The sensors are arranged in an overlapped arrangement. Particularly, the sensors extend circumferentially about the axial centerline such that the sensors physically overlap one another circumferentially. Additionally, the sensors may be disposed within the same or substantially the same plane axially. Signals generated by the sensors may be utilized to monitor and control the fluid and various operational components disposed within the flow passage. 1. A system for a flow duct defining a flow passage and an axial direction , a radial direction , and a circumferential direction , the system comprising:a first sensor extending along the circumferential direction within the flow passage; anda second sensor extending along the circumferential direction within the flow passage, wherein the first sensor extends along the circumferential direction such that at least a portion of the first sensor physically overlaps the second sensor along the circumferential direction.2. The system of claim 1 , wherein the first sensor and the second sensor both extend along the circumferential direction in the same or substantially the same plane along the axial direction.3. The system of claim 1 , wherein the system further comprises:a third sensor extending along the circumferential direction within the flow passage, wherein the third sensor extends along the circumferential direction such that the third sensor physically overlaps the first sensor along the circumferential ...

Controller for supercharger-equipped internal combustion engine and control method thereof

The objective of the present invention is to provide a controller for a supercharger-equipped internal combustion engine and a control method that can reduce man-hours for data measurement and matching, which are required to perform while the internal combustion engine and the supercharger are combined. In a controller, a target turbine flow rate for realizing a target compressor driving force is calculated; a target wastegate flow rate is calculated based on an exhaust gas flow rate and the target turbine flow rate; a target turbine-upstream pressure is calculated based on a target before/after-turbine pressure ratio for realizing the target compressor driving force and a turbine-downstream pressure; a target gate effective opening area is calculated based on the target wastegate flow rate, the target before/after-turbine pressure ratio, and the target turbine-upstream pressure; then, a gate valve control value is calculated.

Intake device for internal combustion engine with supercharger

A compressor ( 5 ) of a turbo supercharger ( 3 ) is located between an air flow meter ( 12 ) and a throttle valve ( 13 ). An EGR passage ( 21 ) is connected to an intake passage ( 10 ) at a joint ( 22 ) upstream of the compressor ( 5 ). The following relationship ( 1 ) is satisfied between an intake passage volume (V 1 ) from the air flow meter ( 12 ) to the junction ( 22 ), an intake passage volume (V 2 ) from the compressor ( 5 ) to the throttle valve ( 13 ) and a maximum boost pressure (P b ) under operating conditions in which the introduction of EGR gas is performed, in order to prevent a mixed gas of fresh air and EGR gas from flowing back to the air flow meter ( 12 ) even under the maximum boost pressure (P b ). V 1 > V 2 × ( P b - P 1 P 1 ) × ( P 1 P b ) κ - 1 κ ( 1 )

Intoxicated Vehicle Driver Accident Reduction System

A sobriety ignition interlock system including an engine control device and a method for managing available vehicle engine power using the sobriety ignition interlock system. The engine control device includes an engine control processor (ECP) that is electronically connected in between an engine control unit (ECU), an engine sensor assembly, and a sobriety processor. The sobriety processor determines a sobriety level of a vehicle driver and sends a corresponding sobriety signal to the ECP. The ECP intercepts an engine signal transmitted from the engine sensor assembly to the ECU and manipulates the engine signal according to the sobriety signal, in order to manage the available power of the vehicle engine. 1. A method of managing available vehicle engine power , the method comprises the steps of:providing a vehicle engine, an engine control processor (ECP), a sobriety processor, an engine control unit (ECU), and an engine sensor assembly;calculating, by the sobriety processor, a sobriety level for a vehicle driver;comparing, by the sobriety processor, the sobriety level to a sobriety threshold in order to produce a sobriety signal;sending, by the sobriety processor, the sobriety signal to the ECP;intercepting, by the ECP, an engine signal transmitted from the engine sensor assembly to the ECU; andmanipulating, by the ECP, the engine signal according to the sobriety signal.2. The method of managing available vehicle engine power claim 1 , the method as claimed in further comprises the step of:terminating, by the ECP, the engine signal, if the sobriety level is above the sobriety threshold.3. The method of managing available vehicle engine power claim 1 , the method as claimed in further comprises the step of:sending, by the ECP, the engine signal to the ECU, if the sobriety level is below the sobriety threshold.4. The method of managing available vehicle engine power claim 1 , the method as claimed in further comprises the steps of:transforming, by the ECP, the ...

Apparatus and Method for Diagnosing Failure of Bypass Valve

Some embodiments of the teachings herein include an apparatus for diagnosing bypass valve failure in an electric supercharger with a motor and an electric compressor comprising: a bypass valve on a bypass line branching from an intake line with the electric supercharger; and a control unit which assesses the vehicle-state information to determine whether failure criteria of a bypass valve start are satisfied. If the failure criteria are satisfied, the control unit transmits ‘open’ or ‘close’ control instructions to the bypass valve and transmits, to the electric supercharger, a specific rotational-speed target value for determining whether the bypass valve is in the normal open state or the normal closed state, thereby determining whether the bypass valve is subject to stuck-open failure or stuck-closed failure. 1. An apparatus for diagnosing bypass valve failure in an electric supercharger with a motor and an electric compressor actuated by the motor to supply supercharged air to the combustion chamber of an engine , the apparatus comprising:a bypass valve on a bypass line branching from an intake line with the electric supercharger, wherein the bypass valve joins the intake line at the front end of a throttle valve for adjusting an intake amount supplied to the combustion chamber;a vehicle-state input unit receiving vehicle-state information; anda control unit which assesses the vehicle-state information to determine whether failure criteria of a bypass valve start are satisfied; andif the failure criteria are satisfied, the control unit transmits ‘open’ or ‘close’ control instructions to the bypass valve and transmits, to the electric supercharger, a specific rotational-speed target value for determining whether the bypass valve is in the normal open state or the normal closed state, thereby determining whether the bypass valve is subject to stuck-open failure or stuck-closed failure.2. The apparatus for diagnosing bypass valve failure of claim 1 , wherein the ...

SYSTEM AND METHOD FOR OPERATING AN ENGINE

Methods and systems for operating an engine including an external exhaust gas recirculation (EGR) system are presented. In one non-limiting example, output of a differential pressure sensor and output of an intake manifold pressure sensor are used as a basis for determining whether or not EGR system degradation is present while an engine is operating at conditions other than engine idle conditions. 1. A method for operating an engine , comprising:receiving a differential pressure sensor output and intake manifold pressure sensor output to a controller;judging whether or not exhaust gas recirculation system degradation is present responsive to the differential pressure sensor output and the intake manifold pressure sensor output while operating an engine with intake manifold pressure greater than atmospheric pressure via the controller; andadjusting an actuator via the controller responsive to the judgment.2. The method of claim 1 , where the actuator is a waste gate.3. The method of claim 1 , further comprising converting the differential pressure sensor output to a differential pressure claim 1 , and where the judgement is based on the differential pressure exceeding a second threshold.4. The method of claim 3 , further comprising converting the intake manifold pressure sensor output to an intake manifold pressure claim 3 , and where the judgement is also based on the intake manifold pressure minus a barometric pressure exceeding a first threshold.5. The method of claim 1 , further comprising converting the differential pressure sensor output to a differential pressure claim 1 , and where the judgement is based on an absolute value of the differential pressure exceeding an eighth threshold.6. The method of claim 5 , further comprising converting the intake manifold pressure sensor output to an intake manifold pressure claim 5 , and where the judgement is also based on the intake manifold pressure minus a barometric pressure exceeding a seventh threshold.7. The ...

Optimized fuel management system for direct injection ethanol enhancement of gasoline engines

Fuel management system for enhanced operation of a spark ignition gasoline engine. Injectors inject an anti-knock agent such as ethanol directly into a cylinder. It is preferred that the direct injection occur after the inlet valve is closed. It is also preferred that stoichiometric operation with a three way catalyst be used to minimize emissions. In addition, it is also preferred that the anti-knock agents have a heat of vaporization per unit of combustion energy that is at least three times that of gasoline.

Atmospheric pressure estimation device of outboard motor

By obtaining an atmospheric pressure learning value by applying filtering to an estimated atmospheric pressure found from an estimated atmospheric pressure map in an atmospheric pressure learning region matched in advance, and by constantly updating this atmospheric pressure learning value, stable and highly reliable atmospheric pressure estimation can be achieved. Also, a pre-set parameter value or the last atmospheric pressure learning value is used as the initial atmospheric pressure value and an unstable intake pressure value at the engine start in a battery-less state is not used. Hence, it becomes possible to provide an estimated atmospheric pressure with which high drivability is achievable by fully exploiting the engine performance as soon as the engine is started.

Electronic fuel injection system and method for engines

A system includes an electronic fuel injection system of an engine, the electronic fuel injection system including an electronic governor control unit for controlling various functions of the engine.

Exhaust Control Valve Controlling Exhaust Gas Flow in a Turbocharger System

Methods and systems for adjusting a branch communication valve in a dual scroll turbocharger system are provided. In one example, a method may include adjusting a position of a valve arranged between a first adaptor and a second adaptor to enable mixing of exhaust received from an exhaust manifold, the exhaust delivered to a first scroll and a second scroll of a turbocharger to drive a turbine during certain engine operating conditions. 111-. (canceled)12. A system having a dual scroll turbocharger , comprising:a first scroll;a second scroll, fluidically separated from the first scroll via a dividing wall;a first adaptor coupled to an outlet of an exhaust manifold, the first adaptor comprising a first hollow cylinder having first divider traversing an interior volume of the first adaptor;a second adaptor coupled to an inlet of the first scroll and an inlet of the second scroll, the second adaptor comprising a second hollow cylinder comprising a second divider traversing an interior volume of the second adaptor; anda valve coupled to and positioned between the first adaptor and the second adaptor to control an amount of mixing of exhaust received from the exhaust manifold, the exhaust delivered to the first scroll and the second scroll of the turbocharger, the valve comprising a third hollow cylinder comprising a third divider traversing an interior volume of the valve.1311. The dual scroll turbocharger system of claim , wherein the valve is positionable in a continuous manner through selected positions , the selected positions including: a second position wherein the valve is open to enable mixing of exhaust flow to each of the first and second scrolls; and', 'a third position wherein the valve is opened a metered amount to enable partial mixing of exhaust flow to each of the first and second scrolls., 'a first position wherein the valve is closed to separate exhaust flow to each of the first scroll and second scroll;'}14. The system of claim 13 , wherein each of ...

MONITORING AND CONTROL SYSTEM FOR A FLOW DUCT

A monitoring and control system for a flow duct and a method for determining a component status of an operational component disposed within a flow passage of the flow duct utilizing the system are provided. In one exemplary aspect, the system includes at least two sensors that are disposed within the flow passage and configured to sense a characteristic of a fluid flowing therethrough. The sensors may be averaging sensors. Each sensor extends circumferentially about an axial centerline defined by the flow duct. The sensors are arranged in an overlapped arrangement. Particularly, the sensors extend circumferentially about the axial centerline such that the sensors physically overlap one another circumferentially. Additionally, the sensors may be disposed within the same or substantially the same plane axially. Signals generated by the sensors may be utilized to monitor and control the fluid and various operational components disposed within the flow passage. 1. A controller , comprising:one or more memory devices; and{'claim-text': ['receive a first signal from a first sensor positioned within a flow passage defined by a duct, the first signal being indicative of a characteristic of a fluid flowing proximate the first sensor;', 'receive a second signal from a second sensor positioned within the flow passage, the second signal indicative of a characteristic of the fluid flowing proximate the second sensor, the first sensor physically overlapping the second sensor in part along a circumferential direction and not physically overlapping the second sensor in part along the circumferential direction;', 'determine a component status of one or more operational components disposed within the flow passage based at least in part on the first signal and the second signal; and', 'generate a control action based at least in part on the component status of the one or more operational components.'], '#text': 'one or more processors configured to:'}2. The controller of claim 1 , ...

Method and apparatus for determining abnormality in exhaust gas recirculation amount

An absolute value of a deviation of an actual EGR ratio, calculated in a current operational status of an engine 1, from a target EGR ratio set on the basis of current operational status of the engine 1 is acquired and is multiplied by a quotient, as gain, acquired from division of a feedback correction amount of opening degree of an EGR valve 12 by an upper limit of the feedback correction amount to determine normality when an acquired product is close to “0” and determine higher degree of abnormality the further the product is away from “0”.

Internal combustion engine egr flow rate estimation apparatus and internal combustion engine control apparatus

Based on an internal EGR ratio and desired external and internal EGR ratios, an EGR valve opening degree is feedback-controlled based on a desired EGR ratio, calculated in such a way as to perform correction so that a total EGR ratio becomes constant, and an EGR effective opening area obtained through learning of the relationship between an EGR valve opening degree and an effective opening area; thus, a correct characteristic of EGR valve opening degree vs. effective opening area can be maintained and hence it is made possible to absorb variations, changes with time, and even environmental conditions, while making an EGR valve and an intake/exhaust VVT collaborate with each other; therefore, an EGR flow rate can accurately be estimated.

Method and Device for Acquiring the Oil Temperature in an Internal Combustion Engine

Various embodiments include a method for determining the temperature of an engine oil in an internal combustion engine comprising: acquiring a value of a parameter characterizing a current operating point of the internal combustion engine; and calculating the temperature of the engine oil using an oil temperature model. The oil temperature model depends at least in part on dilution of the engine oil caused by different components in the engine oil and accounts for modified heating behavior of the engine oil based on the dilution. 1. A method for determining the temperature of an engine oil in an internal combustion engine , the method comprising:acquiring a value of a parameter characterizing a current operating point of the internal combustion engine;calculating the temperature of the engine oil using an oil temperature model;wherein the oil temperature model depends at least in part on dilution of the engine oil caused by different components in the engine oil and accounts for modified heating behavior of the engine oil based on the dilution.2. The method as claimed in claim 1 , further comprising determining the different components using an oil-dilution model.3. The method as claimed in claim 2 , further comprising:determining the input masses for individual components; andassigning a boiling characteristic curve for each input mass to a value memory of a control device;wherein the control device controls operation of the internal combustion engine based on the modelled oil temperature.4. The method as claimed in claim 3 , further comprising acquiring a correction factor for the modelled oil temperature towards low values claim 3 , using the boiling characteristic curves.5. The method as claimed in claim 1 , further comprising including at least one variable selected from the group consisting of: coolant temperature claim 1 , air mass flow claim 1 , intake manifold pressure claim 1 , and air/fuel ratio as a parameter characterizing a current operating point of ...

Monitoring Deviations Occurring In The Valve Drive Of An Internal Combustion Engine, And Electronic Engine Control Units For Executing Such Methods

Various embodiments include a method for detecting deviations occurring in the valve drive of an internal combustion engine comprising: measuring dynamic pressure oscillations of intake air in an air intake tract of respective internal combustion engine during operation; calculating an inlet valve stroke phase difference and/or an outlet valve stroke phase difference based on the measured dynamic pressure oscillation; calculating a valve stroke phase deviation value with respect to a valve stroke phase reference value based on the calculated phase difference; and calculating a first valve drive deviation value based on the valve stroke phase deviation value. 1. A method for detecting deviations occurring in the valve drive of an internal combustion engine , the method comprising:measuring dynamic pressure oscillations of intake air in an air intake tract of respective internal combustion engine during operation;calculating an inlet valve stroke phase difference and/or an outlet valve stroke phase difference based on the measured dynamic pressure oscillation;calculating a valve stroke phase deviation value with respect to a valve stroke phase reference value based on the calculated phase difference; andcalculating a first valve drive deviation value based on the valve stroke phase deviation value.2. The method as claimed in claim 1 , further comprising:measuring an inlet camshaft angle difference and/or an outlet camshaft angle difference using a crankshaft position sensor and an inlet camshaft position sensor and/or outlet camshaft position sensor during operation;calculating a second valve drive deviation value based on the measured angle difference;comparing the first and the second valve drive deviation value with one another to perform a reciprocal plausibility check; andcalculating a valve drive deviation comparison value.3. The method as claimed in claim 2 , wherein the first and/or the second valve drive deviation value is identified as plausible only if the ...

DIAGNOSIS DEVICE AND DIAGNOSIS METHOD FOR INTERNAL COMBUSTION ENGINE, AND CONTROL DEVICE AND CONTROL METHOD FOR INTERNAL COMBUSTION ENGINE

A diagnosis device for a multi-cylinder internal combustion engine having an exhaust turbocharger, the device configured to diagnose a fuel combustion state in each one of cylinders in the internal combustion engine. The diagnosis device includes: a rotational speed detector configured to output a signal corresponding to a rotational speed of the exhaust turbocharger or a signal correlated to fluctuation in the rotational speed of the exhaust turbocharger, and a fuel combustion state diagnosis unit configured to diagnose unevenness in the fuel combustion states of the cylinders through a frequency analysis involving a fast Fourier transformation of a frequency characteristic of a signal output from the rotational speed detector. 1. A diagnosis device for a multi-cylinder internal combustion engine having one or more exhaust turbochargers , the device configured to diagnose a fuel combustion state in each one of cylinders in the internal combustion engine , the diagnosis device comprising:a rotational speed detector configured to output a signal corresponding to a rotational speed of at least one of the one or more exhaust turbochargers or a signal correlated to fluctuation in the rotational speed of at least one of the one or more exhaust turbochargers; anda fuel combustion state diagnosis unit configured to diagnose unevenness in fuel combustion states of the cylinders through a frequency analysis involving a fast Fourier transformation of a frequency characteristic of a signal output from the rotational speed detector.2. The diagnosis device for the internal combustion engine according to claim 1 , wherein the fuel combustion state diagnosis unit is configured to:determine an operating point corresponding to a complex plane through the frequency analysis involving the fast Fourier transformation, andbased on an angle of a vector ranging from an origin of the complex plane to the operating point with respect to a coordinate axis of the complex plane and a length of ...

DEEP REINFORCEMENT LEARNING FOR AIR HANDLING AND FUEL SYSTEM REFERENCING

An engine system includes an air handling and fuel system whose states are managed by a reference managing unit. The engine system has a plurality of sensors whose sensor signals at least partially define a current state of the engine system. The reference managing unit includes a controller which controls the air handling and fuel system of the engine system as well as a processing unit coupled to the sensors and the controller. The processing unit includes an agent which learns a policy function that is trained to process the current state, determines air handling references and fuel system references by using the policy function after receiving the current state as an input, and outputs the air handling references and fuel system references to the controller. Then, the agent receives a next state and a reward value from the processing unit and updates the policy function using a policy evaluation algorithm and a policy improvement algorithm based on the received reward value. Subsequently, the controller controls the air handling and fuel system of the engine in response to receiving the air handling references and the fuel system references. 1. A reference managing unit for air handling and fuel system of an engine system , comprising:a plurality of sensors coupled to the engine system, wherein sensor signals from the plurality of sensors at least partially define a current state;a controller operable to control the air handling and fuel system of the engine system; anda processing unit coupled to the sensors and the controller, the processing unit comprising an agent operative to:learn a policy function trained to process the current state, determine air handling references and fuel system references by using the policy function after receiving the current state as an input, output the air handling references and fuel system references to the controller, receive a next state and a reward value from the processing unit, and update the policy function using a ...

ENGINE CONTROLLER, ENGINE CONTROL METHOD, AND MEMORY MEDIUM

An engine controller, an engine control method, and memory medium are provided. A second calculation process calculates an intake air amount without using a detection result of an air flow meter. The determination process determines that intake air pulsation is great if it is confirmed that a difference between an average flow rate and a minimum flow rate is great. The average flow rate is an average value of an intake air flow rate within a period of the intake air pulsation. The minimum flow rate is a minimum value of the intake air flow rate within the period. When it is determined that the intake air pulsation is great, a calculation method switching process selects a calculated value of the intake air amount that is obtained by the second calculation process. 1. An engine controller used for an engine , the engine including an air flow meter that detects an intake air flow rate in an intake passage , the engine controller operating an actuator installed in the engine , thereby controlling operation of the engine , and the engine controller being configured to execute:a first calculation process that calculates an intake air amount introduced into a cylinder of the engine, the first calculation process detecting the intake air amount based on a detection result of the air flow meter;a second calculation process that calculates the intake air amount based on at least one of a detected value of an intake pipe pressure and a throttle opening degree, without using the detection result of the air flow meter;a determination process that determines whether an intake air pulsation is great based on the intake air flow rate detected by the air flow meter, the determination process determining that the intake air pulsation is great if it is confirmed that a difference between an average flow rate and a minimum flow rate is great, the average flow rate being an average value of the intake air flow rate within a period of the intake air pulsation, and the minimum flow rate ...

Using a variable geometry turbocharger to control an exhaust gas temperature and a pressure of an intake manifold

An engine control module (ECM) may obtain information concerning a speed of an engine, information concerning an exhaust gas temperature, information concerning an engine airflow rate, information concerning a pressure of an intake manifold associated with the engine, and information concerning a requested amount of engine braking power. The ECM may cause one or more components of a variable geometry turbocharger (VGT) to adjust based on the information concerning the speed of the engine, the information concerning the exhaust gas temperature, and the information concerning the engine airflow rate. Additionally, or alternatively, the ECM may cause the one or more components of the VGT to adjust based on the information concerning the pressure of the intake manifold associated with the engine and the information concerning the requested amount of engine braking power.

DIESEL ENGINE SYSTEM

A diesel engine system has a piston in which a cavity is formed in a crown surface. The cavity has a bottom part, a peripheral part dented so as to be convex radially outward in a cross-sectional view, and a lip part formed above the peripheral part and protruding so as to be convex radially inward in the cross-sectional view. An injection controller causes an injector to perform, during operation in a given operating range, a main injection in which injected fuel is directed to the lip part, and an after-injection in which a smaller amount of fuel than the main injection is injected at a given period later than the main injection in an expansion stroke. An injection interval period that is a period of time from an end of the main injection to a start of the after-injection is shorter as an injection pressure of fuel increases. 1. A diesel engine system , comprising:a cylinder;a piston reciprocatably accommodated in the cylinder;an injector configured to inject fuel containing diesel fuel into a combustion chamber that is a space above the piston;an injection pressure acquirer configured to acquire an injection pressure of the fuel injected from the injector; andan injection controller configured to control the injector so that the fuel is injected at a plurality of timings set from a compression stroke to an expansion stroke, during operation of the engine system in a given operating range, a bottom part formed so that a height thereof becomes lower while extending radially outward;', 'a curved peripheral part formed radially outward of the bottom part and dented so as to be convex radially outward in a cross-sectional view including a cylinder axis; and', 'a curved lip part formed above the peripheral part and protruding so as to be convex radially inward in the cross-sectional view,, 'wherein the piston has a cavity dented downwardly in a crown surface thereof, the cavity having, as wall surfaces defining the cavitywherein the injector is provided so as to inject ...

SECONDARY SYSTEM AND METHOD FOR CONTROLLING AN ENGINE

Systems and methods for operating an engine in response to a condition where air flow into an engine via an air filter of an engine air intake is limited are presented. In one example, a canister purge valve is adjusted responsive to accelerator pedal position to reduce engine torque reduction that may be caused by a partially clogged air filter or lower barometric pressure. In this way, the engine air amount may be adjusted to provide additional torque from an engine while engine air flow through the air filter may be limited. 1. An engine control method , comprising:opening a fuel vapor storage canister vent valve and closing a fuel tank vapor blocking valve via a controller in response to an indication of barometric pressure less than a first threshold and a driver demand torque greater than a second threshold.2. The method of claim 1 , where the fuel vapor canister vent valve is positioned along a conduit extending between atmosphere and a fuel vapor storage canister.3. The method of claim 1 , where the fuel tank vapor blocking valve is positioned along a conduit extending between a fuel tank and a fuel vapor storage canister.4. The method of claim 1 , further comprising adjusting a position of a canister purge valve proportionate to a position of an accelerator pedal.5. The method of claim 4 , further comprising holding an engine air inlet throttle in a fixed position in response to the barometric pressure less than the first threshold and the driver demand torque greater than the second threshold.6. The method of claim 1 , where the driver demand torque is based on a position of an accelerator pedal.7. The method of claim 1 , further comprising opening a fuel vapor storage canister vent valve and closing a fuel tank vapor blocking valve via a controller in further response to an engine air intake filter not being degraded.8. An engine control method claim 1 , comprising:opening a fuel vapor storage canister vent valve and closing a fuel tank vapor blocking ...

Supercharging system, control device for supercharging system, control method for supercharging system, and program

This control device starts, an electric motor on the basis of a drive signal. After starting of the electric motor, the control device switches a bypass valve from an open state to a closed state.

VEHICLE CONTROL DEVICE

A vehicle control device includes an engine (), an engine control mechanism that controls an engine torque, and a PCM () that performs vehicle posture control for generating vehicle deceleration by controlling the engine control mechanism to reduce the engine torque upon satisfaction of a condition that a vehicle is travelling and a steering angle-related value related to a steering angle of a steering device increases. When a driver performs an accelerator operation for reducing an accelerator opening during execution of vehicle posture control, the PCM () suppresses reduction of a generated torque of the engine due to the accelerator operation. 1. A vehicle control device comprising:an engine;an engine control mechanism that controls a generated torque of the engine; andcircuitry configured to perform vehicle posture control for generating vehicle deceleration by controlling the engine control mechanism to reduce the generated torque of the engine upon satisfaction of a condition that a vehicle is travelling and a steering angle-related value related to a steering angle of a steering device increases, whereinwhen an accelerator operation for reducing an accelerator opening during execution of the vehicle posture control is performed, the circuitry is configured to suppress reduction of the generated torque of the engine due to the accelerator operation.2. The vehicle control device according to claim 1 , whereinthe circuitry is configured to perform control to continue suppressing the reduction of the generated torque due to the accelerator operation until the vehicle posture control ends.3. The vehicle control device according to claim 1 , wherein{'sub': ';', 'the circuitry is configured to suppress the reduction of the generated torque due to the accelerator operation by at least one of prohibiting the reduction of the generated torque due to the accelerator operation, delaying a start of the reduction of the generated torque due to the accelerator ...

Hydraulic servo gas regulator for multi-fuel engine

A bi-fuel and dual-fuel engine variable pressure fuel system is presented facilitating individual or simultaneous use of liquid and gaseous fuels including natural gas, hydrogen and gasoline, through employment of a variable output pressure gaseous fuel regulator incorporating an attached hydraulic amplifying structure communicating with a relatively low pressure fluid servo circuit that may in turn communicate with a variable pressure automotive liquid fuel system to facilitate relatively high pressure gaseous fuel injection.

SYSTEM AND METHOD FOR CONTROL OF VOLUMETRIC EFFICIENCY IN A DIRECT INJECTION ENGINE

A system and method of inducing an operational response change in an operating direct-injection internal combustion engine is provided such that the engine includes a cylinder into which liquid fuel injection is directly performed. The method starts by operating the direct-injection engine using a start of injection (SOI) protocol. At some point during operation, it is determined that a change is desired for a first parameter of engine operation that is at least partially a function of a charge provided to the cylinder (such as the torque output). In response an operational response in the engine is induced by altering the SOI protocol via a first SOI alteration that alters the volumetric efficiency of the cylinder and changes the first parameter. 19.-. (canceled)10. A method of operating an internal combustion engine , the engine having an intake manifold fluidly coupled to multiple cylinders including at least a first and second cylinder , the method comprising:determining the existence of an imbalance between the first and second cylinders with respect to a first engine property; andaltering a volumetric efficiency experienced by the first cylinder independently of the volumetric efficiency experienced by the second cylinder to reduce the imbalance between the first and second cylinders.11. The method of claim 10 , wherein the engine includes an exhaust gas recirculation loop in which recirculated exhaust flows from at least one cylinder into the intake manifold claim 10 , such that the recirculated exhaust is intermixed with fresh air in the intake manifold to form a charge; and the imbalance is in a fraction of the charge comprised of recirculated exhaust (EGR fraction) claim 10 , and altering a volumetric efficiency experienced by the first cylinder independently of the volumetric efficiency experienced by the second cylinder alters the EGR fraction experienced by the first cylinder independently of the EGR fraction experienced by the second cylinder.12. The ...

Fuel injection control apparatus for internal combustion engine

A fuel injection control apparatus for fuel injection at optimum timing in correspondence with level of gas flow velocity in an intake port upon intake stroke injection. A fuel injection valve is controlled so as to set a large majority (more than half) of an injection period to inject fuel during an intake stroke in respective cylinders within a period where intake port gas pressure is increased. Upon intake stroke injection, the fuel is injected at optimum timing in correspondence with the direction and the level of gas flow velocity in the intake port. Accordingly, the status of air-fuel mixture in a combustion chamber is excellent. It is possible to improve fuel consumption and to reduce exhaust emission.

MULTI-TURBOCHARGER SYSTEMS AND METHODS OF OPERATING SAME

One embodiment relates to a system including first, second, and third turbochargers. The first and second turbocharger include respective first and second turbines in fluid receiving communication with an exhaust manifold of an engine, and respective first and second compressors in fluid providing communication with an intake manifold of the engine. The third turbocharger includes a third turbine in fluid receiving communication with each of the first and second turbines, and a third compressor in fluid providing communication with each of the first and second compressors. A first control valve is controllable so as to controllably permit flow between the first and third compressors. A second control valve is controllable so as to controllably permit flow between the second and third compressors. 1. A system , comprising:a first turbocharger comprising a first turbine in fluid receiving communication with an exhaust manifold of an engine, and a first compressor in fluid providing communication with an intake manifold of the engine;a second turbocharger comprising a second turbine in fluid receiving communication with the exhaust manifold, and a second compressor in fluid providing communication with the intake manifold;a third turbocharger comprising a third turbine in fluid receiving communication with each of the first and second turbines, and a third compressor in fluid providing communication with each of the first and second compressors;a first control valve positioned in a first intake conduit fluidly coupling the first and third compressors, the first control valve controllable between a first position permitting flow between the first and third compressors, and a second position blocking flow between the first and third compressors and permitting flow from external atmosphere to the first compressor; anda second control valve positioned in a second intake conduit fluidly coupling the second and third compressors, the second control valve controllable between ...

Combustion-stabilizing device and combustion-stabilizing method for internal combustion engine

A change amount per unit time of an engine output command for controlling engine output of an internal combustion engine is calculated as an engine output increasing rate, and a power supply device is controlled so that power corresponding to the calculated engine output increasing rate is supplied to a combustion promoter generation device. The combustion promoter generation device generates a combustion promoter through the power supplied from the power supply device to supply the combustion promoter to a combustion chamber of the internal combustion engine, and a generation amount of the combustion promoter increases as the supplied power increases. In this manner, the generation amount of the combustion promoter is adjusted.

CONTROL APPARATUS AND CONTROL METHOD FOR DIESEL ENGINE

A control apparatus for a diesel engine includes a neighboring temperature estimating section which estimates a temperature of a neighborhood of a glow plug that heats an interior of a cylinder upon startup, and a supercharging pressure control section which controls a supercharging pressure in such a way that a rotation fluctuation of the engine does not increase, on the basis of the estimated temperature of the neighborhood of the glow plug. 14-. (canceled)5. A control apparatus for a diesel engin includinga neighboring temperature estimating section configured to estimate a temperature of a neighborhood of a glow plug that heats an interior of a cylinder upon startup;a supercharging pressure control section configured to control a supercharging pressure in such a way that a rotation fluctuation of the engine does not increase, on the basis of the estimated temperature of the neighborhood of the glow plug; anda glow energizing control section configured to set the amount of energization of the glow plug larger upon supercharging than upon non-supercharging until entering the stable region in which the rotational fluctuation is small.6. The control apparatus for the diesel engine according to claim 5 , whereinthe glow energizing control section is configured to set the amount of energization of the glow plug smaller upon supercharging than upon non-supercharging, after entering the stable region in which the rotational fluctuation is small.712-. (canceled) This invention relates to a control apparatus and control method for a diesel engine.Combustion becomes more unstable immediately after a cold start than during a normal operation. That is, the rotations of diesel engines fluctuate more widely. JP2001-263131A discloses a technique for injecting a larger amount of fuel during an idle operation immediately after a cold start than during a normal operation. In this way, the rotational speed of the engine increases, becoming stable earlier.However, there are cases ...

Air quantity calculation device for internal combustion engine

An ECU calculates a cylinder flowing air amount based on an intake tube pressure, using an air intake valve model simulating a behavior of air flowing into a combustion chamber via an air intake valve. The ECU calculates an air intake amount based on a detection result of an air amount detection sensor, and determines whether the air intake amount matches an actual amount of air flowing into the combustion chamber. When the air intake amount is determined to match the actual amount, the ECU calculates a learnt value based on comparison of the cylinder flowing air amount with the air intake amount.

Engine egr device

An EGR device is provided with: an EGR passage for allowing a portion of exhaust gas from an engine to flow to an intake passage; an EGR valve for adjusting an EGR flow rate through the EGR passage; a throttle valve provided in the intake passage; and an electronic control device which calculates a fully closed reference intake pressure based on an operating state of the engine during EGR valve fully-closing, and which diagnoses an abnormality due to valve-opening locking of the EGR valve based on the calculated fully closed reference intake pressure. The ECU determines a foreign matter biting abnormality of the EGR valve based on the intake pressure, and based on the result of adding the fully closed reference intake pressure, calculated according to the rotational speed and the load of the engine, to an intake-pressure increase allowance calculated according to the rotational speed.

Stochastic pre-ignition prediction and mitigation systems and methods

An engine control system for a vehicle includes a timer module, a stochastic pre-ignition (SPI) mitigation module, and a boost control module. The timer module tracks a period of operation of an engine where vacuum within an intake manifold is less than a first predetermined vacuum. The SPI mitigation module generates an SPI signal when the period is greater than a predetermined period and the vacuum is less than a second predetermined vacuum. The second predetermined vacuum is less than the first predetermined vacuum. The boost control module reduces output of a turbocharger in response to the generation of the SPI signal.

Spark control systems and methods for engine torque estimation

A spark control module, for an engine speed and an engine load: for a first predetermined period, supplies spark to each cylinder of the engine at a predetermined spark timing set for the engine speed and the engine load. For a second period following the first predetermined period, the spark control module: provides spark to a first one of the cylinders at a first spark timing that is retarded relative to the predetermined spark timing; and supplies spark to all of the other cylinders of the engine at the predetermined spark timing. The storage module selectively stores in memory: a first torque output of the engine measured during the first predetermined period; and a second torque output of the engine measured during the second period.

Method and system for controlling electronic throttle control system

A method for controlling an electronic throttle control (ETC) system, in which an electronic control unit (ECU) controls the ETC system using an air volume learning value containing information on a volume of air introduced into an engine for each opening degree of the ETC system according to carbon deposit of the ETC system, the method may include reading an air volume learning value used during a previous operation. The air volume learning value is compared to a preset learning value change reference value. Whether an operation condition of the engine satisfies a learning value change condition which is preset to change the air volume learning value, and whether the volume of air passing through the ETC system satisfies a preset learning-value-change-air-volume condition are determined. The air volume learning value used during the previous operation and stored in the ECU is substituted with a preset initial value of the air volume learning value.

DIESEL ENGINE PARTICULATE FILTER REGENERATION SYSTEM AND METHODS

Methods and systems for estimating an amount of residual or retained fuel that remains in a cylinder from a first cycle of the cylinder to a second cycle of the cylinder are described. In one example, the amount of residual fuel is estimated in response to a temperature of an oxidation catalyst. The retained fuel amount may then be the basis for adjusting fuel injection amounts during the second cycle of the cylinder. 1. An engine control method , comprising:estimating an amount of fuel held in a cylinder from a first cycle of the cylinder to a second cycle of the cylinder via a controller in response to a temperature increase of an oxidation catalyst; andadjusting an amount of fuel injected to the cylinder via the controller during the second cycle of the cylinder in response to the estimated amount of fuel.2. The engine control method of claim 1 , further comprising estimating the amount of fuel held in the cylinder in further response to injection timing of post fuel injections during the first cycle of the cylinder.3. The engine control method of claim 1 , further comprising estimating the amount of fuel held in the cylinder in further response to internal and external exhaust gas residual amounts in the cylinder.4. The engine control method of claim 1 , further comprising estimating the amount of fuel held in the cylinder in further response to a pressure difference between intake manifold pressure and exhaust manifold pressure.5. The engine control method of claim 1 , where adjusting the amount of fuel injected during the second cycle of the cylinder includes adjusting an amount of fuel in pilot fuel injections.6. The engine control method of claim 1 , where adjusting the amount of fuel injected during the second cycle of the cylinder includes adjusting an amount of fuel in main fuel injections.7. The engine control method of claim 1 , where the second cycle immediately follows the first cycle of the cylinder.8. The engine control method of claim 1 , further ...

Onboard Control Device

An onboard control device has a drive manipulated variable detection unit () for determining a drive manipulated variable manipulated by a driver to impart a propulsive force to a vehicle, a command value calculation unit () for calculating a command value for a drive source of the vehicle based on the drive manipulated variable, a propulsive force control unit () for controlling the propulsive force based on the command value, operating state detection units () for determining the operating states of the drive source, a drive manipulation rate of change calculation unit () for calculating the rate of change in drive manipulation, an operating state rate of change calculation unit () for calculating the rate of change in the operating state, and an abnormality detection unit () for detecting abnormalities in the drive source based on the rates of change in drive manipulation and the operating state. 1a drive manipulation rate of change calculation unit that calculates a rate of change in drive manipulation that is a rate of change in a drive manipulated by a driver;an operating state rate of change calculation unit that calculates a rate of change in an operating state that is a rate of change in the operating state of the driving source;an abnormality detection unit that detects abnormalities in the drive source, based on a difference or a ratio between the rate of change in drive manipulation and the rate of change in the operating state exceeding a predetermined threshold value, when a vehicle acceleration of a predetermined level or more occurs.. An onboard control device for controlling a propulsive force of a drive source for driving a vehicle comprising: This application is a continuation of U.S. application Ser. No. 15/114,112, filed Jul. 26, 2016, which is a 371 of International Application No. PCT/JP2014/082355, filed Dec. 8, 2014, which claims priority from Japanese Patent Application No. 2014-019604, filed Feb. 4, 2014, the disclosures of which are ...

METHOD AND CONTROL UNIT FOR CARRYING OUT A GAS EXCHANGE IN A CYLINDER OF AN INTERNAL COMBUSTION ENGINE AND INTERNAL COMBUSTION ENGINE HAVING SUCH A CONTROL UNIT

A method for carrying out a gas exchange in a cylinder of an internal combustion engine is provided. The cylinder is connected to a gas line section via a valve. An actuator adjusts a gas pressure in the gas line section. The valve closes at a fixed point in time in a working cycle of the internal combustion engine in case of a constant torque of the internal combustion engine. The method includes the steps of recognizing a torque change request; determining a target value for the gas pressure in the gas line section in dependence on the torque change request; and determining a variable point in time for closing the valve as a result of the torque change request, wherein the variable point in time is shifted in the working cycle relative to the fixed point in time in dependence on the target value of the gas pressure. 1. A method for carrying out a gas exchange in a cylinder of an internal combustion engine , the method comprising:providing the internal combustion engine such that the cylinder is connected, via a valve, to a gas line section and providing, in the gas line section, an actuator for adjusting a gas pressure in the gas line section, wherein the valve closes at a fixed point in time in a working cycle of the internal combustion engine in case of a constant torque of the internal combustion engine;recognizing a torque change request;determining a target value for the gas pressure in the gas line section in dependence on the torque change request and subsequently determining a variable point in time for closing the valve as a result of the torque change request, wherein the variable point in time is shifted in the working cycle relative to the fixed point in time in dependence on the target value of the gas pressure; andcontrolling the actuator as a result of the torque change request in such a way that the target value of the gas pressure prevails in the gas line section.2. The method according to claim 1 , which comprises determining the target value for ...

EVAPORATIVE FUEL PROCESSING APPARATUS

An evaporative fuel processing apparatus executes a purge process when a predetermined purge condition is satisfied. A precondition, which is satisfied immediately before the satisfaction of the purge condition, is set. An operation of a purge pump is started at the time of satisfying the precondition. Thereafter, when the purge condition is satisfied, the purge valve is opened to execute the purge process. In this way, the time required for the purge pump to reach a rated rotational speed upon satisfaction of the purge condition can be shortened. Thus, the operating time period of the purge pump can be shortened, and the response delay of the purge can be avoided. That is, it is possible to limit shortage of the purge amount caused by the response delay. 1. An evaporative fuel processing apparatus comprising:a canister that holds evaporative fuel, which is evaporated in a fuel tank;a purge passage that guides the evaporative fuel, which is held by the canister, to an intake air passage of an internal combustion engine;an electric purge valve that is electrically driven to open and close the purge passage;an electric purge pump that is installed in the purge passage and is electrically driven to pump the evaporative fuel from the canister to the intake air passage; anda control device that controls energization of the electric purge valve and energization of the electric purge pump, wherein:a condition for executing a purge process by opening the electric purge valve and driving the electric purge pump in a middle of operating the internal combustion engine is defined as a purge condition;a condition, which is satisfied before satisfaction of the purge condition in the middle of operating the internal combustion engine, is defined as a precondition; andthe control device starts an operation of the electric purge pump at a time of satisfying the precondition and opens the electric purge valve at a time of satisfying the purge condition.2. The evaporative fuel ...

FUEL FLOW DETECTION METHOD OF IN-VEHICLE ENGINE

A fuel flow detection method of an in-vehicle engine uses gasoline, liquefied gas, and gas as a fuel and adopts a spark ignition system, and a fuel flow is calculated from a detected intake air flow and an air-fuel ratio after combustion or an oxygen ratio. 1. A fuel flow detection method of an in-vehicle engine that uses gasoline , liquefied gas , and gas as a fuel and adopts a spark ignition system ,wherein a fuel flow is calculated from a detected intake air flow (Qa) and an air-fuel ratio (R) after combustion or an oxygen ratio (RO).2. The fuel flow detection method of the in-vehicle engine according to claim 1 , wherein an estimated intake air flow is calculated from information of an intake manifold pressure sensor provided on a downstream side of a throttle valve of an engine claim 1 , information of an air temperature sensor claim 1 , and information of an engine speed or estimated intake air flow information is calculated from information of a throttle valve opening claim 1 , an atmospheric pressure claim 1 , and an air temperature used as the intake air flow.3. The fuel flow detection method of the in-vehicle engine according to claim 1 , wherein the oxygen ratio includes an air-fuel ratio index and the fuel flow is calculated using the following formula:{'br': None, 'i': Qf', 'Qa', 'K, 'Fuel flow()=the detected intake air flow()×constant()/the oxygen ratio.'}4. The fuel flow detection method of the in-vehicle engine according to claim 1 , wherein the fuel flow (Qf) is set to 0 claim 1 , when an engine stop or a fuel supply stop is controlled.5. The fuel flow detection method of the in-vehicle engine according to claim 1 , wherein the fuel flow is detected by a control unit different from a control unit of the in-vehicle engine.6. The fuel flow detection method of the in-vehicle engine according to claim 1 , wherein fuel efficiency is calculated by dividing the fuel flow by a vehicle speed.7. The fuel flow detection method of the in-vehicle engine ...

Method And Device For Detecting A Power-Changing Manipulation Of An Internal Combustion Engine

The embodiment relates to a method for detecting a power-changing manipulation of an internal combustion engine (), wherein the internal combustion engine () has an intake tract () and a pressure sensor () which is arranged in the intake tract (). The method has the following steps:

Method for regulating a boost pressure of an engine

In a method for regulating a boost pressure of an engine which has a compressor, an actual boost pressure and a setpoint boost pressure are used as input parameters. The setpoint boost pressure is regulated in such a way that a pressure ratio in the compressor does not exceed a limit pressure ratio. A reference boost pressure is ascertained based on a speed of the engine and a load of the engine. A flow and/or a pressure of air supplied to the engine is/are detected and an associated flow signal and/or pressure signal is generated. The smaller of the reference boost pressure and a limit boost pressure is used as a setpoint boost pressure. The limit boost pressure is ascertained based on a limit boost pressure ratio and a speed of the compressor.

Rate-based contractive model predictive control method for internal combustion engine air path control

A rate based model predictive controller and method for air path control for a diesel engine regulates intake manifold pressure (MAP) and EGR valve flow rate to specified set points by coordinated control of a variable geometry turbine (VGT) and EGR valve position. A decay and a flexible Lyapunov function is enforced on the rate based model predictive controller for a single step prediction and control arisen.