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Небесная энциклопедия

Космические корабли и станции, автоматические КА и методы их проектирования, бортовые комплексы управления, системы и средства жизнеобеспечения, особенности технологии производства ракетно-космических систем

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Мониторинг СМИ

Мониторинг СМИ и социальных сетей. Сканирование интернета, новостных сайтов, специализированных контентных площадок на базе мессенджеров. Гибкие настройки фильтров и первоначальных источников.

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Поддерживает ввод нескольких поисковых фраз (по одной на строку). При поиске обеспечивает поддержку морфологии русского и английского языка
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Применить Всего найдено 540. Отображено 100.
02-01-2020 дата публикации

Dishwasher thermometer with wireless temperature logger and associated methods

Номер: US20200000310A1
Автор: Luk Wah Jackson Chu
Принадлежит: EWIG INDUSTRIES MACAO COMMERCIAL OFFSHORE Ltd

A dishwasher thermometer captures temperature data of temperature sensed within a dishwasher during a wash cycle. The dishwasher thermometer includes a wireless communication interface that transmits the captured temperature data to one or more of a server and a monitor device. When the captured temperature data indicates that the wash cycle did not achieve defined temperature threshold(s), an alert is generated at the server and/or the monitor device indicating that the wash cycle did not meet appropriate washing conditions. In embodiments, the temperature data may be accessible to a third party for certification of the dishwasher wash cycle.

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Номер записи: 1
06-01-2022 дата публикации

METHOD AND SYSTEM FOR DIAGNOSING MISFIRE OF ENGINE

Номер: US20220003182A1
Автор: EOM Tae Kwang, Jeong Jun Wook, Kim Kyu Sup, Lee Hyeseung, Lee Jeonghun, Paeng Jeong Hwan
Принадлежит:

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 ...

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Номер записи: 2
01-01-2015 дата публикации

TEMPERATURE AND STRAIN SENSING OPTICAL FIBER AND TEMPERATURE AND STRAIN SENSOR

Номер: US20150003497A1
Автор: Burov Ekaterina, de Montmorillon Louis-Anne, Pastouret Alain
Принадлежит:

Disclosed is a temperature and strain sensing optical fiber including a first doped radial zone (Z) with an associated first Brillouin shift (BS) caused by the doping of said zone (Z) and a second doped radial zone (Z) with associated second Brillouin shift (BS) caused by the doping of said second zone (Z). The concentration and/or composition of the doping materials in said first and second radial zones are chosen such that the first Brillouin Shift (BS) is different from the second Brillouin Shift (BS) for all variations of said Brillouin Shifts (BS BS) caused by temperature and/or strain. 123-. (canceled)24. A temperature and strain sensing optical fiber comprising at least two radial zones differently doped and having different isothermal and adiabatic compressibility coefficients between said two zones so as to differentiate the respective contributions , of temperature and strain variations , to the variations of at least two distinct Brillouin shifts of said sensing optical fiber , wherein said two radial zones are differently doped such thatvariations of said two Brillouin shifts, caused by a same temperature variation, differ from each other by more than 50%; andvariations of said two Brillouin shifts, caused by a same strain variation, differ from each other by more than 5%.25. The temperature and strain sensing optical fiber according to claim 24 , wherein said two radial zones are differently doped such that a gap exists between said two Brillouin shifts for all variations of said two Brillouin shifts caused by temperature and/or strain variations.26. The temperature and strain sensing optical fiber according to claim 24 , wherein said two radial zones are respectively a core and a ring of said sensing optical fiber.27. The temperature and strain sensing optical fiber according to claim 24 , wherein said two radial zones respectively comprise different doping combinations of the same doping materials claim 24 , each said radial zone comprising at least ...

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Номер записи: 3
05-01-2017 дата публикации

Filtering Distributed Sensing Data

Номер: US20170003177A1
Автор: Aldemar Dünkel, Alf Clement, Gregor Cedilnik
Принадлежит: Aiq Dienstleistungen Ug (haftungsbeschrankt)

A distributed sensing device for determining a physical quantity which comprises a measuring unit configured for measuring signals over time and space by distributed sensing, a determining unit configured for determining, based on the measured signals, data being correlated to the physical quantity, and a filtering unit configured for filtering the data to reduce noise and substantially preserve real features based on at least one filter parameter which is determined depending on the data which relate to the physical quantity at a plurality of different times.

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Номер записи: 4
07-01-2016 дата публикации

INTAKE AIR TEMPERATURE SENSOR AND FLOW MEASUREMENT DEVICE

Номер: US20160003686A1
Автор: Asano Satoshi, Hanzawa Keiji, Matsumoto Masahiro, NAKANO Hiroshi
Принадлежит: Hitachi Automotive Systems, Ltd.

An object of the present invention is to provide a compact and highly accurate intake air temperature sensor by integrating a fixed resistor, connected in series to a temperature sensing element, into an integrated circuit and dispensing with a reference resistor or a changeover switch for connecting the fixed resistor to this reference resistor. The intake air temperature sensor has a temperature sensing element whose resistance value varies with the intake temperature; an integrated circuit electrically connected to the temperature sensing element; a resistive element connected in series to the temperature sensing element; a writable memory that stores correction information corresponding to the resistance value of the resistive element; and a correction processing unit that corrects errors based on the resistance value of the resistive element, which are included in output signals of the temperature sensing element, on the basis of the correction information stored in the writable memory. 1. An intake air temperature sensor comprising:a temperature sensing element whose resistance value varies with the intake temperature;an integrated circuit electrically connected to the temperature sensing element;a resistive element integrated into the integrated circuit and connected in series to the temperature sensing element;a writable memory that stores corrective information corresponding to the resistance value of the resistive element; anda correction processing unit that corrects, on the basis of corrective information stored in the writable memory, errors based on the resistance value of the resistive element contained in an output signal of the temperature sensing element.2. The intake air temperature sensor according to claim 1 ,wherein the correction processing unit corrects the curvature of the characteristics curve of the output signal of the temperature sensing element relative to the intake temperature.3. The intake air temperature sensor according to claim 2 ...

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Номер записи: 5
07-01-2016 дата публикации

OPTICAL FIBER TEMPERATURE DISTRIBUTION MEASURING DEVICE

Номер: US20160003687A1
Автор: TAKEUCHI Nobuaki
Принадлежит: YOKOGAWA ELECTRIC CORPORATION

An optical fiber temperature distribution measuring device includes: an optical fiber as a sensor; a calculation control unit for measuring a temperature distribution along the optical fiber based on an intensity ratio between Stokes light and anti-Stokes light of backward Raman scattered light from the optical fiber; and a temperature correction unit for correcting the temperature distribution by using temperature dependence of a loss difference between the Stokes light and the anti-Stokes light. 1. An optical fiber temperature distribution measuring device comprising:an optical fiber as a sensor;a calculation control unit for measuring a temperature distribution along the optical fiber based on an intensity ratio between Stokes light and anti-Stokes light of backward Raman scattered light from the optical fiber; anda temperature correction unit for correcting the temperature distribution by using temperature dependence of a loss difference between the Stokes light and the anti-Stokes light.2. The optical fiber temperature distribution measuring device according to claim 1 , whereinthe temperature correction unit includes an optical fiber loss correction temperature storing unit for storing a temperature of the optical fiber at a point in time when a loss correction value of the optical fiber is obtained.3. The optical fiber temperature distribution measuring device according to claim 1 , whereinthe temperature correction unit includes an optical fiber loss temperature characteristic storing unit for storing a temperature characteristic of a loss value of the optical fiber.4. The optical fiber temperature distribution measuring device according to claim 2 , whereinthe temperature correction unit includes an optical fiber loss temperature characteristic storing unit for storing a temperature characteristic of a loss value of the optical fiber.5. The optical fiber temperature distribution measuring device according to claim 4 , whereinthe temperature correction unit ...

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Номер записи: 6
04-01-2018 дата публикации

GAS PROBES

Номер: US20180003597A1
Автор: KNIGHT Jeremy
Принадлежит: Endet Ltd.

An insertion-type probe main body for insertion into a pipe transporting gas and a method for making such an insertion-type probe main body are provided. The probe main body includes: an elongate upper tubular portion; an elongate lower tubular portion which is integral with and having a diameter smaller than the upper tubular portion; a bore which extends between the upper and lower tubular portions; and helical fins integrally formed on the lower tubular portion and which wind along and around an outer surface of the lower tubular portion and which overlap each other. A radial extension of the lower tubular portion plus helical fins corresponds to an external radius of the upper tubular portion, so that the helical fins extend in a streamline fashion from the upper tubular portion. Numerous other aspects are provided. 1. A gas-pipeline insertion-type probe main body for insertion into a pipe transporting gas , the probe main body comprising:an upper tubular portion;an elongate lower tubular portion which is integral with the upper tubular portion;one of a fluid-sample bore and a sensor-receiving bore which extends between the upper and lower tubular portions; andwherein the lower tubular portion has a plurality of helical edges integrally formed thereon which wind along and around an outer surface thereof.2. The gas-pipeline insertion-type probe main body of claim 1 , wherein the upper tubular portion is elongate.3. The gas-pipeline insertion-type probe main body of claim 1 , wherein the helical edges overlap each other.4. The gas-pipeline insertion-type probe main body of claim 1 , wherein a lateral extent of the lower tubular portion plus helical edges matches an external lateral extent of the upper tubular portion.5. The gas-pipeline insertion-type probe main body of claim 4 , wherein an end of each helical edge extends to meet in a flush streamline fashion the upper tubular portion.6. The gas-pipeline insertion-type probe main body of claim 4 , wherein an end ...

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Номер записи: 7
07-01-2021 дата публикации

METHOD AND SYSTEM FOR MEASURING TEMPERATURE IN A GAS TURBINE ENGINE

Номер: US20210003458A1
Автор: BOUCHARD Guy, DUROCHER ERIC, Smith Scott
Принадлежит:

A system and method for measuring average temperature of gas in an axial cross-section of a gas turbine engine gas path, involving diverting gas samples from different positions in the axial cross-section to a gas mixing chamber and measuring a temperature of the resulting mixed gas. 1. A method for measuring average temperature of gas in an axial cross-section of a gas turbine engine gas path comprising:diverting a plurality of gas samples from the gas path from positions in the axial cross-section circumferentially spaced from one another;mixing the gas samples to form a mixed gas; andmeasuring a temperature of the mixed gas.2. The method of wherein the corresponding positions lie in a common plane.3. The method of wherein the corresponding positions are equally interspaced from one another around the axial cross-section.4. The method of claim 1 , claim 1 , or further comprising conveying the diverted gas samples to a gas mixing chamber.5. The method of claim 1 , claim 1 , or further comprising conveying the mixed gas to a gas measuring chamber claim 1 , wherein the measuring is performed in the gas measuring chamber.6. The method of claim 1 , claim 1 , or further comprising releasing the mixed gas to the gas path after said measuring.7. The method of further comprising releasing the mixed gas upstream of a low-pressure turbine rotor claim 6 , after said measuring.8. The method of further comprising releasing the mixed gas downstream of a low-pressure turbine rotor claim 6 , after said measuring.9. The method of claim 6 , claim 6 , or further comprising releasing the mixed gas into a space external to the gas turbine engine claim 6 , after said measuring.10. The method of claim 6 , claim 6 , or wherein the axial cross-section is in a turbine section of the turbine engine.11. A gas turbine engine having a gas path extending sequentially across a compressor section claim 6 , a combustor claim 6 , and a turbine section claim 6 , the gas path being annular around an ...

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Номер записи: 8
07-01-2021 дата публикации

MULTI-PIECE THERMOWELL

Номер: US20210003459A1
Автор: Obillo Keith
Принадлежит: Gas Turbine Specialty Parts LLC

A multi-piece thermowell system includes a measurement protection device, a temperature measurement device, a torque mechanism, and a torque transfer mechanism. 1. A multi-piece thermowell comprising:a measurement protection device;a temperature measurement device having a measurement end;a torque mechanism situated within the internal cavity operably attached to the temperature measurement device and the measurement protection device; anda torque transfer mechanism operably attached to the torque mechanism configured to transfer force to the temperature measure device.2. The thermowell of claim 1 , wherein the measurement protection device comprises a well housing inserted through a mounting washer wherein one end of the well housing is affixed to a shield.3. The thermowell of claim 2 , wherein the shield is a tube operationally connected to the well housing such that when the thermowell is placed within a process stream claim 2 , the tube is parallel with the direction of the process stream.4. The thermowell of claim 1 , wherein the temperature measurement device is a thermocouple.5. The thermowell of claim 1 , wherein the torque transfer mechanism comprises a torque nut.6. The thermowell of wherein the torque transfer mechanism further comprises a thumb screw operationally connected to the torque nut.7. The thermowell of claim 1 , wherein the torque mechanism comprises a tube.8. The thermowell of claim 7 , wherein a spring is placed inside one end of the tube and a seating is placed in the other end of the tube and receives the measurement end of the temperature measurement device.9. The thermowell of claim 8 , wherein the seating maintains stability of the measurement end of the temperature measurement device. The present invention claims priority to and the benefit of U.S. Provisional Application No. 62/869,673, the contents of which are incorporated herein by reference.The present invention is generally related to measuring temperature in industrial processes. ...

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Номер записи: 9
07-01-2021 дата публикации

METHOD AND DEVICE FOR MEASURING FAT IN MILK

Номер: US20210003491A1
Автор: DRAHM Wolfgang, Pfluger Stefan, ZHU Hao
Принадлежит:

Method for continuous determining of fat content of milk having variable solids fractions 1. Method for continuous determining of fat content of milk having variable solids fractions and flowing with variable gas content in a pipeline , comprising:ascertaining a value for velocity of sound and an average density value for milk flowing in the pipeline based on eigenfrequencies of at least two bending oscillation wanted modes of measuring tubes of a densimeter arranged in the pipeline;ascertaining a value for static pressure in the pipeline by means of a pressure sensor connected to the pipeline;ascertaining a value for gas volume fraction based on the value for the velocity of sound, the value for the average density and the value for the pressure;ascertaining a value of density of milk flowing in the pipeline without gas content based on the value for the average density and based on the value for the gas volume fraction;ascertaining a value for permittivity of milk flowing in the pipeline based on at least one measuring of propagation velocity and/or absorption of microwaves in the milk by means of a microwave sensor arranged in the pipeline; andcalculating fat fraction based on the value of the density of the milk flowing in the pipeline without gas content and the value for the effective permittivity.2. Method as claimed in claim 1 , wherein claim 1 , for the calculating claim 1 , the milk is modeled as a three component system claim 1 , wherein the components comprise fat claim 1 , water and fat-free solids.3. Method as claimed in claim 2 , wherein the solids comprise proteins and carbohydrates claim 2 , especially mainly lactose.4. Method as claimed in one of the preceding claims claim 2 , wherein density of milk flowing in the pipeline without gas content is modeled as a function claim 2 , for example claim 2 , a linear function claim 2 , of concentration of the components contained in the milk with density values of pure components as weighting factors; ...

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Номер записи: 10
03-01-2019 дата публикации

MULTIMODE OPTICAL FIBER, APPLICATION THEREOF AND TEMPERATURE-MEASURING SYSTEM

Номер: US20190003902A1
Автор: Liu Tongqing, MAO Xin, TONG Weijun, Wang Song, WANG Zhendong, Yang Chen
Принадлежит:

A multimode optical fiber includes a core and a cladding covering the core. The core has a radius in a range of 23.75-26.25 μm. A refractive index profile of the core has a graded refractive index distribution with a refractive index distribution index α in a range of 1.80-1.89. The core has a maximum relative refractive index difference Δ1% in a range from 1.0% to 1.15%. The multimode optical fiber has a fusion loss less than or equal to 0.08 dB. The multimode optical fiber is applied in a middle-and-long distance distributed temperature-measuring system, and a temperature-measuring distance of the system reaches 10 km to 27 km. The system includes a pulsed laser light source, a wavelength division multiplexer, an avalanche photodiode, a data acquisition device, an upper computer, and the temperature-measuring multimode optical fiber. 1. A temperature-measuring multimode optical fiber , comprising a core and a cladding covering the core , wherein the core has a radius in a range from 23.75 μm to 26.25 μm; a refractive index profile of the core has a graded refractive index distribution with a refractive index distribution index α in a range from 1.80 to 1.89; and the core has a maximum relative refractive index difference Δ1% in a range from 1.0% to 1.15% , and the temperature-measuring multimode optical fiber having a fusion loss less than or equal to 0.08 dB.2. The temperature-measuring multimode optical fiber according to claim 1 , having a numerical aperture in a range from 0.190 to 0.205.3. The temperature-measuring multimode optical fiber according to claim 1 , wherein the core is made of SiOquartz glass of a germanium-fluorine co-doped system.4. The temperature-measuring multimode optical fiber according to claim 1 , wherein the cladding is made of high-purity quartz glass.5. The temperature-measuring multimode optical fiber according to claim 1 , wherein the cladding has a radius in a range from 62.0 μm to 63.0 μm.6. The temperature-measuring multimode ...

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Номер записи: 11
04-01-2018 дата публикации

WATER QUALITY MEASUREMENT APPARATUS AND METHOD

Номер: US20180005507A1
Автор: Song Inho
Принадлежит: MOEN INCORPORATED

A water quality measurement apparatus is provided. The apparatus comprises an electrochemical cell, a pH sensor, a temperature sensor, a control circuit, a power source, a database, and a warning device. The electrochemical cell comprises a working electrode, a reference electrode, and a counter electrode. The control circuit provides predetermined adjustable potentials between the reference electrode and the working electrode and measures electrochemical currents between the working electrode and the counter electrode, to form a current diagram based on the predetermined adjustable potentials and the electrochemical currents. The database stores predetermined reference diagrams based on various pH values and temperatures, and is in communication with the control circuit. The warning device is configured to output warnings, wherein the control circuit triggers the warning device in the condition that the current diagram exceeds the predetermined reference diagram based on the same range of the pH values and the temperatures. 1. A water quality measurement apparatus , comprising:an electrochemical cell, comprising a working electrode, a reference electrode, and a counter electrode, wherein the working electrode, the reference electrode, and the counter electrode are configured to be inserted into water to be detected,a pH sensor, configured to detect pH values of the water and to provide a pH signal reflecting the pH values of the detected water to a control circuit,a temperature sensor, configured to detect temperatures of the water, and to provide a temperature signal reflecting the temperatures of the detected water to the control circuit,the control circuit, electrically connected to the electrochemical cell, the pH sensor, and the temperature sensor, wherein the control circuit is configured to provide predetermined adjustable potentials between the reference electrode and the working electrode and to measure electrochemical currents between the working ...

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Номер записи: 12
10-01-2019 дата публикации

BRAKE TEMPERATURE MONITORING SYSTEM

Номер: US20190009769A1
Автор: Antanaitis David B., Riefe Mark T., YEN Chih-hung
Принадлежит:

A brake temperature monitoring system configured to monitor at least one of a rotor and hydraulic fluid of a brake mechanism for a vehicle. The system including a controller including a processor and an electronic storage medium, a vehicle velocity sensor, an ambient temperature sensor, and a pre-programmed module. The vehicle velocity sensor is configured to output a velocity signal to the processor. The ambient temperature sensor is configured to output an ambient temperature signal to the processor. The model is pre-programmed into the electronic storage medium, and is adapted to estimate the temperature of at least one of the rotor and the hydraulic fluid. The estimation is based on an ambient air temperature, and a pre-established relationship between a conductive heat transfer factor and a convective heat transfer factor. The convective heat transfer factor is a function of vehicle velocity. 1. A brake temperature monitoring system configured to monitor at least one of a rotor and hydraulic fluid of a brake mechanism for a vehicle , the brake temperature monitoring system comprising:a controller including a processor and an electronic storage medium;a vehicle velocity sensor configured to output a velocity signal to the processor;an ambient temperature sensor configured to output an ambient temperature signal to the processor; anda model pre-programmed into the electronic storage medium, wherein the model is adapted to estimate the temperature of at least one of the rotor and the hydraulic fluid, based on an ambient temperature measured by the ambient temperature sensor, and a pre-established relationship between a conductive heat transfer factor and a convective heat transfer factor, with the convective heat transfer factor being a function of vehicle velocity measured by the vehicle velocity sensor.2. The brake temperature monitoring system set forth in claim 1 , wherein the convective heat transfer factor is a linear function of the vehicle velocity.3. The ...

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Номер записи: 13
15-01-2015 дата публикации

Delivery unit for a liquid additive with a temperature sensor, method for checking the operating state of a delivery unit and motor vehicle having a delivery unit

Номер: US20150013315A1
Автор: Cheikh Diouf, Finn FREDERIKSEN, Georges Maguin, Jan Hodgson, Sven Schepers
Принадлежит: EMITEC GESELLSCHAFT FUER EMISSIONSTECHNOLOGIE MBH

A delivery unit for delivering a liquid additive in a motor vehicle, includes at least one temperature sensor for contactlessly measuring a temperature at least at one measurement point in the delivery unit. The temperature sensor and the measurement point have a spacing therebetween and a radiation channel which is free from fixtures is provided between the temperature sensor and the measurement point. A method for checking the operating state of a delivery unit and a motor vehicle having a delivery unit are also provided.

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Номер записи: 14
11-01-2018 дата публикации

ZERO-EQUATION TURBULENCE MODELS FOR LARGE ELECTRICAL AND ELECTRONICS ENCLOSURE APPLICATIONS

Номер: US20180014427A1
Автор: VanGilder James William
Принадлежит:

A method comprises performing an analysis of airflow and temperature distribution in an indoor environment utilizing a hybrid turbulence model including a Chen-Xu model used for analysis of bulk flow and a wall function used in first grid cells bounding solid objects in the indoor environment and adjusting physical layout and/or operating parameters of heat producing electrical equipment and/or a cooling system of the indoor environment responsive to results of the analysis to improve one of temperature distribution within the indoor environment and operating efficiency of the cooling system of the indoor environment. 1. A method comprising:performing an analysis of airflow and temperature distribution in an indoor environment utilizing a hybrid turbulence model including a Chen-Xu model used for analysis of bulk flow and a wall function used in first grid cells bounding solid objects in the indoor environment; andadjusting physical layout and/or operating parameters of heat producing electrical equipment and/or a cooling system of the indoor environment responsive to results of the analysis to improve one of temperature distribution within the indoor environment and operating efficiency of the cooling system of the indoor environment.2. The method of claim 1 , wherein the analysis of airflow and temperature is performed on an indoor environment having dimensions consistent with those of an industry standard ISO shipping container.3. The method of claim 1 , wherein the analysis of airflow and temperature is performed on an indoor environment including an externally mounted cooling system.4. The method of claim 3 , wherein the analysis of airflow and temperature is performed on an indoor environment including cooling air supply vents defined in external walls of the indoor environment.5. The method of claim 1 , wherein the analysis of airflow and temperature is performed utilizing a Cartesian grid system with uniform computationally defined grid cells.6. The method ...

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Номер записи: 15
19-01-2017 дата публикации

DISC CAVITY THERMOCOUPLE

Номер: US20170016774A1
Автор: Olejarski Michael J.
Принадлежит:

A thermocouple and a method for making the thermocouple. The thermocouple includes a thermocouple element shaft and at least one sleeve coupled to the thermocouple element shaft in at least one location of the thermocouple element shaft that is expected to experience wear. 1. A thermocouple comprising:a thermocouple element shaft; andat least one sleeve that is affixed to the thermocouple element shaft, said at least one sleeve being wider than the thermocouple element shaft and being located in at least one region of the thermocouple element shaft that is expected to deteriorate due to wear.2. The thermocouple according to wherein the at least one sleeve is affixed to the thermocouple element shaft by crimping the at least one sleeve to the thermocouple element shaft.3. The thermocouple according to wherein the at least one sleeve is affixed to the thermocouple element shaft by welding the at least one sleeve to the thermocouple element shaft.4. The thermocouple according to wherein the at least one sleeve is approximately twice as wide in diameter relative to the thermocouple element shaft.5. The thermocouple according to wherein the at least one sleeve includes at least two sleeves that are spaced apart from each other.6. The thermocouple according to wherein the at least one sleeve includes at least two sleeves that are adjacent to one another.7. The thermocouple according to wherein the at least one sleeve is approximately two inches long.8. The thermocouple according to wherein the at least one sleeve is approximately one inch long.9. A disc cavity thermocouple for measuring temperature in a gas turbine engine claim 1 , said disc cavity thermocouple comprising:a thermocouple element shaft; andat least one sleeve that is affixed to the thermocouple element shaft, said sleeve being wider than the thermocouple element shaft and being located in at least one region of the thermocouple element shaft that is expected to deteriorate due to wear.10. The disc cavity ...

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Номер записи: 16
19-01-2017 дата публикации

A METHOD AND APPARATUS FOR DETECTING A STRUCTURAL FAULT IN A STRUCTURE

Номер: US20170016801A1
Автор: Nikles Marc
Принадлежит:

A method for detecting a structural fault in a structure includes the steps of, (a) performing a Brillouin measurement at a point along a sensing optical fiber which operably cooperates with the structure, to obtain a Brillouin gain spectrum at that point; (b) identifying at least two curves which, when added together, best fit the Brillouin gain spectrum; (c) identifying if peaks of the least two curves occur at different frequencies so as to determine if the structure has a structural fault. There is further provided a corresponding apparatus for detecting a structural fault in a structure. 1. A method for detecting a structural fault in a structure , comprising the steps of , (a) performing a Brillouin measurement at a point along a sensing optical fiber which operably cooperates with the structure , to obtain a Brillouin gain spectrum at that point;(b) identifying at least two curves which, when added together, best fit the Brillouin gain spectrum;(c) identifying if peaks of the least two curves occur at different frequencies so as to determine if the structure has a structural fault.2. The method of wherein the structure comprises at least one of a pipe claim 1 , riser claim 1 , umbilical claim 1 , power cable.3. The method of wherein the structural fault is a structural fault which gives rise to strain or compression in the structure.4. The method of wherein the structural fault is a crack through which fluid leaks out of the structure or fluid leaks into the structure.5. The method according to comprising the steps of claim 4 , identifying out of the least two curves claim 4 , the curve whose peak occurs at a frequency which is within +−10 MHz of the frequency at which the peak of the Brillouin gain spectrum occurs claim 4 , as being a reference curve and determining if hot or cold fluid is leaking through the structure at the structural fault based on whether the peak of the other of the at least two curves is offset to the right or offset to the left of the ...

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Номер записи: 17
21-01-2016 дата публикации

Water-temperature-sensor backup system

Номер: US20160017789A1
Автор: Takayuki Nishi
Принадлежит: HINO MOTORS LTD

Water-temperature sensors for detection of temperature of cooling water 12 having passed through an engine 1 are increased in number into two ( 18 and 19 ). A controller 20 is provided to confirm that each of detection values of the water-temperature sensors 18 and 19 is within a normal range and then employ either of the detection values as temperature of the cooling water 12 . The controller 20 is configured such that, when either of the detection values of the water-temperature sensors 18 and 19 is out of the normal range, the remaining detection value within the normal range is employed as temperature of the cooling water 12.

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Номер записи: 18
21-01-2016 дата публикации

METHOD FOR PRODUCING A SOOT SENSOR WITH A LASER BEAM

Номер: US20160017830A1
Автор: Teusch Dieter, WIENAND Karlheinz, ZINKEVICH Matsvei
Принадлежит:

A method for producing a soot sensor is provided. The method includes steps of applying a contiguous metallic layer on an electrically insulating substrate and structuring the metal coating with a laser beam by vaporizing areas of the metallic layer. At least two interlaced contiguous electrically conductive structures are produced. The electrically conductive structures are spatially separated from one another with the laser beam and are electrically insulated from one another such that the conductive structures substantially extend next to one another and close to one another in an area relative to a total length thereof. A soot sensor produced using such a method is also provided. The soot sensor has an electrically insulating substrate and at least two contiguous electrically conductive structures which are spatially separated from one another and are interlaced as structured metallic layers. An intermediate space between the conductive structures is burned free with a laser.

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Номер записи: 19
21-01-2016 дата публикации

OPTICAL FIBER TEMPERATURE DISTRIBUTION MEASURING DEVICE

Номер: US20160018271A1
Автор: SHIDA Hideo
Принадлежит: YOKOGAWA ELECTRIC CORPORATION

An optical fiber temperature distribution measuring device includes: an optical fiber as a sensor; a calculation control unit for measuring a temperature distribution along the optical fiber by using backward Raman scattered light from the optical fiber; a far-end-position dispersion characteristic calculation unit for obtaining a dispersion characteristic of the optical fiber at a far-end position thereof; a per-unit-length dispersion characteristic calculation unit for obtaining a per-unit-length dispersion characteristic of the optical fiber based on the dispersion characteristic of the optical fiber at the far-end position thereof; and a correction parameter calculation unit for calculating a correction parameter for correcting a dispersion characteristic of the optical fiber based on a dispersion characteristic at each of different positions along the optical fiber. 1. An optical fiber temperature distribution measuring device comprising:an optical fiber as a sensor;a calculation control unit for measuring a temperature distribution along the optical fiber by using backward Raman scattered light from the optical fiber;a far-end-position dispersion characteristic calculation unit for obtaining a dispersion characteristic of the optical fiber at a far-end position thereof;a per-unit-length dispersion characteristic calculation unit for obtaining a per-unit-length dispersion characteristic of the optical fiber based on the dispersion characteristic of the optical fiber at the far-end position thereof; anda correction parameter calculation unit for calculating a correction parameter for correcting a dispersion characteristic of the optical fiber based on a dispersion characteristic at each of different positions along the optical fiber.2. The optical fiber temperature distribution measuring device according to claim 1 , whereinthe correction parameter calculation unit is configured to obtain the correction parameter by performing a convolution calculation of an ...

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Номер записи: 20
21-01-2016 дата публикации

OPTICAL FIBER TEMPERATURE DISTRIBUTION MEASURING DEVICE

Номер: US20160018272A1
Автор: NISHIO Yuuji
Принадлежит: YOKOGAWA ELECTRIC CORPORATION

An optical fiber temperature distribution measuring device includes: an optical fiber as a sensor; a light source for outputting, to the optical fiber, signal light which has been amplified by excitation light; a temperature distribution calculation unit for measuring a temperature distribution along the optical fiber by using backward Raman scattered light from the optical fiber; an ASE light intensity variation measurement unit for measuring an intensity variation of an ASE light generated at the light source; and a temperature distribution correction unit for correcting the temperature distribution based on a measurement result of the ASE light intensity variation measurement unit.

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Номер записи: 21
22-01-2015 дата публикации

CHARACTERIZING CONTENTS OF CONDUITS, IN PARTICULAR MULTIPHASE FLOW CONDUITS

Номер: US20150020580A1
Автор: Amundsen Lene, Clark William George, Hoffman Rainer Josef, Schulkes Ruben
Принадлежит: STATOIL PETROLEUM AS

A method and apparatus for determining contents of a conduit containing at least one fluid is described. The conduit may be at least partially defined by at least one wall portion. The wall portion may be cooled. After cooling said, the temperature at least one temperature sensor located adjacent to the wall portion may be measured. A characteristic of said contents is determined based on said measured temperature at the or each temperature sensor. 1. A method of determining contents of a conduit containing at least one fluid , the conduit being at least partially defined by at least one wall portion , the method comprising:cooling said wall portion;after cooling said wall portion, measuring the temperature at at least one temperature sensor located adjacent to the wall portion; anddetermining a characteristic of said contents based on said measured temperature at the or each temperature sensor.2. A method as claimed in claim 1 , wherein the cooling step includes applying a pulse of cold fluid adjacent to the wall portion.3. A method as claimed in claim 1 , wherein the determining step comprises:determining a parameter of the contents of the conduit in proximity to the or each temperature sensor using the measured temperature at the or each temperature sensor; anddetermining a characteristic of the contents using the determined contents parameter.4. A method as claimed in claim 1 , wherein said measuring step uses a plurality of temperature sensors located adjacent to the wall portion claim 1 , and the method includes:measuring a temperature at each of the plurality of temperature sensors; using the measured temperatures to determine parameters of the contents of the conduit in proximity to each of the temperature sensors; andusing the determined content parameters to determine a characteristic of the contents of the conduit.5. A method as claimed in claim 1 , including:repeating said cooling step; andmeasuring the temperature at the or each temperature sensor after ...

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Номер записи: 22
21-01-2021 дата публикации

GAS PROBES

Номер: US20210018406A1
Автор: KNIGHT Jeremy
Принадлежит: EnDet Limited

A fluid sampling probe is provided. The probe comprises an elongate main tube having: an inlet end, an outlet end, and a fluid-sampling bore disposed within the elongate main tube and extending from the inlet end and to the outlet end; at least three elongate helical fins which are adapted to prevent or reduce probe damage caused by vortex-induced vibration. The elongate helical fins overlap along a length of the elongate main tube; and the fluid-sampling bore is open at or adjacent to the inlet end, and is adapted to receive a fluid-sample extracted from a fluid flowing past the fluid sampling probe. Numerous other aspects are provided. 1. A fluid sampling probe comprising:an elongate main tube having: an inlet end, an outlet end, anda fluid-sampling bore disposed within the elongate main tube and extending from the inlet end and to the outlet end;at least three elongate helical fins which are adapted to prevent or reduce probe damage caused by vortex-induced vibration,wherein the elongate helical fins overlap along a length of the elongate main tube; andwherein the fluid-sampling bore is open at or adjacent to the inlet end, and is adapted to receive a fluid-sample extracted from a fluid flowing past the fluid sampling probe.2. The fluid sampling probe of claim 1 , wherein the elongate main tube is substantially circular in cross-section.3. The fluid sampling probe of claim 1 , wherein each elongate helical fin includes a radially outermost surface which is flat.4. The fluid sampling probe of claim 1 , wherein circumferentially-spaced helical flow channels are defined by respective neighboring elongate helical fins.5. The fluid sampling probe of claim 4 , wherein the elongate helical fins form edges of the associated helical flow channels.6. The fluid sampling probe of claim 4 , wherein an end of each circumferentially-spaced helical flow channel is substantially flush with the outlet end.7. The fluid sampling probe of claim 4 , wherein the circumferentially- ...

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Номер записи: 23
22-01-2015 дата публикации

TEMPERATURE SENSOR

Номер: US20150023391A1
Автор: Massiera Stéphane, Sannier Jean, Seigneur Marc
Принадлежит: SC2N

The invention relates to a temperature sensor () for a motor vehicle comprising:—a housing () defining an internal volume comprising a temperature sensitive element (),—electrical wires () linked electrically to said temperature sensitive element () and configured to transmit an item of temperature information from said sensitive element () to the exterior of the housing (),—a seal () partially surrounding the said electrical wires () so as to isolate the sensitive element () with respect to the exterior of the housing (), the seal () extending preferably in a direction, termed the longitudinal direction. According to the invention, said sensor () furthermore comprises a guidance means () integral with said seal () for the guiding of said electrical wires () out of said sensor, said guidance means () lying in the extension of said seal () according to the longitudinal direction of said seal () from a central zone of the seal () towards the exterior of said sensor housing (), and the cross section of said guidance means () being of smaller dimension than that of the cross section of the seal (), at least one portion of said guidance means () lying outside the housing. 1. A temperature sensor for a motor vehicle , comprising:a housing defining an internal volume comprising a temperature-sensitive element;electrical wires electrically connected to said temperature-sensitive element and configured to send temperature information of said sensitive element outside the housing;a seal partially surrounding said electrical wires so as to isolate the sensitive element from the exterior of the housing, the seal extending along a direction referred to as the longitudinal direction; anda guide means secured to said seal for guiding said electrical wires where they emerge from said sensor, said guide means extending in continuation of said seal along the longitudinal direction of said seal, from a central region of the seal in the direction of the exterior of said sensor housing, ...

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Номер записи: 24
28-01-2016 дата публикации

MOBILE DEVICE WHICH SENSES PARTICULATE MATTER AND METHOD OF SENSING PARTICULATE MATTER WITH THE MOBILE DEVICE

Номер: US20160025628A1
Автор: CHUNG Seokwhan, Kim Jongseok
Принадлежит: SAMSUNG ELECTRONICS CO., LTD.

A mobile device which senses particulate matter is provided. The mobile device includes a housing having an air flow path through which air flows when the mobile device is shaken; an inertia sensor that detects acceleration of the mobile device; a light-scattering type sensor that irradiates the air flow path with light and detects particulate matter in air flowing through the air flow path; and a controller that includes a counter for counting the particulate matter detected by the light-scattering type sensor, and a flow rate calculator for detecting an air flow rate of the air flow path based on a detection signal of the inertia sensor. 1. A mobile device which senses particulate matter , the mobile device comprising:a housing configured to have an air flow path through which air flows in response to the mobile device being shaken;an inertia sensor configured to detect an acceleration of the mobile device;a light-scattering type sensor configured to irradiate the air flow path with light and detect particulate matter in air flowing through the air flow path; anda controller which comprises a counter configured to count the particulate matter detected by the light-scattering type sensor, and a flow rate calculator configured to detect an air flow rate of the air flow path based on a detection signal of the inertia sensor.2. The mobile device of claim 1 , further comprising a temperature sensor configured to measure a temperature of the air claim 1 , wherein the controller revises a density value of the air based on the measured temperature.3. The mobile device of claim 1 , wherein the housing comprises a first opening and a second opening through which the air flow path communicates with an external region outside the housing.4. The mobile device of claim 3 , wherein the housing comprises an upper housing and a lower housing claim 3 , andwherein the first opening is provided at the upper housing and the second opening is provided at the lower housing, and air ...

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Номер записи: 25
25-01-2018 дата публикации

ENGINE WARM-UP APPARATUS FOR VEHICLE

Номер: US20180023453A1
Автор: NARA Kenichi, OKAMURA Toru, TANIOKA Kuniyoshi
Принадлежит:

A warm-up device is provided in a cooling-water circuit, through which cooling water is circulated so as to pass through an engine. The warm-up device has a heat accumulating passage, in which a heat accumulating device is provided, and an accumulating-device bypassing passage bypassing the heat accumulating device. A waste-heat collecting device is provided in the cooling-water circuit so that heat is collected from exhaust gas from the engine and such collected heat is accumulated in the heat accumulating device. The cooling water is circulated through the heat accumulating device during a start-up operation of the engine in order to heat the cooling water flowing into the engine so as to quickly warm up the engine. 1. An engine warm-up apparatus for a vehicle comprising;a cooling-water circuit for circulating cooling water through an engine of the vehicle;a warm-up device arranged in the cooling-water circuit in such a way that the warm-up device works as a fluid resistance for a flow of the cooling water flowing into the engine, wherein the warm-up device operatively heats the cooling water during a start-up operation of the engine,wherein the warm-up device comprises;(i) a heat accumulating device having heat accumulating material for carrying out heat exchange between the cooling water and the heat accumulating material in order that waste heat of the engine is accumulated in the heat accumulating material and/or heat accumulated in the heat accumulating material is radiated to the cooling water;(ii) a passage switching device for switching a water passage for the cooling water flowing into the engine from a heat accumulating passage in which the cooling water flows through the heat accumulating device to an accumulating-device bypassing passage in which the cooling water bypasses the heat accumulating device, or vice versa; and(iii) a control unit for controlling the passage switching device in such a way that;(iii-a) the cooling water is circulated through ...

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Номер записи: 26
25-01-2018 дата публикации

BRILLOUIN-BASED DISTRIBUTED BEND FIBER SENSOR AND METHOD FOR USING SAME

Номер: US20180023948A1
Автор: Bennett Kevin Wallace, Li Ming-Jun, Li Shenping
Принадлежит:

A Brillouin-based distributed bend fiber sensor and method for using the Brillouin-based distributed bend fiber sensor are described herein. In one example, the Brillouin-based distributed bend fiber sensor is specially configured to measure a temperature distribution (ΔT), a bend angle β, and a bend radius R along a deployed fiber (e.g., four-core fiber). 1. A Brillouin-based distributed fiber sensor comprising:a fiber comprising a first core, a second core, a third core, and a fourth core, wherein the first core, the second core, and the third core are located at three different positions along a circular path within the fiber, wherein the circular path has a radius (r) to a center of the fiber, and wherein the fourth core is located at the center of the fiber; and,a Brillouin backscattering sensing mechanism coupled to the first core, the second core, the third core, and the fourth core.2. The Brillouin-based distributed fiber sensor of claim 1 , further comprising: [{'sub': B1', 'B2', 'B3', 'B4, 'obtain, prior to deployment of the fiber when the fiber has no bend applied thereto, from the Brillouin backscattering mechanism a first Brillouin frequency shift (BFS) baseline measurement (v) along the first core, a second BFS baseline measurement (v) along the second core, a third BFS baseline measurement (v) along the third core, and a fourth BFS baseline measurement (v) along the fourth core;'}, {'sub': B1', 'B2', 'B3', 'B4, 'obtain, after deployment of the fiber and when there is a bend applied to the fiber, from the Brillouin backscattering mechanism a first BFS bend measurement (v′) along the first core, a second BFS bend measurement (v′) along the second core, a third BFS bend measurement (v′) along the third core, and a fourth BFS bend measurement (v′) along the fourth core;'}], 'a processing system, coupled to the Brillouin backscattering sensing mechanism, configured to{'sub': B1', 'B2', 'B3', 'B4, 'calculate a change of a first, second, third, and fourth ...

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Номер записи: 27
28-01-2016 дата публикации

FIBER OPTIC TEMPERATURE SENSING SYSTEM AND METHOD UTILIZING BRILLOUIN SCATTERING FOR LARGE, WELL-VENTILATED SPACES

Номер: US20160027537A1
Автор: "ONEILL Nicholas Francis", Dooies Brett J., Loewen Eric P., STREGE Seth Ryan Paul
Принадлежит: GE-HITACHI NUCLEAR ENERGY AMERICAS LLC

A temperature change detection apparatus for monitoring temperature change in various portions of a large space includes a trip logic unit configured to execute a trip operation based on receipt of a trip signal at the trip logic unit; a plurality of temperature sensors each including a sensing portion composed of optical fiber cable and each being configured to generate light information indicating an amount of Brillouin scattering that occurs within the sensing portion; a plurality of monitoring units configured such that each monitoring unit determines a temperature value corresponding to each temperature sensor connected to the monitoring unit based on an amount of Brillouin scattering indicated by the light information generated by each of the connected temperature sensors, an each monitoring unit generates a trip signal when a determined temperature value exceeds a running average by more than a threshold amount. 1. A temperature change detection apparatus for monitoring temperature change in various portions of a first space comprising:a trip logic unit configured to execute a trip operation based on receipt of a trip signal at the trip logic unit;a plurality of temperature sensors being configured such that, for each of the plurality of temperature sensors, the temperature sensor includes a sensing portion composed of optical fiber cable and the temperature sensor is configured to generate light information indicating an amount of Brillouin scattering that occurs within the sensing portion; connected to temperature sensors from among the plurality of temperature sensors,', determine a temperature value corresponding to the connected temperature sensor based on an amount of Brillouin scattering indicated by the light information generated by the connected temperature sensor, the determined temperature value being indicative of a temperature at a location of the sensing portion of the connected temperature sensor, and', 'generate a comparison result based on ...

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Номер записи: 28
10-02-2022 дата публикации

INTELLIGENT SERVER-LEVEL TESTING OF DATACENTER COOLING SYSTEMS

Номер: US20220043413A1
Автор: Heydari Ali
Принадлежит:

A thermal load system for testing a datacenter liquid cooling system is disclosed. The system includes a server box having at least one thermal feature associated with at least one cooling feature and at least one flow controller, where the at least one thermal feature and the at least one flow controller are adjustable to cause cooling stress on the datacenter liquid cooling system. 1. A thermal load system for testing a datacenter liquid cooling system , comprising:a server box comprising at least one thermal feature associated with at least one cooling feature and at least one flow controller, the at least one thermal feature and the at least one flow controller adjustable to cause cooling stress on the datacenter liquid cooling system.2. The thermal load system of claim 1 , further comprising:a heating element having adjustable heat levels and located adjacent to a cold plate, the cold plate having inlet and outlet ports to circulate a cooling media from the datacenter liquid cooling system.3. The thermal load system of claim 2 , further comprising:at least one processor to control the heating element and to control the at least one flow controller, the heating element having a temperature range replicating a datacenter device and the at least one flow controller controllable to a flow rate replicating a disconnection or a liquid line connection of the datacenter liquid cooling system to the datacenter device.4. The thermal load system of claim 1 , further comprising:second server boxes comprising second thermal features, second cooling features, and second flow controllers to cause the cooling stress to be a rack-level cooling stress on the datacenter liquid cooling system.5. The thermal load system of claim 1 , further comprising:at least one first cold plate forming the at least one cooling feature or part of the at least one cooling feature that is associated with the at least one thermal feature; andat least one second cold plate associated with a ...

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Номер записи: 29
23-01-2020 дата публикации

LIQUID MEASUREMENT SYSTEMS, APPARATUS, AND METHODS OPTIMIZED WITH TEMPERATURE SENSING

Номер: US20200027533A1
Автор: LEGRAND Matthew, SIHLANICK Kevin, WHALLEY RICHARD, White James
Принадлежит: Common Sensing Inc.

An apparatus for measuring liquid volume in a container includes a plurality of light sources for emitting electromagnetic radiation (EMR) toward the container, a plurality of sensors optically coupleable to the plurality of light sources, each sensor of the plurality of sensors for detecting the EMR emitted by at least a portion of the plurality of light sources, a temperature sensor for measuring at least one temperature associated with a liquid in the container, and at least one processor for receiving data representative of the portion of the detected EMR from each of the plurality of sensors, comparing the at least one measured temperature to a temperature guideline to identify any temperature events associated with the received data; normalizing the received data based on any temperature events associated with the received data; and converting the normalized data into a signature representative of the EMR detected by the plurality of sensors. 120.-. (canceled)21. An apparatus , comprising:a light source disposed and configured to emit electromagnetic radiation toward a container containing a volume of a drug;a plurality of sensors optically coupleable to the light source, each sensor of the plurality of sensors disposed and configured to detect a portion of the electromagnetic radiation emitted by the light source;a temperature sensor disposed and configured to measure at least one temperature associated with the drug in the container; and receive, from each sensor from the plurality of sensors, data representative of electromagnetic radiation detected by that sensor;', 'receive, from the temperature sensor, data representative of the at least one measured temperature;', 'adjust the data received from each sensor from the plurality of sensors based on the at least one measured temperature to produce compensated data; and', 'convert the compensated data into a signature including a plurality of values representative of the electromagnetic radiation detected by ...

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Номер записи: 30
02-02-2017 дата публикации

SENSOR ELEMENT FOR DETECTING AT LEAST ONE PROPERTY OF A MEASURED GAS IN A MEASURED GAS CHAMBER, AND METHOD FOR MANUFACTURING THE SAME

Номер: US20170030858A1
Автор: Alt Peter, Bischoff Alexander, Buse Frank, Dotterweich Oliver, Juestel Thomas, Rottmann Andreas, Schneider Jens, Taeuber Antje
Принадлежит:

A sensor element for detecting a level of a gas component in the measured gas or a temperature of the measured gas. The sensor element includes at least one solid electrolyte layer. The solid electrolyte layer has at least one plated-through hole. The sensor element further includes a conductive element, which produces an electrically conductive connection through the plated-through hole. In the plated-through hole, the solid electrolyte layer is electrically insulated from the conductive element by an insulating element. At least one opening region of the plated-through hole is stabilized against phase transition by a stabilizing element. The stabilizing element is made at least partially of a material, which includes a noble metal and an element selected from the group consisting of: V, Nb, Ta, Sb, Bi, Cr, Mo, W. A method for manufacturing the sensor element is also provided. 115-. (canceled)16. A sensor element for detecting a level of a gas component in a measured gas or a temperature of the measured gas , the sensor element comprising:at least one solid electrolyte layer, the solid electrolyte layer having at least one plated-through hole; anda conductive element which produces an electrically conductive connection through the plated-through hole, from an upper side of the solid electrolyte layer to a lower side of the solid electrolyte layer, wherein in the plated-through hole, the solid electrolyte layer is electrically insulated from the conductive element by an insulating element;wherein at least one opening region of the plated-through hole is stabilized against phase transition by a stabilizing element, the stabilizing element being made at least partially of a material, which includes a noble metal and an element selected from the group consisting of V, Nb, Ta, Sb, Bi, Cr, Mo, and W.17. The sensor element as recited in claim 16 , wherein the noble metal is platinum.18. The sensor element as recited in claim 16 , wherein a level of the element in the ...

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Номер записи: 31
01-02-2018 дата публикации

FLOW LINE INSERT WITH INDENTATIONS

Номер: US20180031397A1
Автор: Al Faihan Lahdan Fahad
Принадлежит:

An example implementation of the subject matter described within this disclosure is a thermowell with the following features. A body has a closed end, an open end, an outer surface, and defining an interior cavity starting prior to the closed end and terminating at the open end. The outer surface defines dimples that reduce vibration in response to vortex shedding. 1. A thermowell , comprising:a body having a closed end, an open end, and an outer surface, and defining an interior cavity starting prior to the closed end and terminating at the open end, wherein the outer surface defines a plurality of dimples configured to reduce vibration in response to vortex shedding.2. The thermowell of claim 1 , wherein the body is cylindrical.3. The thermowell of claim 1 , wherein the body has a length spanning from the closed end to the open end and larger than a width of the body.4. The thermowell of claim 1 , wherein each of the plurality of dimples are circular.5. The thermowell of claim 4 , wherein each of the plurality of dimples comprises a same diameter and depth.6. The thermowell of claim 1 , wherein the plurality of dimples is evenly distributed on the outer surface.7. The thermowell of claim 1 , wherein each of the plurality of dimples comprises a depth less than one quarter of a width between the interior cavity and the outer surface claim 1 , and each of the plurality of dimples has a diameter in a range of two to four times the depth of that dimple.8. A method comprising: 'a body having a closed end, an open end, and an outer surface, and defining an interior cavity starting prior to the closed end and terminating at the open end, wherein the outer surface defines a plurality of dimples configured to reduce vibration in response to vortex shedding; and', 'in a process fluid carrying flow line flowing a process fluid flow stream, selectively positioning a thermowell in the process fluid flow stream, the thermowell comprisingaffecting drag on the body in response to ...

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Номер записи: 32
01-02-2018 дата публикации

PLANT, MEASUREMENT SYSTEM, AND METHOD FOR MEASURING TEMPERATURE AND VELOCITY OF A FLOW OF FLUID

Номер: US20180031401A1
Автор: DECOUSSEMAEKER Pascal, Haffner Ken Yves, HEINIS Dominique
Принадлежит:

A method of measuring temperature and velocity of a fluid flow passing through a device of a plant includes the step of positioning at least two sensors in the device. For each sensor, a traveling path for an acoustic signal received from another sensor is determined. Each sensor emits an acoustic signal at a frequency that differs from a frequency of an acoustic signal to be emitted by the other sensor(s) in the fluid flow. A velocity profile and temperature profile for the fluid flow based on the acoustic signals received by the sensors is determined. A measurement system can include sensors and a computer device that can determine a velocity profile and temperature profile for a fluid flow passing through a device based on the acoustic signals received by the sensors. A plant can be configured to implement the method or include an embodiment of the measurement system. 2. The method of claim 1 , wherein each sensor comprises:an acoustic transceiver having a receiver unit and a transmitter unit.3. The method of claim 1 , wherein each sensor comprises:a tweeter and a receiver.4. The method of claim 1 , wherein the determining of the velocity profile and the temperature profile comprises:accounting for the traveling path of each acoustic signal received by each sensor and for a difference between a measured travel time and an expected travel time for each acoustic signal based on a theoretical correlation between temperature and speed fluctuations of the fluid flow.5. The method of claim 4 , comprising:applying a Time-Dependent Stochastic Inversion method to account for differences between the measured travel time and the expected travel time for each acoustic signal.6. The method of claim 4 , wherein the accounting for a difference between a measured travel time and an expected travel time for each acoustic signal based on a theoretical correlation between temperature and speed fluctuations of the fluid flow comprises:consecutively calculating:(i) a spatial average ...

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Номер записи: 33
01-02-2018 дата публикации

DETERMINATION DEVICE, DETERMINATION METHOD, AND NON-TRANSITORY COMPUTER-READABLE RECORDING MEDIUM

Номер: US20180031428A1
Автор: Arioka Takahiro, FUKUDA Hiroyuki, Kasajima Takeo, Uno Kazushi
Принадлежит: FUJITSU LIMITED

A determination device includes: a memory; and a processor coupled to the memory and the processor configured to executes a process, the process comprising: generating a reference model of a sensor detection value; determining whether a time from a predetermined point in time until a deviation between the reference model and the sensor detection value exceeds a threshold is shorter than a predetermined time; and outputting a signal associated with an abnormality when the time is determined to be shorter. 1. A determination device comprising:a memory; anda processor coupled to the memory and the processor configured to executes a process, the process comprising:generating a reference model of a sensor detection value;determining whether a time from a predetermined point in time until a deviation between the reference model and the sensor detection value exceeds a threshold is shorter than a predetermined time; andoutputting a signal associated with an abnormality when the time is determined to be shorter.2. The determination device as claimed in claim 1 , wherein in the generating claim 1 , the reference model is generated with use of the sensor detection valve and detection value of a plurality of other sensors having a correlation with the sensor detection value.3. The determination device as claimed in claim 2 , wherein in the generating claim 2 , the reference model is generated by a regression analysis with use of the sensor detection value and the detection values of the plurality of other sensors.4. The determination device as claimed in claim 2 , wherein the process further comprises re-generating the reference model with use of the sensor detection value and the detection values of the plurality of other sensors of a predetermined past time from a time when a deviation between the reference model and the sensor detection value exceeds a threshold.5. The determination device as claimed in claim 2 , wherein the deviation between the reference model and the ...

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Номер записи: 34
31-01-2019 дата публикации

Method For Monitoring The Thermomechanical Behaviour Of A Subsea Pipe For Transporting Pressurised Fluids

Номер: US20190033102A1
Автор: AGOUMI Jalil, LAMOUR Vincent, MARAVAL Damien, Pionetti François-Régìs, SUNDERMANN Axel
Принадлежит:

A method of monitoring thermomechanical behavior of an undersea pipe () transporting fluid under pressure and made by assembling unit pipe elements (), comprising determining a mechanical signature specific to each unit pipe element, using a measurement cable () having an optical fiber sensor using Brillouin backscattering to measure deformation of the pipe element while it is subjected on land to various mechanical stresses in predetermined directions and magnitudes, and establishing a stiffness matrix associated with the mechanical signature of each pipe element, a step of determining a thermal signature specific to each unit pipe element, which step consists in measuring the temperature changes of the unit pipe element while it is being subjected on land to various different electrical heating powers, and in establishing a thermal transfer function associated with the thermal signature of each pipe element, and a monitoring step consisting of recovering. 1. A method of monitoring the thermomechanical behavior of an undersea pipe for transporting fluid under pressure , the undersea pipe being made by assembling together a plurality of unit pipe elements arranged end to end , the method comprising:a step of determining a mechanical signature specific to each unit pipe element, which step consists in using at least one measurement cable having at least one optical fiber sensor using at least Brillouin backscattering and positioned along the entire length of the unit pipe element to measure the deformations experienced by or simulated on said unit pipe element while it is being subjected on land to various different mechanical stresses in predetermined directions and of predetermined magnitudes, and, on the basis of the deformation measurements, in establishing a stiffness matrix associated with the mechanical signature of the unit pipe element;a step of determining a thermal signature specific to each unit pipe element, which step consists in using at least one ...

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Номер записи: 35
30-01-2020 дата публикации

Thermal Dispersion Flow Meter with Fluid Leak Detection and Freeze Burst Prevention

Номер: US20200032494A1
Автор: Kenneth Fox, Robert Trescott, Scott Pallais, Scott Shaw
Принадлежит: Sentinel Hydrosolutions LLC

A non-invasive thermal dispersion flow meter with chronometric monitor for fluid leak detection includes a heater, an ambient temperature sensor and a flow rate sensor which are configured to sense the temperature of a fluid in a conduit, and then monitor the flow of that fluid through the conduit. Based upon the ambient temperature sensor readings, the flow rate sensor and heater may be adjusted to optimize the operation of the system to detect leaks. Based on the sensor readings, the flow may be adjusted to prevent damage and leaks by relieving the system of excess pressure. Geographic location, occupancy sensors and occupant identifiers are used to control the system to facilitate operation and minimize leak damage when occupants are away.

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Номер записи: 36
11-02-2016 дата публикации

UREA WATER PIPE CLOGGING DETECTION DEVICE FOR UREA SCR

Номер: US20160040577A1
Автор: Minezawa Masanobu, NIHONGI Shigeru
Принадлежит: Isuzu Motors Limited

A clogging detection device includes a urea water sensor which detects temperature in a urea water tank, a pressure sensor which detects pressure in a urea water feed line, an exhaust gas temperature sensor disposed in an exhaust pipe upstream of a selective catalytic reduction device, and a determination unit. When a key switch is turned on, the determination unit performs a startup control to drive a supply pump and increase the pressure in a pipe segment extending to a dosing value. If a detection value of the exhaust gas temperature sensor is no greater than a predetermined temperature, and a detection value of the urea water sensor is no smaller than a freezing temperature, then the determination unit performs emptying control for returning the urea water from the pipe segment to the urea water tank to detect clogging of the pipe segment from the detection value of the pressure sensor. 1. A urea water pipe clogging detection device for urea selective catalytic reduction configured to suck urea water from a urea water tank with a supply pump and spray the urea water from a dosing valve disposed upstream of an selective catalytic reduction device via a pressurized urea water feed line , and detect clogging of a pipe segment that extends to the dosing valve from the supply pump , said urea water pipe clogging detection device comprising:a urea water sensor configured to detect urea water temperature in the urea water tank;a pressure sensor configured to detect pressure of the pressurized urea water feed line;an exhaust gas temperature sensor disposed on an exhaust pipe upstream of the selective catalytic reduction device; anda clogging determination unit configured to perform startup control for driving the supply pump and increasing pressure in the pipe segment upon turning on of a key switch, and then perform emptying control for returning the urea water from the pipe segment to the urea water tank if a detection value of the exhaust gas temperature sensor is ...

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Номер записи: 37
06-02-2020 дата публикации

AIR TEMPERATURE SENSOR HAVING A BUSHING

Номер: US20200041352A1
Автор: Ashton Gregory Lloyd, Goedel Jarodd Dan, Parsons John Patrick
Принадлежит:

An air temperature sensor for use on an aircraft can include a housing defining an interior and having a trailing edge, a temperature sensor having a distal end and located within the interior, a support tube surrounding at least a portion the temperature sensor, an element shroud surrounding at least a portion of support tube, and a bushing isolating the trailing edge of the housing from the distal end of temperature sensor. 1. An air temperature sensor assembly , the air temperature sensor assembly comprising:a housing defining an interior and having a trailing edge;a temperature sensor having a distal end and located within the interior;a support tube surrounding at least a portion the temperature sensor;an element shroud surrounding at least a portion of support tube; anda bushing isolating the trailing edge of the housing from the distal end of temperature sensor.2. The air temperature sensor assembly of wherein the bushing is press fit between the element shroud and the support tube.3. The air temperature sensor assembly of wherein the bushing further comprises an aperture through a length of the bushing.4. The air temperature sensor assembly of wherein the support tube is press fit into the aperture of the bushing.5. The air temperature sensor assembly of wherein the distal end of the temperature sensor is spaced from an end wall of the bushing.6. The air temperature sensor assembly of wherein an outer wall of the bushing is press fit into the distal end of the element shroud.7. The air temperature sensor assembly of wherein the bushing further comprises a lip for acting as a stop for element shroud.8. The air temperature sensor assembly of wherein the bushing holds the support tube and element shroud in fixed relationship relative to one another.9. The air temperature sensor assembly of further comprising a gap between the support tube and element shroud.10. The air temperature sensor assembly of wherein the gap is uniform about a circumference of the ...

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Номер записи: 38
06-02-2020 дата публикации

EXHAUST GAS TEMPERATURE SENSOR

Номер: US20200041353A1
Автор: Burger Cliff, Hendricks William Joseph, Jackson David Reece, Parsons John Patrick
Принадлежит:

A temperature sensor assembly having a support tube defining an interior, a temperature sensor having a distal end and a proximal end located within the interior, and, a concentric ring surrounding at least a portion of the temperature sensor and the concentric ring is positioned between the temperature sensor and the support tube for holding the temperature sensor in the support tube. 1. A temperature sensor assembly comprising:a support tube defining an interior;a temperature sensor having a distal end and a proximal end located within the interior; anda concentric ring surrounding at least a portion of the temperature sensor and wherein the support tube surrounds at least a portion the concentric ring and the temperature sensor and the concentric ring is positioned between the temperature sensor and the support tube for holding the temperature sensor in the support tube.2. The temperature sensor assembly of further comprising a gap between the support tube and the temperature sensor for allowing exhaust gas to flow into contact with the temperature sensor.3. The temperature sensor assembly of wherein the concentric ring centers the temperature sensor in the support tube.4. The temperature sensor assembly of wherein the support tube further comprises an inflow exhaust gas aperture for allowing exhaust gas to flow into the gap to contact the temperature sensor.5. The temperature sensor assembly of wherein the support tube further comprises at least one outflow exhaust gas aperture to allow exhaust gas to flow out of the gap away from the temperature sensor.6. The temperature sensor assembly of wherein the at least one outflow exhaust gas aperture comprises two exhaust gas apertures equally spaced about the inflow exhaust gas aperture.7. The temperature sensor assembly of wherein the two exhaust gas apertures are positioned 90 degrees from the inflow exhaust gas aperture.8. The temperature sensor assembly of wherein the concentric ring is positioned between the ...

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Номер записи: 39
06-02-2020 дата публикации

DUAL WAVELENGTH DISTRIBUTED TEMPERATURE SENSING WITH BUILT-IN FIBER INTEGRITY MONITORING

Номер: US20200041360A1
Автор: CHAMPAVERE Andre
Принадлежит: VIAVI SOLUTIONS INC.

In some examples, a temperature distribution sensor may include a laser source to emit a laser beam that is tunable to a first wavelength and a second wavelength for injection into a device under test (DUT). A first wavelength optical receiver may convert a return signal corresponding to the first wavelength with respect to Rayleigh backscatter or Raman backscatter Anti-Stokes. A second wavelength optical receiver may convert the return signal corresponding to the second wavelength with respect to Rayleigh backscatter or Raman backscatter Stokes. Bending loss associated with the DUT may be determined by utilizing the Rayleigh backscatter signal corresponding to the first wavelength and the Rayleigh backscatter signal corresponding to the second wavelength. Further, temperature distribution associated with the DUT may be determined by utilizing the Raman backscatter Anti-Stokes signal corresponding to the first wavelength and the Raman backscatter Stokes signal corresponding to the second wavelength. 1. A temperature distribution sensor comprising:a laser source to emit a laser beam that is tunable to a first wavelength and to a second wavelength for injection into a device under test (DUT);a first wavelength optical receiver to convert a return signal corresponding to the first wavelength with respect to Rayleigh backscatter or Raman backscatter Anti-Stokes;a second wavelength optical receiver to convert the return signal corresponding to the second wavelength with respect to Rayleigh backscatter or Raman backscatter Stokes;a processor; and 'determine bending loss associated with the DUT by utilizing the Rayleigh backscatter signal corresponding to the first wavelength and the Rayleigh backscatter signal corresponding to the second wavelength.', 'a memory storing machine readable instructions that when executed by the processor cause the processor to2. The temperature distribution sensor according to claim 1 , wherein the machine readable instructions claim 1 , when ...

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Номер записи: 40
06-02-2020 дата публикации

BRILLOUIN SCATTERING MEASUREMENT METHOD AND BRILLOUIN SCATTERING MEASUREMENT DEVICE

Номер: US20200041411A1
Автор: KISHIDA Kinzo, Koyamada Yahei, Nishiguchi Kenichi
Принадлежит: NEUBREX CO., LTD.

In a measurement requiring a high space resolution using S-BOTDR, a pulse train composed of a plurality of pulses having the interval between the pulses longer than the phonon lifetime is interpulse-code-modulated. A Golay code is used for the interpulse code modulation to eliminate the sidelobes of the correlation in using a technique of correlation. In a technique without using correlation, an Hadamard matrix is used for the interpulse code modulation and the resultant matrix is inverted in the signal processing. 16-. (canceled)7. A Brillouin scattering measurement method that uses a composite pulse train composed of composite pulses with an interval of the composite pulse train being longer than a phonon lifetime; each composite pulse being formed of two kinds of optical pulses having different durations generated from a laser light from a laser source , by combining both optical pulses as a pair to be located at respective predetermined time positions; and injects the composite pulse train into one end of an optical fiber provided to a measurement object , to measure physical quantities of the measurement object from frequency shift change of Brillouin backscattered light generated by the composite pulse train in the optical fiber , the Brillouin scattering measurement method comprising the steps of:phase-modulating one of the optical pulses on the basis of two Golay code sequences;optically heterodyne-receiving the Brillouin backscattered light from each composite pulse with a reference light from the laser light source, to output as a first signal;heterodyne-receiving the first signal with a signal having a predetermined frequency and then passing the heterodyne-received signal through two kinds of low-pass filters corresponding to the optical pulses, to output the filtered signals as second signals;calculating, for each Golay code sequence, cross-spectrum of one of the second signals and a complex conjugate signal of the other second signal;calculating a ...

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Номер записи: 41
18-02-2021 дата публикации

METHOD AND SYSTEM FOR PROCESSING A TEMPERATURE MEASUREMENT SIGNAL DELIVERED BY A SENSOR

Номер: US20210048351A1
Автор: GIRAUDET DE BOUDEMANGE Benoit Pierre Marie
Принадлежит: SAFRAN AIRCRAFT ENGINES

A method for processing a measurement signal T of a temperature delivered by a sensor includes digitally modeling, by a modeled signal T the temperature measured by the sensor; estimating a lag error signal for this sensor, on the basis of the modeled signal T and of a signal T obtained by filtering the modeled signal, this filtering being parameterized by an estimate of a time constant of the sensor. A temperature signal is obtained by adding to a signal T derived from the measurement signal T the product of a real parameter K by a signal resulting from the subtraction of the signal T from the modeled signal T the value of the parameter K applied during the obtaining step varying over time and depending on the value of the estimated lag error signal. 111-. (canceled)13. The processing method as claimed in claim 12 , wherein the value of the parameter K varies linearly between the values 0 and 1 as a function of the value of the lag error signal estimated when the absolute value of the lag error signal is varying between the zero value and the first predetermined threshold.14. The processing method as claimed in claim 12 , wherein said temperature is a temperature of a fluid flowing through an aircraft engine and wherein claim 12 , when it is detected simultaneously that the value of the estimated lag error signal is zero and that said temperature is undergoing a succession of rapid variations claim 12 , the value of the parameter K is kept equal to the value that it had before said detection or is permitted to vary with respect to this value only by a predetermined maximum quantity.15. The processing method as claimed in claim 14 , further comprising detecting that the temperature is undergoing a succession of rapid variations when a variation in a rotation speed of the aircraft engine is greater than a second predetermined threshold.1641. The processing method as claimed in claim 12 , wherein the signal T is equal to the measurement signal T.1741. The processing ...

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Номер записи: 42
19-02-2015 дата публикации

Method and system for gas temperature measurement

Номер: US20150049786A1
Автор: Guanghua Wang, Nirm Velumylum Nirmalan, Robert David Briggs, Robert Michael Zacharias, Ronald Scott Bunker, Shawn David Wehe, Todd Garrett Wetzel
Принадлежит: General Electric Co

A temperature measurement system includes a plurality of filaments. The plurality of filaments are configured to emit thermal radiation in a relatively broad and substantially continuous wavelength band at least partially representative of a temperature of the plurality of filaments. A first and second portion of the filaments has a differing first and a second diameter and/or emissivity, respectively. The system also includes a detector array configured to generate electrical signals at least partially representative of the thermal radiation received from the filaments. The system further includes a controller communicatively coupled to the detector array configured to transform the first electrical signals to a first temperature indication at least partially as a function of the first diameter and/or first emissivity and transform the second electrical signals to a second temperature indication at least partially as a function of the second diameter and/or emissivity.

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Номер записи: 43
06-02-2020 дата публикации

SYSTEM FOR DISTRIBUTED MONITORING OF PERTURBATION IN GIGABIT PASSIVE OPTICAL NETWORK (GPON) ARCHITECTURE AND METHOD THEREOF

Номер: US20200045389A1
Автор: CHAI Tee Din, HANN Fong Kok, JAMALUDIN Muhammad Lukman Hadi, LAMBAK Zainuddin Bin, MASKURIY Farha Binti
Принадлежит: Telekom Malaysia Berhad

The present invention relates to a system and method for distributed monitoring of perturbation in Gigabit Passive Optical Network (GPON) architecture. The system based on Brillouin Optical Time Domain Analysis (BOTDA) includes a BOTDA module; where in the module includes signal source module, an optical circulator connected to a Wavelength Division Multiplexer (WDM); a wavelength reflector deployed near to an Optical Network Unit (ONU) along the optical fiber line; a photodetector connected to the optical circulator; and a signal processing module. 1. A system for distributed monitoring of perturbation in Gigabit Passive Optical Network , GPON , architecture , characterized in that , the system which is based on Brillouin Optical Time Domain Analysis , BOTDA , comprising: wherein the multi-wavelength sensing signal includes a first sensing signal and a second sensing signal produced by the signal source module, each transmitted at different predetermined transmitting periods;', 'wherein the second sensing signal is subject to stimulated Brillouin scattering to generate a backscattered sensing signal;, 'a signal source module comprising fiber path ports each configured for generating a multi-wavelength sensing signal,'} wherein the WDM combines the first sensing signal with a data signal generated by an Optical Line Terminal, OLT for producing a combined signal;', 'wherein the combined signal is guided within the GPON architecture through an optical fiber line;, 'an optical circulator connected to a Wavelength Division Multiplexer, WDM, for circulating the first sensing signal to a GPON architecture,'} a photodetector connected to the optical circulator for receiving reflected sensing signal from wavelength reflector and backscattered sensing signal, wherein the reflected sensing signal and the backscattered sensing signal are converted to a digital sensing signal by a signal digitizer;', 'a signal processing module for analyzing the digital sensing signal received ...

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Номер записи: 44
03-03-2022 дата публикации

TEMPERATURE SENSOR ISOLATION IN SMART-HOME DEVICES

Номер: US20220065704A1
Автор: Dong William, Mitchell Michael, RAGHUPATHY Arun, Shanov Adrian
Принадлежит: Google LLC

A smart-home device may include a housing, a printed circuit board (PCB) inside the housing, an environmental sensor mounted to the PCB inside the housing, and a gasket that encloses the environmental sensor inside the housing to isolate the environmental sensor from an atmosphere inside of the housing while allowing an atmosphere outside of the housing to enter the gasket such that the environmental sensor can measure an aspect of the atmosphere outside of the housing.

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Номер записи: 45
03-03-2022 дата публикации

TEMPERATURE SENSOR

Номер: US20220065706A1
Автор: Artus David E., Geislinger Dale F., Nunez Christian Gerardo
Принадлежит:

A temperature sensor for accurately measuring a temperature, such as that of a fluid where the temperature is changing, can include a housing with an exterior surface extending between a first end and a second end. The temperature sensor housing can include a set of exterior grooves, which provides for coupling a set of temperature sensor probes along the exterior of the housing with a probe extending at the first end. Additionally, a set of recesses can be formed in the first end for positioning the probes within the recesses. Furthermore, the interior of the housing can be hollow, with a second type of probe extending through the interior between the first end and the second end.

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Номер записи: 46
14-02-2019 дата публикации

MASS-AIRFLOW MEASUREMENT CONVERSION APPARATUS FOR INTERNAL COMBUSTION ENGINE CARBURETORS

Номер: US20190048819A1
Автор: Bowling Bruce A., Grippo Albert C.
Принадлежит:

A controller for an electronic fuel injection system for an internal combustion engine includes: a plurality of analog-to-digital (A/D) converters; a memory; and a processor communicatively coupled to the A/D converters and the memory. The A/D converters are configured to receive analog electrical signals representing pressures generated by a plurality of pressure sensors disposed at different locations along an air intake path and output corresponding digital signals representing the pressures, one or more of the pressure sensors are disposed in a body of a carburetor rendered permanently inoperable to mix fuel with air flowing in the air intake path, and the processor is configured to receive the digital signals representing the pressures output from the A/D converters and output a mass air flow signal representing a mass air flow rate as to an engine management system to control the electronic fuel injection system based on the received pressure signals. 1. A controller for an electronic fuel injection system for an internal combustion engine , the controller comprising:a plurality of analog-to-digital (A/D) converters;a memory;and a processor communicatively coupled to the plurality of A/D converters and the memory, the plurality of A/D converters are configured to receive analog electrical signals representing pressures generated by a plurality of pressure sensors disposed at different locations along an air intake path of the internal combustion engine and output corresponding digital signals representing the pressures,', 'one or more of the plurality of pressure sensors are disposed in a body of a carburetor rendered permanently inoperable to mix fuel with air flowing in the air intake path, and', 'the processor is configured to receive the digital signals representing the pressures output from the plurality of A/D converters and output a mass air flow signal representing a mass air flow rate as to an engine management system to control the electronic fuel ...

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Номер записи: 47
25-02-2016 дата публикации

TEMPERATURE SENSOR

Номер: US20160054182A1
Автор: YOSHIDA Kouichi
Принадлежит:

A temperature sensor includes a metal tube containing thermo-sensitive element and filled with an insulating filling material, and a housing to which the metal tube is fixed. The metal tube includes a small-diameter part and a large-diameter part. The distal end of the small-diameter part is located beyond a virtual line. The virtual line passes a center of a maximum virtual circle which is an inscribed circle that contacts at least three inner surfaces of the pipe in a cross-section perpendicular to an axial direction of the pipe, and is perpendicular to a center axis line of the metal tube. The whole of the small-diameter part and the part of the large-diameter part filled with the filling material are located within a center virtual circle which is coaxial with the maximum virtual circle and has an inner diameter of ⅔ of that of the maximum virtual circle. 1. A temperature sensor comprising:a thermo-sensitive element;a metal tube containing therein the thermo-sensitive element, a distal end thereof at which the thermo-sensitive element is disposed being closed;an insulating filling material filled in the metal tube; anda housing to which a proximal end portion of the metal tube is fixed, the housing being fitted to a pipe through which a measurement gas flows,at least a distal end portion of the metal tube being disposed inside the pipe, whereinthe metal tube includes a small-diameter part located on a distal end side thereof, and a large-diameter part located on a proximal end side of the small-diameter part and having an outer diameter larger than an outer diameter of the small-diameter part,the outer diameter of the small-diameter part is in a range between 1 mm and 3 mm, a ratio of a length of the small-diameter part to the outer diameter of the small-diameter part being in a range between 8 and 15,the filling material is filled continuously in a whole of the small-diameter part and a part of the large-diameter part,a distal end of the small-diameter part is ...

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Номер записи: 48
25-02-2016 дата публикации

TRACKING DEVICE

Номер: US20160054448A1
Автор: DESMARAIS Richard Mark, GAMES Bill, Leshuk Jeffrey Allen, STREIT Blair, UYS Tim, Varga Stephen, WALD Robin L., WOOLF Grant Heston
Принадлежит:

A tracking device () configured to track a shipment of cargo is provided including a housing () having a complementary top portion () and bottom portion (). The top portion and the bottom portion of the housing are pivotally coupled. A tracking unit, arranged within the housing, includes a processor configured to collect and transmit data. A power unit having at least one power source is arranged within the housing and is configured to supply power to the tracking unit. A circuit board connects the power unit and the tracking unit. The circuit board includes a metal tab arranged adjacent a conductive interface. A portion of a pull tab () formed from a thin, non-conductive material is arranged between the tab and the conductive interface. The tracking device is configured to transform from an inactive state to a fully active state upon removal of the pull tab (). 1. A tracking device configured to track a shipment of cargo , comprising:a housing having a complementary top portion and bottom portion, the top portion and the bottom portion being pivotally coupled;a tracking unit arranged within the housing and configured to collect and transmit data;a power unit having at least one power source arranged within the housing, the power unit being configured to supply power to the tracking unit;a circuit board connecting the power unit and the tracking unit, the circuit board includes a metal tab arranged adjacent a conductive interface, a portion of a pull tab formed from a thin, non-conductive material is arranged between the tab and the conductive interface, wherein the tracking device is configured to transform from an inactive state to a fully active state upon removal of the pull tab.2. The tracking device according to claim 1 , wherein the metal tab is biased into contact with the conductive interface.3. The tracking device according to claim 1 , wherein the power source includes at least one battery.4. The tracking device according to claim 3 , wherein the at least ...

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Номер записи: 49
25-02-2021 дата публикации

SENSOR MODULE FOR AIR QUALITY MEASUREMENT

Номер: US20210055139A1
Автор: BECKER Manuel, Braun Stephan, BRUGGER Thomas, Merz Matthias, Schmid Tobias
Принадлежит:

A sensor module as well as a method for manufacturing a sensor module for determining a property of a fluid, in particular for measuring air quality, comprises a printed circuit board, at least one sensor on the printed circuit board for measuring a parameter of the surrounding air and a housing for the printed circuit board. A part of the printed circuit board protrudes from an opening in the housing (), wherein the at least one sensor () is located on a front side of the protruding part of the printed circuit board. In addition, at least the front side of the protruding part of the printed circuit board, with the exception of a recess for the at least one sensor, is encapsulated with a filling compound. The sensor module can be used in an interior or an air duct of motor vehicles or buildings. In one embodiment, the sensor module measures temperature, relative humidity and gas concentration in a fluid, especially in the surrounding air. 1. Sensor module for determining a property of a fluid , in particular for measuring air quality , comprisinga printed circuit board,at least one sensor on the printed circuit board for recording a parameter of the fluid, in particular of the surrounding air, anda housing for the circuit board,wherein a part of the circuit board protrudes from an opening in the housing,wherein the at least one sensor is located on a front side of the protruding part of the printed circuit board,wherein at least the front side of the protruding part of the printed circuit board, with the exception of a recess for the at least one sensor, is encapsulated with a filling compound.2. Sensor module according to claim 1 , wherein at least a back side of the protruding part of the printed circuit board claim 1 , with the exception of a further recess which is opposite the at least one sensor claim 1 , is encapsulated with filling compound.3. Sensor module according to claim 1 , wherein at least the opening in the housing is encapsulated with filling ...

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Номер записи: 50
13-02-2020 дата публикации

AN ASSEMBLY AND THE RELATED METHOD FOR MEASURING THE TEMPERATURE OF A FLUID FOR HYPERTHERMIC TREATMENT OF A BODY CAVITY

Номер: US20200049566A1
Автор: PERSY Rogier Thomas
Принадлежит:

An assembly for measuring the temperature of a fluid for hyperthermic treatment of a body cavity includes a tubular structure having a tubular wall and an opening; a temperature sensing element having a temperature sensor; a sensor cap having a cap inner surface and a cap outer surface encapsulating the temperature sensor in direct contact with the cap inner surface, and connected to the tubular wall such that the encapsulated temperature sensor is positioned in the tubular structure through the opening; and a connector such that the sensor cap and the tubular wall are connected in a releasable manner by means of the connector. 115-. (canceled)16. An assembly for measuring the temperature of a fluid for hyperthermic treatment of a body cavity , said fluid flowing in a tubular inner area of a tubular structure , said assembly comprising:said tubular structure comprising:a tubular wall with an inner surface and an outer surface enclosing said tubular inner area; andan opening defined through said tubular wall from said inner surface to said outer surface of said tubular structure;a temperature sensing element adapted to measure temperature, said temperature sensing element comprising a temperature sensor and at least one wire electrically coupled to said temperature sensor at a coupling point;a sensor cap comprising a cap inner surface and a cap outer surface,wherein said sensor cap encapsulates said temperature sensor, andwherein said sensor cap is connected to said tubular wall of said tubular structure such that said encapsulated temperature sensor is positioned in said tubular inner area of said tubular structure through said opening; anda connector;wherein:said sensor cap encapsulates said temperature sensor such that said temperature sensor is in direct contact with said cap inner surface of said sensor cap; andsaid sensor cap and said tubular wall are connected in a releasable manner by means of said connector such that said opening is sealed when connected.17. ...

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Номер записи: 51
22-02-2018 дата публикации

METHOD AND SYSTEM FOR MANAGING COOLING DISTRIBUTION

Номер: US20180052063A1
Автор: Gennello Anthony
Принадлежит: DCIM Solutions, LLC

Accurate measurement and monitoring of a computer room air conditioning unit's cooling production, distribution, and consumption is necessary to optimize effectiveness and efficiency and minimize redundancy. A mass air flow monitoring device comprises an array of sensor modules and a controller module with display, user interface, and I/O for third party connectivity. The device monitors temperature, pressure, water content, and quantity of airflow in a CRAC's supply air stream and return air stream and compares the two measurements to determine the amount of energy, or enthalpy, put into or taken out of the air. The result, displayed in watts, allows for the efficient control of production, distribution, and usage of supply air from the CRAC unit. Over or under provisioning can be quickly identified and corrected and, when used in conjunction with power consumption monitoring, a “watts of cooling for watts of power consumption” efficiency metric can be provided. 1. A system for managing cooling distribution , comprising:a first array of sensor modules positioned in a return air stream;a second array of sensor modules positioned in a supply air stream;a controller communicatively connected to the first array of sensor modules and the second array of sensor modules;wherein mass air flow is measured by the controller through the first array of sensor modules;mass air flow is measured by the controller through the second array of sensor modules;measurements from the first array of sensor modules are compared to measurements from the second array of sensor modules to calculate enthalpy gain or lost between the return air stream and the supply air stream; and the controller manages cooling distribution by adjusting supply air stream temperature as a function of the enthalpy gain or lost between the return air stream and the supply air stream.2. The system of claim 1 , wherein mass air flow includes temperature claim 1 , pressure claim 1 , water content and quantity of ...

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Номер записи: 52
01-03-2018 дата публикации

Float with fishing conditions detection

Номер: US20180055028A1
Автор: Cheng Ying Weng, Ta Wei Chung, Yin Hui Hsieh
Принадлежит: Intel Corp

Embodiments of the present disclosure provide for an apparatus for a float with fishing conditions detection capabilities. In one instance, the float may include a float case, one or more sensors disposed inside the float case, and a processing block coupled with the sensors and disposed inside or outside the float case. The processing block may be configured to detect one or more conditions of fishing. To detect the conditions of fishing, the processing block may be configured to receive and process sensor readings from the sensors, and determine the conditions of fishing, based on a result of the processing of the sensor readings. Other embodiments may be described and/or claimed.

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Номер записи: 53
21-02-2019 дата публикации

AIRCRAFT CABIN AIR TEMPERATURE SENSING APPARATUS AND SYSTEM USING PASSIVE AIR FLOW

Номер: US20190055024A1
Автор: FAGUNDES Sandro Afonso Silva, STEFANINI Luciano Martinez, Wang Hongzhi
Принадлежит:

An air temperature sensing apparatus and a system for an aircraft includes an ejector with a first air duct for receiving a first air flow from an aircraft air distribution duct, the first air duct defining a first cross-sectional area, a second air duct for receiving a second air flow from a passenger compartment of the aircraft, the second air flow merging with the first air flow downstream of the second air duct, and a restrictor connected to the first air duct defining a minimal cross-sectional area. The apparatus and system also include a temperature sensor in fluid communication with the second air flow. The minimal cross-sectional area of the restrictor is smaller than the first cross-sectional area of the first air duct to create a region of low pressure within the ejector, causing the second air flow to be suctioned over the temperature sensor. 1. An air temperature sensing apparatus for an aircraft , comprising: a first air duct for receiving a first air flow from an aircraft air distribution duct, the first air duct defining a first cross-sectional area,', 'a second air duct for receiving a second air flow from a passenger compartment of the aircraft, the second air flow merging with the first air flow downstream of the second air duct, and', 'a restrictor connected to the first air duct defining a minimal cross-sectional area; and, 'an ejector comprising'}a temperature sensor in fluid communication with the second air flow,wherein the minimal cross-sectional area of the restrictor is smaller than the first cross-sectional area of the first air duct so as to create a region of low pressure within the ejector, causing the second air flow to be suctioned over the temperature sensor and through the second air duct.2. The air temperature sensing apparatus of claim 1 , wherein the restrictor defines a restrictor length claim 1 , the restrictor decreasing in cross-sectional area over at least a portion of the restrictor length to the minimal cross-sectional ...

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Номер записи: 54
03-03-2016 дата публикации

Temperature distribution prediction method and air conditioning management system

Номер: US20160061668A1
Автор: Hiroyuki Fukuda, Kazushi Uno, Masao Kondo, Masatoshi Ogawa, Masayuki Fujita, Minoru Ishinabe, Takeo Kasajima, Takeshi Hatanaka
Принадлежит: Fujitsu Ltd

A temperature distribution prediction method of predicting a predetermined temperature distribution in an air conditioning system, the air conditioning system including an air conditioner for supplying temperature-adjusted air into a room where racks in which electronic apparatuses are accommodated are installed; and air blowers for transferring the air supplied from the air conditioner to an intake side of the racks, the method includes: measuring the temperature distribution for actual conditions varying the operating situations of the air blowers; and predicting the temperature distribution for conditions of non-measurement for the air blowers based on the measured values.

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Номер записи: 55
03-03-2016 дата публикации

WIRELESS COMBUSTION/EFFICIENCY ANALYZER

Номер: US20160061799A1
Автор: Epperson David L.
Принадлежит:

A technician uses a wireless apparatus and system to vary air or fuel in the burner to optimize efficiency and safety. A wireless remote sensor unit has a probe in a flue to draw a sample of combustion gas from the flue for gas sensors and a temperature sensor. The sensors generate analog signals of gas identity, concentration and temperature that are converted to digital signals by an A-to-D converter. A wireless transceiver sends digital signals to a hand held unit or central computer via wireless transmission. The hand held unit receives the digital signals and displays an analysis of the signals. The analysis may be performed by any one of the remote sensor unit, the hand held unit, or the central computer. The wireless unit also receives control signals for the hand held unit or the central computer. 1. A gas analyzer system comprising: a housing;', 'an elongated sampling tube extending from the housing and configured to have one end pass through a wall of a flue into a bore of the flue;', 'a pump having an inlet and an outlet, the inlet disposed at the other end of the sampling tube for drawing a sample of combustions gas from the flue into the housing;', 'one or more gas sensors, in fluid communication with the outlet of the pump, said gas sensor(s) configured to sense a presence of one or more gases in the combustion gas and to measure a concentration of one or more gases in the combustion gas;', 'a temperature sensor for sensing the temperature of the sample of combustion gas;', 'a wireless transceiver coupled to the gas sensor for sending signals representative of temperature, type of gases and concentrations of gases and for receiving control signals;, 'a remote sensor unit having'} a wireless transceiver for receiving signals representative of temperature, types of gases and concentrations of gases and for transmitting control signals;', 'a display for showing the temperature, types of gases and concentrations of gases; and', 'circuitry and software ...

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Номер записи: 56
05-03-2015 дата публикации

NON-INTRUSIVE MEASURMENT OF HOT GAS TEMPERATURE IN A GAS TURBINE ENGINE

Номер: US20150063411A1
Автор: Claussen Heiko, DeSilva Upul P., Rosca Justinian, Ulerich Nancy H., Yan Michelle Xiaohong
Принадлежит:

A method and apparatus for operating a gas turbine engine including determining a temperature of a working gas at a predetermined axial location within the engine. An acoustic signal is encoded with a distinct signature defined by a set of predetermined frequencies transmitted as a non-broadband signal. Acoustic signals are transmitted from an acoustic transmitter located at a predetermined axial location along the flow path of the gas turbine engine. A received signal is compared to one or more transmitted signals to identify a similarity of the received signal to a transmitted signal to identify a transmission time for the received signal. A time-of-flight is determined for the signal and the time-of-flight for the signal is processed to determine a temperature in a region of the predetermined axial location. 1. A method of operating a gas turbine engine , including determining a temperature of a working gas passing through a flow path within the gas turbine engine , the method comprising the steps of:transmitting an acoustic signal from an acoustic transmitter located at a predetermined axial location along the flow path of the gas turbine engine;receiving the acoustic signal from the acoustic transmitter at an acoustic receiver located at the predetermined axial location;the acoustic signal being encoded with a distinct signature defined by a set of predetermined frequencies transmitted as a non-broadband acoustic signal;wherein receiving the acoustic signal includes comparing a received signal to one or more transmitted signals to identify a similarity of the received signal to a transmitted signal to identify a transmission time for the received signal;determining a time-of-flight for the signal from the acoustic transmitter to the acoustic receiver; andprocessing the time-of-flight for the signal to determine a temperature in a region of the predetermined axial location.2. The method of claim 1 , wherein comparing the received signal to one or more ...

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Номер записи: 57
05-03-2015 дата публикации

LOSS COMPENSATION FOR DISTRIBUTED SENSING IN DOWNHOLE ENVIRONMENTS

Номер: US20150063418A1
Автор: Chandran Ashwin, Lambert Christopher H., Wysocki Paul F.
Принадлежит: BAKER HUGHES INCORPORATED

An apparatus for estimating a parameter includes: an optical fiber sensor including at least one optical fiber configured to be disposed in a downhole location and including at least one sensing location configured to generate measurement signals; at least one light source configured to transmit a measurement signal having a wavelength to interrogate a sensing location and cause the sensing location to return a reflected measurement signal indicative of a measured parameter, and configured to transmit a reference signal and cause a reflected reference signal to be returned from a location associated with the sensing location, the reflected reference signal having a known relationship to hydrogen concentration; and a processor configured to receive the reflected measurement signal and the reflected reference signal, estimate the hydrogen concentration based on the reflected reference signal, and calibrate the first reflected signal based on the estimated hydrogen concentration. 1. An apparatus for estimating a parameter , the apparatus comprising:an optical fiber sensor including at least one optical fiber configured to be disposed in a downhole location, the at least one optical fiber including at least one sensing location disposed along the optical fiber and configured to generate measurement signals;at least one light source configured to transmit a measurement signal having a wavelength to interrogate a sensing location and cause the sensing location to return a reflected measurement signal indicative of a measured parameter, and configured to transmit a reference signal and cause a reflected reference signal to be returned from a location associated with the sensing location, the reflected reference signal having a known relationship to hydrogen concentration; anda processor configured to receive the reflected measurement signal and the reflected reference signal, estimate the hydrogen concentration based on the reflected reference signal, and calibrate the ...

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Номер записи: 58
01-03-2018 дата публикации

TEMPERATURE MEASUREMENT DEVICE, TEMPERATURE MEASUREMENT METHOD, AND COMPUTER-READABLE NON-TRANSITORY MEDIUM

Номер: US20180058947A1
Автор: Arioka Takahiro, FUKUDA Hiroyuki, Kasajima Takeo, Uno Kazushi
Принадлежит: FUJITSU LIMITED

A temperature measurement device includes: a light source configured to input a light into an optical fiber; a detector configured to detect a Stokes component and an anti-Stokes component from a back scattering light from the optical fiber; a memory; and a processor configured to execute a process, the process comprising: in a predetermined region including a sample point of the optical fiber, calculating a range including the sample point in accordance with a largeness of a correlation between the Stokes component and the anti-Stokes component; smoothing the Stokes component and the anti-Stokes component in the range; and measuring a temperature of the sample point with use of the Stokes component and the anti-Stokes component that are smoothed by the corrector. 1. A temperature measurement device comprising:a light source configured to input a light into an optical fiber;a detector configured to detect a Stokes component and an anti-Stokes component from a back scattering light from the optical fiber;a memory; anda processor configured to execute a process, the process comprising:in a predetermined region including a sample point of the optical fiber, calculating a range including the sample point in accordance with a largeness of a correlation between the Stokes component and the anti-Stokes component;smoothing the Stokes component and the anti-Stokes component in the range; andmeasuring a temperature of the sample point with use of the Stokes component and the anti-Stokes component that are smoothed by the corrector.2. The temperature measurement device as claimed in claim 1 , wherein claim 1 , in the calculating claim 1 , the range is elongated as the largeness of the correlation decreases.3. The temperature measurement device as claimed in claim 1 , wherein claim 1 , in the calculating claim 1 , an upper limit value of the range is set when the largeness of the correlation is less than a first threshold.4. The temperature measurement device as claimed in ...

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Номер записи: 59
01-03-2018 дата публикации

TEMPERATURE MEASUREMENT DEVICE, TEMPERATURE MEASUREMENT METHOD, AND COMPUTER-READABLE NON-TRANSITORY MEDIUM

Номер: US20180058948A1
Автор: Arioka Takahiro, FUKUDA Hiroyuki, Kasajima Takeo, Uno Kazushi
Принадлежит: FUJITSU LIMITED

A temperature measurement device includes: a detector to detect a first Stokes component and a first anti-Stokes component when a light is input into a first end of an optical fiber and detect a second Stokes component and a second anti-Stokes component when a light is input into a second end; and a processor configured to execute a process comprising: replacing the second anti-Stokes component with a value according to the first Stokes component, the first anti-Stokes component and the second Stokes component when any one of correlations of the second anti-Stokes component to the first Stokes component and the first anti-Stokes component is less than or equal to a threshold value; and measuring a temperature at the sample point by using the first Stokes component, the first anti-Stokes component, the second Stokes component, and the second anti-Stokes component that is replaced in the replacing. 1. A temperature measurement device comprising:a detector configured to detect a first Stokes component and a first anti-Stokes component from a back scattering light generated when a light is input into a first end of an optical fiber and detect a second Stokes component and a second anti-Stokes component from a back scattering light generated when a light is input into a second end of the optical fiber;a memory; anda processor configured to execute a process, the process comprising:within a predetermined region including a sample point of a partial region on the first end side of the optical fiber, replacing the second anti-Stokes component with a value according to the first Stokes component, the first anti-Stokes component and the second Stokes component when any one of correlations of the second anti-Stokes component to the first Stokes component and the first anti-Stokes component is less than or equal to a threshold value; andmeasuring a temperature at the sample point by using the first Stokes component, the first anti-Stokes component, the second Stokes component, ...

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Номер записи: 60
01-03-2018 дата публикации

TEMPERATURE PROBE

Номер: US20180058951A1
Автор: Clark Mark, Rinn Joerg, Zinn Hanspeter
Принадлежит: ANSALDO ENERGIA SWITZERLAND AG

A temperature probe and method for determining a temperature in a gas flow are disclosed. The probe includes a probe body. A free flow temperature sensor a free flow temperature of the gas flow and a total temperature sensor measures a total temperature of the gas flow. The method includes measuring a flow temperature in a free gas flow, providing a static gas volume in which essentially all kinetic energy of the flowing gas is recovered and converted into thermal energy, and measuring a total temperature in the static gas volume. An accurate determination of the total temperature of a gas flow, which is representative of a specific total enthalpy, can thereby be achieved while detecting fast and transient temperature changes. 1. A temperature probe for determining a temperature in a gas flow , the probe comprising:a probe body;and at least two temperature sensors wherein a first temperature sensor is provided as a free flow temperature sensor to measure a free flow temperature of a gas flow and a second temperature sensor is provided as a total temperature sensor to measure a total temperature of a gas flow.2. The probe according to claim 1 , wherein the free flow temperature sensor is located distant from the probe body.3. The probe according to claim 1 , wherein the probe body is shaped to provide a flow stagnation area claim 1 , the flow stagnation area being provided and configured to convert essentially all kinetic energy of an incoming flow into thermal energy claim 1 , wherein the total temperature sensor is located in a gas volume in said stagnation area.4. The probe according to claim 3 , wherein the stagnation area is provided as a stagnation cavity in the probe body claim 3 , the stagnation cavity being provided as a blind cavity and the stagnation cavity opening out to an exterior of the probe body with a flow receiving opening claim 3 , the flow receiving opening being provided at one end of the stagnation cavity and a blind end being provided on an ...

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Номер записи: 61
02-03-2017 дата публикации

Device and method for spatially resolved measurement of temperature and/or strain by Brillouin scattering

Номер: US20170059427A1
Автор: Bunse Roland, Penno Stefan
Принадлежит:

Device for spatially resolved measurement of temperature and/or strain by Brillouin scattering, with a laser light source () for generating a laser radiation, an optical fiber () used for the measurement, into which the laser radiation can be coupled in and from which Brillouin signals generated by Brillouin scattering can be coupled out, sensors for detecting the coupled-out Brillouin signals, evaluators for determining spatially resolved from the detected Brillouin signals the temperature and/or strain of sections of the optical fiber (), a polarization beam splitter () capable of splitting the coupled-out Brillouin—signals into two components () having mutually different polarizations, and an optical coupler () for admixing a laser radiation to the Brillouin signal. 1. A device for spatially resolved measurement of temperature and/or strain by Brillouin scattering , comprising{'b': '1', 'at least one laser light source () configured to produce laser radiation,'}{'b': '5', 'an optical fiber () used for the measurement, into which the laser radiation can be coupled in and from which the Brillouin signals generated based on the Brillouin scattering can coupled out,'}sensors configured to capture the coupled-out Brillouin signals,{'b': '5', 'evaluator configured to determine spatially resolved from the captured Brillouin signals the temperature and/or strain at least of sections of the optical fiber (),'}{'b': 10', '11', '12', '13, 'at least one optical polarization beam splitter (, ) configured to split the coupled-out Brillouin signals into two components (, ) with mutually different polarizations,'}{'b': 16', '17, 'at least one optical coupler (, ) configured to admix to the Brillouin signal a laser radiation.'}21213. The device according to claim 1 , wherein the sensors can detect the components ( claim 1 , ) separate from each other.3161712131011. The device according to claim 1 , wherein the device comprises two optical couplers ( claim 1 , ) claim 1 , each ...

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Номер записи: 62
02-03-2017 дата публикации

Device and Method for Spatially Resolved Measurement of Temperature and/or Strain by Brillouin Scattering

Номер: US20170059428A1
Автор: Alexander Rath, Benjamin MARX, Wieland Hill
Принадлежит: LIOS TECHNOLOGY GMBH

Device for spatially resolved measurement of temperature and/or strain by Brillouin scattering, with a laser light source ( 1 ) for generating a laser radiation, an optical fiber ( 5 ) used for the measurement, into which the laser radiation can be coupled in and from which Brillouin signals generated by Brillouin scattering can be coupled out, sensors for detecting the coupled-out Brillouin signals, evaluators for determining spatially resolved from the detected Brillouin signals the temperature and/or strain of sections of the optical fiber ( 5 ), a polarization beam splitter ( 10, 11 ) capable of splitting the coupled-out Brillouin-signals into two components ( 12, 13 ) having mutually different polarizations, and an optical coupler ( 16, 17 ) for admixing a laser radiation to the Brillouin signal.

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Номер записи: 63
04-03-2021 дата публикации

MONITORING HUMIDITY MEASUREMENT SYSTEM AND MONITORING HUMIDITY MEASUREMENT METHOD

Номер: US20210063209A1
Автор: KISHIDA Kinzo, NAKAMICHI Masanori, NAKAO Kazushige
Принадлежит: NEUBREX CO., LTD.

A monitoring humidity measurement system includes: a humidity measurement optical fiber including a first optical fiber and a humidity detection layer provided so as to annularly cover the first optical fiber; a reference optical fiber including a second optical fiber; a plurality of optical communication cables; and a signal processing device configured to, with a laser beam entering into the first and second optical fibers, calculate and obtain Brillouin frequency shift and Rayleigh frequency shift of backscatter light from the first and second optical fibers based on the entering laser beam, and store predetermined constants, wherein reference data and target data are measured from the Rayleigh frequency shift and an initial humidity value calculated from the Brillouin frequency shift, and the value of humidity at the present time is calculated on the basis of Rayleigh frequency shift per unit humidity calculated from a difference between the above two data. 1. A monitoring humidity measurement system comprising:a humidity measurement optical fiber including a first optical fiber and a humidity detection layer provided so as to cover the first optical fiber;a reference optical fiber for measuring an environmental variable other than humidity, the reference optical fiber including a second optical fiber and arranged along with the humidity measurement optical fiber; andan optical signal processing device having a laser light source and a plurality of signal channels individually connected to the humidity measurement optical fiber and the reference optical fiber, the optical signal processing device being configured to calculate and obtain Brillouin frequency shift and Rayleigh frequency shift from backscatter light of a laser beam entering from the laser light source into each optical fiber, and store a proportionality constant representing a relationship between the Brillouin frequency shift and humidity, and a change coefficient which is a change amount of the ...

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Номер записи: 64
28-02-2019 дата публикации

OPTICAL FIBER SENSOR MEASURING APPARATUS

Номер: US20190064446A1
Автор: Tezuka Shin-ichirou
Принадлежит: YOKOGAWA ELECTRIC CORPORATION

An optical fiber sensor measuring apparatus includes a base portion, and a measuring optical fiber laid in the base portion. Adjacent linear portions of the measuring optical fiber are in contact with each other. The base portion may be plate-like. The measuring optical fiber may have the linear portion and a folded portion. 1. An optical fiber sensor measuring apparatus comprising:a base; anda measuring optical fiber laid in the base, whereinadjacent linear portions of the measuring optical fiber contact each other.2. The optical fiber sensor measuring apparatus according to claim 1 , whereinthe base has a plate-like shape, andthe measuring optical fiber comprises a folded portion.3. The optical fiber sensor measuring apparatus according to claim 2 , whereinthe linear portions include a first linear portion extending in a first direction and a second linear portion extending in a second direction perpendicular to the first direction.4. The optical fiber sensor measuring apparatus according to claim 1 , whereinthe base has a three-dimensional shape having an outer peripheral surface, andthe measuring optical fiber is wound along the outer peripheral surface.5. The optical fiber sensor measuring apparatus according to claim 1 , whereinthe base comprises a plurality of tubes, andthe measuring optical fiber is passed through the tubes.6. The optical fiber sensor measuring apparatus according to claim 1 , whereinthe base comprises a plurality of grooves, andthe measuring optical fiber is fitted in the grooves.7. The optical fiber sensor measuring apparatus according to claim 1 , whereinthe measuring optical fiber is disposed on the base and the linear portions extending in the same direction are stacked.8. The optical fiber sensor measuring apparatus according to claim 2 , whereinthe measuring optical fiber is disposed on the base and the linear portions extending in the same direction are stacked.9. The optical fiber sensor measuring apparatus according to claim 3 , ...

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Номер записи: 65
10-03-2016 дата публикации

Method of Predicting an Ambient Temperature around a Mobile Device, Computer Program Product and Mobile Device

Номер: US20160069753A1
Автор: Ng Pei Sin, Phan Le Kim
Принадлежит:

There is disclosed a method of predicting an ambient temperature around a mobile device, wherein: a primary temperature sensor comprised in said mobile device measures a first temperature value; at least one secondary temperature sensor comprised in said mobile device measures a second temperature value; a processing unit comprised in said mobile device calculates a first prediction of an ambient temperature around the mobile device in dependence on the first temperature value and at least one parameter which is indicative of a thermal influence of one or more mobile device components on the measurements; the processing unit calculates a second prediction of said ambient temperature in dependence on the second temperature value and said parameter; the processing unit compares the first prediction with the second prediction and adjusts said parameter if the difference between the first prediction and the second prediction exceeds a predefined maximum. Furthermore, a corresponding computer program product and a corresponding mobile device are disclosed. 1. A method of predicting an ambient temperature around a mobile device , wherein:a primary temperature sensor comprised in said mobile device measures a first temperature value;at least one secondary temperature sensor comprised in said mobile device measures a second temperature value;a processing unit comprised in said mobile device calculates a first prediction of an ambient temperature around the mobile device in dependence on the first temperature value and at least one parameter which is indicative of a thermal influence of one or more mobile device components on the measurements;the processing unit calculates a second prediction of said ambient temperature in dependence on the second temperature value and said parameter;the processing unit compares the first prediction with the second prediction and adjusts said parameter if the difference between the first prediction and the second prediction exceeds a ...

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Номер записи: 66
27-02-2020 дата публикации

SYSTEMS AND METHODS FOR A REVERSE THERMOSTAT

Номер: US20200063982A1
Автор: Pepper Douglas
Принадлежит:

Various embodiments of a reverse thermostat for use in restricting hot water in a plumbing system from being delivered to cold water fixtures are disclosed. 1. A reverse thermostat apparatus for use in a plumbing system , comprising:a gate seat interposed between a reservoir support housing and a gate rod support housing, wherein the reservoir support housing is coupled to the gate rod support housing;a gate rod that extends through the gate seat and extends outwardly from gate rod support housing, the gate rod being coupled to a flow control gate for controlling the flow of water through the reverse thermostat;a reservoir engaged to the reservoir support housing and in fluid flow communication with a reservoir cylinder; anda heat sensitive expansion element disposed within the reservoir, wherein the heat sensitive expansion element expands at a temperature above a predetermined temperature such that the heat sensitive expansion element transforms from a solid state to a liquid state such that the heat sensitive expansion element expands and flows through the reservoir cylinder to control the position of the flow control gate, and wherein the heat sensitive expansion element contracts at a temperature below the predetermined temperature thereby driving the flow control gate into an open position;wherein water from a hot water supply line flows into the reverse thermostat apparatus from a proximal end and wherein water flows out of a distal end of the reverse thermostat apparatus when the flow control gate is in the open position.2. The reverse thermostat apparatus of claim 1 , wherein the expansion of the heat-sensitive expansion element is operable to drive the flow control gate into a closed position claim 1 , wherein the flow control gate is disposed into the gate seat which creates a seal between the flow control gate and the gate seat claim 1 , and wherein the contraction of the heat-sensitive expansion element causes the heat-sensitive expansion element to ...

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Номер записи: 67
17-03-2016 дата публикации

Foam Dispensing Gun

Номер: US20160074886A1
Автор: Brian Milliff, Christopher MIEDZA, Douglas CAFFOE, John Mcquaid, Kerry ARMES, Michael J. Maczuzak, Sara JONAS, Scott E. MIZER, Stefan Gantenbein, Thomas Fishback, Timothy SHOEMAKER
Принадлежит: Fomo Products Inc

A foam spray gun is illustrated in which a third hose is attached to the gun for the application of either a liquid or a gas.

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Номер записи: 68
15-03-2018 дата публикации

APPARATUS FOR INTERROGATING DISTRIBUTED OPTICAL FIBRE SENSORS USING A STIMULATED BRILLOUIN SCATTERING OPTICAL FREQUENCY-DOMAIN INTERFEROMETER

Номер: US20180073900A1
Автор: BASTIANINI Filippo
Принадлежит:

Apparatus for producing and sourcing two lightwaves having a wavelength-shift known and controllable and suitable to be used as “pump” and “probe” in a stimulated Brillouin analyser in which part of the radiation of frequency ffrom a primary source () is first shifted of a frequency Δftypically from 200 to 1000 MHz lower than the Brillouin shift Δfin the sensor, by a first frequency conversion system comprising a Brillouin ring laser () and then is shifted of a frequency Δfin order to fall inside the Brillouin gain band of the sensor through a further tuneable frequency conversion system () in which at least one electro-optical modulator generates modulation side bands () of frequency (f−Δf+Δf) and (f<Δf−Δf), only one of which can fall within a Brillouin gain band of the sensor. The apparatus possibly comprises also a feedback stabilization system that acts on Δfdepending on changes in the value of Δfin order to stabilise at least one between |Δf+Δf| and |Δf−Δf|. The apparatus solves the following problems of known solutions: wavelength-shift stability and accuracy, wavelength agility, width of the wavelength-shift tuning range, power consumption, tuning speed and industrial cost. 1. An apparatus for producing and sourcing , through multiple frequency conversions , at least two optical radiations suitable to be used in a Brillouin analyser , characterized by the facts of comprising:{'b': '70', 'at least one source () of primary radiation with frequency f0 and linewidth not greater than the Brillouin gain bandwidth GBWB,BGM in a Brillouin gain medium and possibly than that GBWB,SNS in a sensing medium; and'}{'b': 72', '102', '74', '105', '70, 'claim-text': 'fB,SNS characteristic of the sensor at least twice the width of the Brillouin gain bandwidth GBWB,SNS of the sensor; and', 'at least one first stimulated Brillouin frequency conversion system (,) using a special Brillouin Gain Medium BGM (, ) characterized by doping in Germanium and/or other substances and/or a ...

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Номер записи: 69
15-03-2018 дата публикации

TEMPERATURE OR STRAIN DISTRIBUTION SENSOR

Номер: US20180073959A1
Автор: LECOEUCHE Vincent
Принадлежит: VIAVI SOLUTIONS INC.

According to examples, a temperature or strain distribution sensor may include a photodiode to acquire a beat frequency between a first laser beam and a second laser beam. A modulator may modulate the first laser beam that is to be injected into a device under test (DUT). A coherent receiver may acquire a backscattered signal from the DUT, and use the second laser beam as a local oscillator to determine a Brillouin trace with respect to the DUT. The Brillouin trace may be used to determine a Brillouin frequency shift and a Brillouin power for the DUT to implement an absolute referencing of a Rayleigh reference trace. The coherent receiver may determine, relative to the Rayleigh reference trace, a further Brillouin frequency shift and a Rayleigh frequency shift to determine a temperature or a strain associated with the DUT. 1. A temperature or strain distribution sensor comprising:a first laser source to emit a first laser beam;a second laser source to emit a second laser beam; a predetermined offset frequency shift between the first laser beam and the second laser beam, wherein the predetermined offset frequency shift is relative to a predetermined frequency of either the first laser beam or the second laser beam, or', 'a constant optical frequency for the first laser beam and the second laser beam;, 'a photodiode to acquire a beat frequency between the first laser beam and the second laser beam, wherein the beat frequency is used to maintain'}a modulator to modulate the first laser beam, wherein the modulated first laser beam is to be injected into a device under test (DUT); and the coherent receiver is to use the second laser beam as a local oscillator to determine a Brillouin trace with respect to the DUT based on the predetermined offset frequency shift between the first laser beam and the second laser beam, wherein the Brillouin trace is used to determine a Brillouin frequency shift and a Brillouin power for the DUT to implement an absolute referencing of a ...

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Номер записи: 70
07-03-2019 дата публикации

MEASUREMENT SYSTEM AND TEMPERATURE AND/OR SHAPE CHANGE SENSOR USING BRILLOUIN BACK-REFLECTION ANALYSIS

Номер: US20190072417A1
Автор: KHADOUR Aghiad, OUDAR Jean-Louis
Принадлежит:

A measurement system for performing measurement by Brillouin scattering analysis, the system comprising a laser emitter device () configured to emit an incident wave (ν) and a reference wave (ν−νB), the incident wave presenting an incident frequency (ν) and the reference wave presenting a reference frequency (ν−νB), the reference frequency (ν−νB) being shifted from the incident frequency (ν) by a predetermined value (νB). The system is configured to: 1. A measurement system for performing measurement by Brillouin scattering analysis , the system comprising a laser emitter device configured to emit an incident wave and a reference wave , the incident wave presenting an incident frequency and the reference wave presenting a reference frequency , the reference frequency being shifted from the incident frequency by a predetermined value , the system being configured , when it is connected to at least a first end of an optical fiber:to project the incident wave into said first end of the fiber;to receive in return a backscattered wave at the first end of the fiber;to generate a composite wave combining at least the backscattered wave and the reference wave; andto determine at least one property relating to the fiber by analyzing a Brillouin spectrum of the composite wave;the system further including a dual-frequency vertical-cavity surface-emitting laser source forming part of the laser emitter device and configured to emit the incident wave and the reference wave.2. A measurement system according to claim 1 , wherein the wavelength of the incident wave lies in the range 1.3 μm to 1.8 μm.3. A measurement system according to claim 1 , including an optical detector arranged on the path of the composite wave so as to collect the composite wave claim 1 , and a frequency analyzer configured to analyze the Brillouin spectrum of the composite wave so as to determine said at least one property relating to the fiber.4. A measurement system according to claim 1 , including a first ...

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Номер записи: 71
07-03-2019 дата публикации

MEASURING DEVICE, COMBUSTIBLE GAS SUPPLY DEVICE WITH SAID TYPE OF MEASURING DEVICE AND INTERNAL COMBUSTION ENGINE WITH SAID TYPE OF COMBUSTIBLE GAS SUPPLY DEVICE

Номер: US20190072418A1
Автор: Kläser-Jenewein Ludwig, MEYER ULRICH
Принадлежит:

A measuring device for measuring a physical property of a fluid, including a base body which is closed along a peripheral line. The base body surrounds a first recess passing through the base body in the axial direction and the base body includes at least one second recess passing through the base body in the axial direction recess. At least one sensor device, which can be associated with the base body, can be bought into contact with the first recess. 110.-. (canceled)11. A measuring device for measuring a physical property of a fluid , comprising:a main body that is closed along a peripheral line and which surrounds a first aperture that passes through the main body in an axial direction, wherein the main body has at least one second aperture that passes through the main body in the axial direction; andat least one sensor device, which can be brought into operative connection with the first aperture, is assigned to the main body,12. The measuring device according to claim 11 , wherein the main body has a plurality of second apertures.13. The measuring device according to claim 12 , wherein the plurality of second apertures is arranged around the first aperture.14. The measuring device according to claim 11 , wherein the main body has two ends claim 11 , namely a first end and a second end claim 11 , which when viewed in the axial direction faces away from the first end claim 11 , wherein the first aperture and the at least one second aperture open into the first and second ends claim 11 , whereina) a first sealing device is arranged on at least one of the two ends between the first aperture and the at least one second aperture when viewed in a radial direction, and/or whereinb) the main body has at least two second apertures, wherein a first fluid connection between the at least two second apertures is formed at at least one of the two ends, and/or whereinc) a second sealing device is arranged radially outside the at least one second aperture at at least one of ...

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Номер записи: 72
07-03-2019 дата публикации

Distributed Sensing of Electromagnetic Components Using Optical Fiber Based Methods

Номер: US20190072437A1
Автор: Beddingfield Richard, Buric Michael, Leary Alex, McHenry Michael, Ohodnicki Paul
Принадлежит:

An OFDR based fiber-optics sensor for distributed real-time temperature rise monitoring of a transformer in operation has been disclosed. The fiber-optic sensor provides an effective solution to monitoring the physical structures of the transformer core, as well as accurately detecting the non-uniform temperature distribution inside the transformer, and thus provides innovative feedback to the transformer design by minimizing the core losses. Additionally, the method may be responsive to the presence of magnetic and electric fields, as well as responsive to various chemical species. The method allows novel approaches to real-time asset monitoring of power transformers while operational. 1. A method of temperature measurement comprising:instrumenting one or more portions of an electromagnetic component by placing an optical fiber in thermal contact with the one or more portions;interrogating the optical fiber sensor, when the magnetic component is energized, using optical backscattering interferometry; andcreate, based on the interrogation, a continuous spatially resolved distribution of internal temperatures of the magnetic component.2. The method of further comprising mapping a 2d or 3d temperature profile of the magnetic component.3. The method of wherein the continuous spatially resolved distribution of internal temperatures is based on Rayleigh scattering observed in the optical fiber.4. The method of wherein thermal contact between the optical fiber and the magnetic component is maintained using a thermal paste.5. The method of wherein the continuous spatially resolved distribution of internal temperatures is based on Raman scattering observed in the optical fiber.6. The method of wherein the magnetic component is a transformer and further wherein the instrumentation comprises placing the optical fiber along the outer and inner diameters of a core of the transformer.7. The method of wherein the instrumentation further comprises placing the optical fiber between ...

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Номер записи: 73
24-03-2022 дата публикации

TWO AND THREE-DIMENSIONAL MODEL BASED CORRECTION OF ELBOW TAP FLOW MEASUREMENT

Номер: US20220090948A1
Автор: LOJEK John, SWARTZ Matthew M.
Принадлежит: WESTINGHOUSE ELECTRIC COMPANY LLC

A system for determining coolant flow rate in a nuclear reactor primary cooling loop includes a processor and a memory. The memory stores physical measurements of the mechanical components comprising the primary cooling loop. The memory also stores instructions that cause the processor to: receive pressure data from a plurality of pressure sensors in the cooling loop; calculate a model of fluid flow through the primary cooling loop based on the mechanical component measurements; compare the data from the pressure sensors with estimated data from the fluid flow model; and calculate a statistical weighting of the pressure data from the pressure sensors based on the estimated pressure data from the fluid flow model. In another system, the flow rate is determined from a combination of the estimate from the modeled fluid flow with an estimate based on a calorimetric thermal exchange calculation. 1. A system for determining a coolant fluid flow rate in a primary cooling loop of a nuclear reactor , the system comprising:a processor unit; and wherein the memory component is configured to store primary cooling loop physical data defining one or more measurements of mechanical components of at least a portion of the primary cooling loop, and', receive pressure data from a plurality of differential pressure sensors disposed within the primary cooling loop;', 'calculate a model of a fluid flow through the mechanical components of the at least portion of the primary cooling loop based at least in part on the primary cooling loop physical data;', 'compare the pressure data from the plurality of differential pressure sensors with estimated pressure data derived from the model of the fluid flow rate through the mechanical components of the at least portion of the primary cooling loop; and', 'calculate a statistical weighting of the pressure data from the plurality of differential pressure sensors based on the estimated pressure data derived from the model of the fluid flow rate., ' ...

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Номер записи: 74
18-03-2021 дата публикации

BRILLOUIN AND RAYLEIGH DISTRIBUTED SENSOR

Номер: US20210080350A1
Автор: LECOEUCHE Vincent
Принадлежит: VIAVI SOLUTIONS INC.

According to examples, a Brillouin and Rayleigh distributed sensor may include a first laser source to emit a first laser beam, and a second laser source to emit a second laser beam. A photodiode may acquire a beat frequency between the two laser beams. The beat frequency may be used to maintain a predetermined offset frequency shift between the two laser beams. A modulator may modulate the first laser beam. The modulated first laser beam is to be injected into a device under test (DUT). A coherent receiver may acquire a backscattered signal from the DUT. The backscattered signal results from the modulated first laser beam injected into the DUT. The coherent receiver may use the second laser beam as a local oscillator to determine Brillouin and Rayleigh traces with respect to the DUT based on the predetermined offset frequency shift. 1. A Brillouin and Rayleigh distributed sensor comprising:a first laser source to emit a first laser beam;a second laser source to emit a second laser beam;a photodiode to acquire a beat frequency between the first laser beam and the second laser beam, wherein the beat frequency is used to maintain a predetermined offset frequency shift between the first laser beam and the second laser beam, wherein the predetermined offset frequency shift is relative to a predetermined frequency of either the first laser beam or the second laser beam;a modulator to modulate the first laser beam, wherein the modulated first laser beam is to be injected into a device under test (DUT); anda coherent receiver to acquire a backscattered signal from the DUT, wherein the backscattered signal results from the modulated first laser beam injected into the DUT, and wherein the coherent receiver is to use the second laser beam as a local oscillator to determine Brillouin and Rayleigh traces with respect to the DUT based on the predetermined offset frequency shift between the first laser beam and the second laser beam.2. The Brillouin and Rayleigh distributed ...

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Номер записи: 75
22-03-2018 дата публикации

GAS ANALYSIS SYSTEM AND BOILER

Номер: US20180080869A1
Автор: Kawazoe Kohei, Muta Kenji, NISHIMIYA Tatsuyuki, OKA Hirotaka
Принадлежит:

A gas analysis system includes: a laser light source for emitting a laser light to be transmitted through an analysis target gas; a photodetector configured to receive the laser light transmitted through the analysis target gas, for outputting a signal corresponding to an emission intensity of the received laser light; a gas analysis apparatus for analyzing the analysis target gas on the basis of the signal outputted from the photodetector; a variable light attenuator disposed between the analysis target gas and the laser light source; a transmitted-light amount detector configured to evaluate a transmitted light amount of the laser light transmitted through the analysis target gas on the basis of the signal outputted from the photodetector; and an attenuation amount controller configured to control an attenuation amount of the variable light attenuator on the basis of the transmitted light amount of the laser light evaluated by the transmitted-light amount detector. 114-. (canceled)15. A gas analysis system , comprising:a laser light source for emitting a laser light to be transmitted through an analysis target gas;a photodetector configured to receive the laser light transmitted through the analysis target gas, for outputting a signal corresponding to an emission intensity of the received laser light;a gas analysis apparatus for analyzing the analysis target gas on the basis of the signal outputted from the photodetector;a variable light attenuator disposed between the analysis target gas and the laser light source;a transmitted-light amount detector configured to evaluate a transmitted light amount of the laser light transmitted through the analysis target gas on the basis of the signal outputted from the photodetector;an attenuation amount controller configured to control an attenuation amount of the variable light attenuator on the basis of the transmitted light amount of the laser light evaluated by the transmitted-light amount detector;a vessel housing the ...

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Номер записи: 76
23-03-2017 дата публикации

TEST EQUIPMENT ARRANGEMENT HAVING A SUPERHEAT CONTROLLER

Номер: US20170082336A1
Автор: "OKeefe Jennifer", Chung Buu, Rao Arvind, Yang Chen
Принадлежит: DUNAN MICROSTAQ, INC.

A test equipment arrangement includes a superheat controller configured for connection to a unit under test, and further configured to test at least one operational parameter of the unit under test. 1. A test equipment arrangement comprising a superheat controller configured for connection to a unit under test , and configured to test at least one operational parameter of the unit under test.2. The end of line test equipment arrangement according to claim 1 , wherein the unit under test is a modular silicon expansion valve.3. The end of line test equipment arrangement according to claim 1 , wherein the unit under test is one of a modular silicon expansion valve claim 1 , a microvalve enabled device claim 1 , a microvalve claim 1 , an electronic fluid valve claim 1 , a pressure sensor claim 1 , and a flow sensor.4. The end of line test equipment arrangement according to claim 1 , further including at least one test component configured to test at least one operational parameter of the unit under test.5. The end of line test equipment arrangement according to claim 4 , wherein the at least one test component is one or more of a multimeter claim 4 , a thermistor claim 4 , a pressure transducer claim 4 , a pulse width modulation driver claim 4 , a pressure regulator claim 4 , and a pressure reducer claim 4 , each test component configured to test at least one operational parameter of the unit under test.6. The end of line test equipment arrangement according to claim 1 , further including a computer connected to the superheat controller and the unit under test.7. The end of line test equipment arrangement according to claim 6 , further including a data acquisition device connected to the superheat controller and the unit under test.8. The end of line test equipment arrangement according to claim 1 , wherein the superheat controller includes a processer configured to perform the function of a multimeter.9. The end of line test equipment arrangement according to claim 8 , ...

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Номер записи: 77
02-04-2015 дата публикации

METHOD FOR DETERMINING THE TEMPERATURE INSIDE A COMBUSTOR

Номер: US20150089950A1
Автор: Schuermans Bruno, WASSMER Dominik
Принадлежит:

A method for determining the temperature of an aggressive and/or abrasive gas is described using an acoustic transmitter and an acoustic receiver. The transmitter emits an acoustic signal with varying frequencies and the receiver extracts from the acoustic input signal a frequency of the maximum. Based on this the frequency of this maximum the temperature of the gas between transmitter and receiver is calculated. 1. A method for determining the combustion temperature in a combustor by acoustic measurements having an active acoustic source and a receiver for receiving the output of the acoustic source , said method comprising:emitting an acoustic signal from the acoustic source, the acoustic signal having a frequency which is within a frequency band that comprises one resonance frequency of the gas in the combustor,{'sub': gas', 'res, 'receiving the acoustic signal from the acoustic source by means of the receiver, and determining the actual temperature (T(t)) of said gas based on the actual resonance frequency (f(t)) of said gas, wherein said acoustic source and said receiver are installed at the walls of the combustor and the combustor itself is used as resonance cavity.'}2. A method according to claim 1 , wherein the frequency band covers a range of +−10% of the resonance frequency (f) at normal operation of the combustor.3. A method according to claim 1 , wherein frequency of the acoustic signal sweeps within the frequency band.5. The method according to claim 1 , wherein the active acoustic source and the receiver are installed at the same wall of the combustor.6. The method according to claim 4 , wherein the active acoustic source and the receiver are part of a transceiver.7. The method according to claim 1 , wherein the active acoustic source and the receiver are installed at opposite walls of the combustor.8. The method according to claim 1 , wherein it is applied for determining the combustion temperature in a combustor of a gas turbine claim 1 , a boiler of ...

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Номер записи: 78
29-03-2018 дата публикации

TRACK ASSEMBLY FOR TRACKED VEHICLE

Номер: US20180086398A1
Автор: Yoon Sung Soo, YOON Woo Seok
Принадлежит: JINSUNG INDUSTRY CO., LTD.

The present invention relates to a track assembly for a tracked vehicle, which, particularly, comprises: a support shaft disposed to be orthogonal to a traveling direction of a work body; a connecting collar for connecting the support shaft to the work body while supporting both ends of the support shaft; a rotary roller fitted on the outer periphery of the support shaft and rotating while supporting the inner peripheral surface of a track; a first detection unit disposed between the support shaft and the rotary roller to measure the number of rotations of the rotary roller or the acceleration thereof; a second detection unit for measuring the temperature of a lubricant applied between the support shaft and the rotary roller; a third detection unit disposed on the rotary roller to measure a wear state of the rotary roller; and a communication unit for communicating, to the outside, a result value measured by the first detection unit or the third detection unit. Therefore, the track assembly can improve the efficiency and reliability of work. 1. A track assembly for a tracked vehicle , comprising:a support shaft disposed to be orthogonal to a traveling direction of a work body;a rotary roller fitted on the outer periphery of the support shaft and rotating while supporting the inner side of a chain belt;a first detection unit disposed between the support shaft and the rotary roller to measure either the number of rotations of the rotary roller or the acceleration thereof;a second detection unit for measuring the temperature of a lubricant applied between the support shaft and the rotary roller; anda third detection unit disposed on the rotary roller to measure a wear state of the rotary roller.2. The track assembly of claim 1 , further comprising a communication unit for communicating claim 1 , to the outside claim 1 , result values measured by the first to third detection units.3. The track assembly of claim 1 , wherein the first detection unit comprises:a magnet ...

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Номер записи: 79
25-03-2021 дата публикации

LOW-PRESSURE SENSOR DEVICE AND USE OF AN INLET CONNECTOR PIECE AS A FLUID INLET FOR A LOW-PRESSURE SENSOR DEVICE

Номер: US20210088401A1
Автор: HABIBI Masoud, HAUER Christian, Janitza Thorsten-Kai, MAIS Torsten
Принадлежит:

A low-pressure sensor device for measuring a charge pressure of an engine in a vehicle is described. The low-pressure sensor device has a pressure sensor for measuring the pressure of a fluid in the low-pressure sensor device, and a temperature sensor for measuring the temperature of the fluid in the low-pressure sensor device, the low-pressure sensor device having an in particular essentially cylindrical inlet connector piece for admitting the fluid into the low-pressure sensor device, the inlet connector piece having an in particular circular inlet opening on a side facing away from the pressure sensor. 110-. (canceled)11. A low-pressure sensor device for measuring a charge pressure of a motor in a vehicle , the low-pressure sensor device comprising:a pressure sensor configured to measure a pressure of a fluid in the low-pressure sensor device;a temperature sensor configured to measure a temperature of the fluid in the low-pressure sensor device; anda cylindrical inlet connector piece configured to admit the fluid into the low-pressure sensor device, the inlet connector piece having a circular inlet opening on a side facing away from the pressure sensor, the inlet connector piece having a sieve-type wall structure which includes a multitude of recesses in a subregion facing the inlet opening.12. The low-pressure sensor device as recited in claim 11 , wherein the temperature sensor is at least partially situated at a level of the sieve-type wall structure of the inlet connector piece.13. The low-pressure sensor device as recited in claim 11 , wherein the inlet connector piece has a completely closed wall structure in a subregion facing away from the inlet opening.14. The low-pressure sensor device as recited in claim 11 , wherein the inlet connector piece has a circumferential drip-off edge at an end facing the inlet opening.15. The low-pressure sensor device as recited in claim 11 , wherein the inlet connector piece is injection-molded in one piece.16. The low- ...

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Номер записи: 80
21-03-2019 дата публикации

METHOD AND APPARATUS FOR IDENTIFYING ERRONEOUS DISCHARGE AIR TEMPERATURE (DAT) SENSOR INSTALLATION

Номер: US20190086276A1
Автор: Delgoshaei Payam, Kowald Glenn W., Oernbo Lars Noergaard, Venkatesh Sridhar
Принадлежит: Lennox Industries Inc.

A method of monitoring a HVAC system to detect erroneous sensor installation. The method includes determining whether a circulation fan has been operational for a first predetermined time interval. If the circulation fan has been operational for the first predetermined time interval, determining whether a cooling demand is present. If the cooling demand is present, determining whether the HVAC system has been conditioning air for the first predetermined time interval responsive to the cooling demand. If the HVAC system has been conditioning the air for the first predetermined time interval, determining whether a difference between an indoor air temperature value corresponding to an enclosed space and an air temperature value from a discharge air temperature (DAT) sensor is greater than a predetermined temperature value. If the difference is not greater than the predetermined temperature value, forwarding a message indicating that the DAT sensor positioned within a duct of the HVAC system is improperly installed. 1. A method of monitoring a heating , ventilation , and air conditioning (HVAC) system to detect erroneous sensor installation , the method comprising:monitoring, by a controller, operation of the HVAC system;determining, by the controller, whether a circulation fan has been operational for a first predetermined time interval;responsive to a determination that the circulation fan has been operational for the first predetermined time interval, determining, by the controller, whether a cooling demand is present;responsive to a determination that the cooling demand is present, determining, by the controller, whether the HVAC system has been conditioning air for the first predetermined time interval responsive to the cooling demand;responsive to a determination that the HVAC system has been conditioning the air for the first predetermined time interval, determining, by the controller, whether a difference between an indoor air temperature value corresponding to ...

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Номер записи: 81
31-03-2016 дата публикации

Sound and Temperature Sensors for Environmental Anomaly Detection

Номер: US20160093187A1
Автор: Huang Yanyuan, Wu Zhanmin, Yan Xiang, Yuan Qin, ZHANG Guohua, ZHANG Junmin, ZHAO Hongjuan
Принадлежит:

The sound wave and temperature sensor of the present disclosure can be used for detecting whether a fire accident occurs within a specific area without risking altering or damaging existing sensors, and can be a part of an intelligent home security system. One aspect is to provide an integrated sound wave and temperature sensor that can efficiently work together with the existing sensors. An example apparatus can include a sound sensor, a temperature sensor, a communication circuit, and a microcontroller. The microcontroller can be configured to, responsive to the sound sensor detecting an audible alarm emitted from an environmental detector, determine whether an ambient temperature exceeds a threshold value. Further, the microcontroller can, responsive to both the sound sensor detecting the audible alarm and the ambient temperature exceeding a threshold value, cause the communication circuit to transmit an alert to a recipient. 1. An apparatus comprising:a sound sensor;a temperature sensor;a communication circuit; anda microcontroller coupled to the sound sensor, the temperature sensor, and the communication circuit, wherein the microcontroller is configured to:responsive to the sound sensor detecting an audible alarm emitted from an environmental detector that is separate from the apparatus, determine whether an output from the temperature sensor exceeds a threshold value; andresponsive to both the sound sensor detecting the audible alarm and the output from the temperature sensor exceeding a threshold value, cause the communication circuit to transmit an alert to a recipient.2. The apparatus of claim 1 , wherein the microcontroller is further configured to:detect the audible alarm by comparing a frequency of a detected sound with a number of predetermined sound frequencies.3. The apparatus of claim 1 , wherein the microcontroller is further configured to:exit a low power mode upon the audible alarm being detected.4. The apparatus of claim 1 , wherein the ...

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Номер записи: 82
30-03-2017 дата публикации

TWO-CORE OPTICAL FIBERS FOR DISTRIBUTED FIBER SENSORS AND SYSTEMS

Номер: US20170089834A1
Автор: Hoover Brett Jason, Li Ming-Jun, Liu Shenping
Принадлежит:

According to one embodiment two-core optical fiber is provided for use in Brillouin distributed fiber sensor applications and systems. The two-core fiber includes a first and second core. Each core is configured to exhibit a Brillouin frequency shift greater than Mhz relative to the other core. Further, each core possesses temperature and strain coefficients that differ from the other core. The cores can be configured to produce Brillouin frequency shift levels of at least Mhz relative to one another. These differences in shift levels may be affected by adjustment of the material compositions, doping concentrations and/or refractive index profiles of each of the cores. These optical fibers may also be used in BOTDR- and BOTDA-based sensor systems and arrangements. 1. A fiber sensor , comprising:a light source coupled to an optical fiber, the optical fiber comprising a first core, a second core, and a cladding surrounding both of the cores,wherein each core is configured to exhibit a Brillouin frequency shift of at least 30 Mhz relative to the other core.2. The fiber sensor according to claim 1 , further comprising a receiver element configured to measure the Brillouin frequency of the first and second optical cores.3. The fiber sensor according to further including a mirror claim 2 , said mirror coupling light from said one core to the other core.4. The fiber sensor according to claim 1 , wherein each core is configured to exhibit a Brillouin frequency shift of at least 80 Mhz relative to the other core.5. The fiber sensor according to claim 1 , wherein each core is doped with germania and the amount of germania is different in one core relative to the other core.6. The fiber sensor according to claim 5 , wherein each core is further configured with a refractive index profile that differs from the refractive index profile of the other core.7. The fiber sensor according to claim 5 , wherein the cores are configured such that the relative refractive index of the cores ...

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Номер записи: 83
01-04-2021 дата публикации

Ultrasonic flow meter path layout configuration

Номер: US20210096009A1
Автор: Bin Sai, Jie Tong, Wen Peng
Принадлежит: Honeywell International Inc

An ultrasonic flowmeter and a fluid pipeline. The ultrasonic flowmeter includes: a housing, which defines a fluid inlet and a fluid outlet with a fluid passage therebetween; and at least two pairs of ultrasonic sensors, wherein each pair of the at least two pairs of ultrasonic sensors have a first ultrasonic sensor and a second ultrasonic sensor arranged opposite to each other; wherein at least some of the at least two pairs of ultrasonic sensors are arranged in grooves on an inner wall of the fluid passage, and center points of front end faces of at least some of the at least two pairs of ultrasonic sensors are located on a cylindrical curved surface defined by the inner wall of the fluid passage.

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Номер записи: 84
05-04-2018 дата публикации

OPTICAL FIBER STRAIN AND TEMPERATURE MEASUREMENT APPARATUS

Номер: US20180094987A1
Автор: IWAMURA Hideyuki, KOIZUMI Kengo, MURAI Hitoshi
Принадлежит: OKI ELECTRIC INDUSTRY CO., LTD.

By removing remaining components of Rayleigh scattered light, control is sufficiently performed of polarization states even when the wavelength of scattered light has changed. A light source unit configured to generate probe light, a wavelength control unit configured to receive backscattered light emitted from an optical fiber to be tested by the probe light and to output Brillouin backscattered light included in the backscattered light, and a self-delayed heterodyne interferometer to which the Brillouin backscattered light is input are included. The wavelength control unit includes a wavelength separation filter, a variable wavelength filter, an optical intensity measurement unit, and a control unit. The wavelength separation filter has two output ports, outputs and transmits, from one of the two output ports, the Brillouin backscattered light to the variable wavelength filter, and outputs and transmits, from the other output port, Rayleigh scattered light to the optical intensity measurement unit. The optical intensity measurement unit measures a center wavelength and a peak intensity of the Rayleigh scattered light. The control unit controls a cutoff wavelength of the variable wavelength filter in accordance with a direction and amount of change of the center wavelength. 1. An optical fiber strain and temperature measurement apparatus comprising:a light source unit configured to generate probe light;a wavelength control unit configured to receive backscattered light emitted from an optical fiber to be tested by the probe light and to output Brillouin backscattered light included in the backscattered light; anda self-delayed heterodyne interferometer to which the Brillouin backscattered light is input,wherein the wavelength control unit includes a wavelength separation filter, a variable wavelength filter, an optical intensity measurement unit, and a control unit,the wavelength separation filter has two output ports, outputs and transmits, from one of the two ...

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Номер записи: 85
05-04-2018 дата публикации

EXHAUST GAS TEMPERATURE SENSING PROBE ASSEMBLY

Номер: US20180094989A1
Автор: Jackson David Reece
Принадлежит:

A temperature sensing probe assembly includes a temperature sensing probe having a tip and a first thermocouple junction located nearer the tip and a second thermocouple junction located nearer an attachment point for the temperature sensing probe assembly, and a housing positioned around at least a portion of the temperature sensing probe. 1. A temperature sensing probe assembly , comprising:a temperature sensing probe having a tip and a first thermocouple junction located nearer the tip and a second thermocouple junction located nearer an attachment point for the temperature sensing probe assembly; anda housing positioned around at least a portion of the temperature sensing probe and having a lengthened inlet opening on a fore side of the housing and where the lengthened inlet opening extends from at least a portion of the first thermocouple junction to at least a portion of the second thermocouple junction and having a set of exhaust openings located on an aft side of the housing;wherein a stream of air flows through the housing from the lengthened inlet opening to the set of exhaust openings to establish a flow path through the housing and wherein the lengthened inlet opening has a first cross sectional area and the set of exhaust openings have a combined second cross sectional area and where the first cross sectional area and the second cross sectional area are substantially the same.2. The temperature sensing probe assembly of wherein the lengthened inlet opening extends beyond the second thermocouple junction towards the attachment point for the temperature sensing probe assembly.3. The temperature sensing probe assembly of wherein at least one of the set of exhaust openings is located between the second thermocouple junction and the attachment point for the temperature sensing probe assembly.4. The temperature sensing probe assembly of wherein the lengthened inlet opening extends beyond the first thermocouple junction towards the tip.5. The temperature ...

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Номер записи: 86
16-04-2015 дата публикации

ELECTROCHEMICAL SENSING USING VOLTAGE-CURRENT TIME DIFFERENTIAL

Номер: US20150101937A1
Автор: Allmendinger Klaus Karl, Fitzpatrick Joseph Jay, Glass Robert Scott, Henderson Brett Tamatea, Lourdhusamy Anthoniraj, Steppan James John, Wang Gangqiang, Woo Leta Yar-Li
Принадлежит:

A device for signal processing. The device includes a signal generator, a signal detector, and a processor. The signal generator generates an original waveform. The signal detector detects an affected waveform. The processor is coupled to the signal detector. The processor receives the affected waveform from the signal detector. The processor also compares at least one portion of the affected waveform with the original waveform. The processor also determines a difference between the affected waveform and the original waveform. The processor also determines a value corresponding to a unique portion of the determined difference between the original and affected waveforms. The processor also outputs the determined value. 1. A device for signal processing , the device comprising:a signal generator to generate an original waveform;a signal detector configured to detect an affected waveform; and receive the affected waveform from the signal detector;', 'compare at least one portion of the affected waveform with the original waveform;', 'determine a difference between the affected waveform and the original waveform;', 'determine a value corresponding to a unique portion of the determined difference between the original and affected waveforms; and', 'output the determined value., 'a processor coupled to the signal detector, the processor configured to2. The device of claim 1 , wherein the original waveform comprises a non-sinusoidal waveform.3. The device of claim 2 , wherein the original waveform comprises a triangle waveform.4. The device of claim 1 , wherein the at least one portion of the affected and original waveforms comprises a non-zero point on the affected and original waveforms.5. The device of claim 1 , wherein the processor is configured to simultaneously determine at least two values by comparing at least two portions of the original waveform with corresponding portions of the affected waveform.6. The device of claim 5 , wherein the processor is configured to ...

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Номер записи: 87
28-03-2019 дата публикации

Optical fiber strain and temperature measurement apparatus and optical fiber strain and temperature measurement method

Номер: US20190094082A1
Автор: Hitoshi Murai, Kengo KOIZUMI, Tokuo Yamaguchi
Принадлежит: Oki Electric Industry Co Ltd

A self-delayed homodyne interferometer includes light source unit, a splitting unit, an interference signal acquisition unit, a scattered light intensity acquisition unit, and a signal processing unit. The light source unit generates probe light. The splitting unit splits into two branches, Brillouin backscattered light occurring in an optical fiber to be measured with the probe light. The acquisition unit receives scattered light of one branch, and uses a self-delayed homodyne interferometer to generate an interference signal. The acquisition unit receives scattered light of the other branch, and acquires intensity of the scattered light. The signal processing unit separates and acquires a frequency shift amount from the intensity of the interference signal, and strain and temperature change from the intensity of the scattered light. The acquisition unit can change a phase of the scattered light of the one of the two branches.

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Номер записи: 88
06-04-2017 дата публикации

EXHAUST SYSTEM TEMPERATURE ESTIMATION SYSTEMS AND METHODS

Номер: US20170096957A1
Автор: Casetti Martino, COWGILL Joshua D., Naik Sanjeev M., Wu Zhijian James
Принадлежит:

A control system for an engine of a vehicle includes an adder module that determines a temperature sum based on a sum of a plurality of temperatures determined based on (i) a plurality of operating parameters of the vehicle and (ii) a plurality of predetermined values calibrated for determining an estimated temperature at a location within an exhaust system of the vehicle. A temperature difference module determines a temperature difference based on the temperature sum and a previous value of the temperature difference. An estimating module determines the estimated temperature at the location within the exhaust system based on the temperature difference and a reference temperature. An actuator control module selectively adjusts at least one engine actuator based on the estimated temperature. 1. A control system for an engine of a vehicle , comprising:an adder module that determines a temperature sum based on a sum of a plurality of temperatures determined based on (i) a plurality of operating parameters of the vehicle and (ii) a plurality of predetermined values calibrated for determining an estimated temperature at a location within an exhaust system of the vehicle;a temperature difference module that determines a temperature difference based on the temperature sum and a previous value of the temperature difference;an estimating module that determines the estimated temperature at the location within the exhaust system based on the temperature difference and a reference temperature; andan actuator control module that selectively adjusts at least one engine actuator based on the estimated temperature.2. The control system of further comprising:a first change module that determines a first temperature change based on a difference between the temperature sum and the previous value of the temperature difference; anda second change module that determines a second temperature change based on a product of the first temperature change and a gain value,wherein the temperature ...

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Номер записи: 89
06-04-2017 дата публикации

Temperature measurement device and temperature measurement method

Номер: US20170097267A1
Автор: Hiroyuki Fukuda, Kazushi Uno, Takahiro Arioka, Takeo Kasajima
Принадлежит: Fujitsu Ltd

A temperature measurement device includes: an optical fiber that is arranged along a predetermined path; a light source configured to input a light into the optical fiber; a measurer configured to measure temperature distribution information in an extension direction of the optical fiber based on a back-scattering light from the optical fiber; and a corrector configured to make a filter for reducing a noise component of temperature distribution information measured by the measurer based on a difference of temperature distribution information between two different regions of the optical fiber in which a common temperature distribution is obtained, and correct the temperature distribution information by applying the filter to the temperature distribution information.

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Номер записи: 90
12-04-2018 дата публикации

TARGET EVAPORATOR OUTLET TEMPERATURE MAPS FOR VEHICLE AIR CONDITIONING CONTROL

Номер: US20180099540A1
Автор: Cosgrove David W., Hirabayashi Hidekazu
Принадлежит:

A vehicle heating, ventilating, and air conditioning (HVAC) system can reduce a load applied to a vehicle powertrain during certain conditions. The system can include a compressor operable based on a first target evaporator outlet (TEO) temperature map. Systems and methods can determine if an HVAC system is activated, and whether an engine water temperature meets a forced HVAC recirculation intake threshold. Responsive to determining that the engine water temperature meets the forced HVAC recirculation intake threshold, it can be determined if the engine water temperature meets a first threshold. Responsive to the recirculation mode air source being selected, determining if at least one measured vehicle condition meets predetermined criteria. Responsive to determining that the engine water temperature meets the first threshold, the compressor can be operated based on a second TEO temperature map, the second TEO temperature map including higher TEO temperatures than the first TEO temperature map. 1. A method of operating a heating , ventilating , and air conditioning (HVAC) system in a vehicle , the HVAC system including a compressor operable based on a first target evaporator outlet (TEO) temperature map , the method comprising:determining whether an engine water temperature meets a forced HVAC recirculation intake threshold;responsive to determining that the engine water temperature meets the forced HVAC recirculation intake threshold, determining if the engine water temperature meets a first threshold; andresponsive to determining that the engine water temperature meets the first threshold, operating the compressor based on a second TEO temperature map, the second TEO temperature map including higher TEO temperatures than the first TEO temperature map.2. The method of claim 1 , further including the steps of:determining if the engine water temperature meets a second threshold; andresponsive to determining that the engine water temperature meets the second ...

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Номер записи: 91
08-04-2021 дата публикации

Verifiable Bubbler

Номер: US20210101817A1
Автор: Swiler Daniel R.
Принадлежит:

A bubbler device and method of its operation are disclosed. The bubbler device includes a bubbler tube that provides bubbles to a molten material in a furnace; a protective layer disposed on the bubbler tube; and a wire that is electrically coupled to the protective layer. The wire extends through the bore, and the protective layer and the wire partially form an electrical circuit for measuring integrity of the bubbler device based on at least one of conductivity or resistance in the electrical circuit. Sometimes, an inner protective material may be disposed on an inside surface of the tube and coupled to the protective layer, and the wire can be coupled to the inner protective material or multiple wires may be used. The use of dissimilar materials in these components may be used to form a thermocouple junction to measure the temperature of the molten material in a furnace. 1. A bubbler device comprising:a bubbler tube including an internal bore that provides bubbles to a molten material in a furnace;a protective layer disposed on an outside surface of the bubbler tube; andan electrically conductive material that is electrically coupled to the protective layer, wherein the electrically conductive material extends through at least a portion of the bore, and wherein the protective layer and the electrically conductive material at least partially form a first electrical circuit for measuring integrity of the bubbler device based on at least one of conductivity or resistance in the electrical circuit or temperature of the molten material.2. The bubbler device of claim 1 , wherein the bubbler device is configured to be inserted into the furnace.3. The bubbler device of claim 2 , wherein the bubbler device is configured to be inserted into a refractory block in a floor of the furnace.4. The bubbler device of claim 1 , wherein the molten material is glass.5. The bubbler device of claim 1 , wherein the electrically conductive material is structurally coupled to the ...

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Номер записи: 92
12-04-2018 дата публикации

HEAT EXCHANGER

Номер: US20180100822A1
Автор: Phillips Paul
Принадлежит:

A heat exchanger system comprises a heat exchanger; and one or more sensor(s) for measuring characteristics of a fluid flow field across a cross-section of a flow path in the heat exchanger. Each of the one or more sensor(s) comprises multiple conductivity sensing elements distributed across multiple locations in an array extending over the cross-section of the flow path for obtaining measurements of the fluid flow field at the multiple locations. 1. A heat exchanger system comprising:a heat exchanger; andone or more sensor(s) for measuring characteristics of a fluid flow field across a cross-section of a flow path in the heat exchanger;wherein each of the one or more sensor(s) comprises multiple conductivity sensing elements distributed across multiple locations in an array extending over the cross-section of the flow path for obtaining measurements of the fluid flow field at the multiple locations.2. A heat exchanger system as claimed in claim 1 , including one or more sensor(s) at one or more of a cross-section of a flow path at an inlet and/or an outlet of the heat exchanger claim 1 , within a manifold or flow distributor such as a tank claim 1 , at an entrance and/or an exit from a heat exchanger core of the heat exchanger claim 1 , part-way through a heat exchanger core of the heat exchanger and/or at any other selected location in the heat exchanger.3. A heat exchanger system as claimed in claim 2 , further comprising:two or more sensors at the heat exchanger core for measuring the distribution of fluid density, flow rate or temperature in a fluid flow field of two or more cross-sections at the core, wherein the sensors are located at two or more of an entrance to the core, and an exit from the core, or within the core and part-way through the core.4. A heat exchanger system as claimed in claim 1 , wherein each of the one or more sensor(s) comprise multiple conductivity sensing elements having electrode pairs with a space in between the electrodes claim 1 , ...

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Номер записи: 93
26-03-2020 дата публикации

METHOD OF ASSEMBLING A SENSING DEVICE HAVING A DOUBLE CLINCH SEAL

Номер: US20200096406A1
Автор: Petrarca Neil, VONK EDWIN
Принадлежит: SENSATA TECHNOLOGIES, INC.

A device for sensing pressure and temperature in a fluid environment includes a cover defining an interior. A thermistor tube is positioned at least partially within the interior, the thermistor tube extending substantially along a longitudinal axis. A port body is also positioned at least partially within the interior, the port body forming a channel which extends along the longitudinal axis for receiving a fluid from the fluid environment. A diaphragm is affixed within the port body. The diaphragm has a first surface exposed to the fluid within the channel and a second surface sealed from the channel. 120-. (canceled)21. A method of assembling a pressure sensing device having a double clinch seal , comprising:providing a cover defining an interior with a pressure sensing element within the interior, the cover having an annular flange within the interior;providing a port body within the interior, the port body having an outer annular ring, a channel being defined by the port body and the cover;forming the double clinch seal between the annular flange and the outer annular ring, the double clinch seal hermetically sealing the cover to the port body around the channel and preventing fluid from the channel from entering the interior.22. The method of claim 21 , further comprising providing a thermistor tube within the channel claim 21 , the channel being defined between the cover claim 21 , the port body claim 21 , and the thermistor tube claim 21 , the thermistor tube including a thermistor element within the channel.23. The method of claim 21 , further comprising pressing a housing against the cover to form a seal and seal an inner cavity around the interior.24. The method of claim 23 , wherein:a lower surface of the housing and an upper surface of the cover have alternating teeth; andduring the step of pressing the housing against the cover, the alternating teeth are interlocked and the housing the alternating teeth crimp to seal the housing and the cover.25. The ...

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Номер записи: 94
13-04-2017 дата публикации

GAS PROBES

Номер: US20170102298A1
Автор: KNIGHT Jeremy
Принадлежит: Endet Ltd.

An insertion-type probe main body for insertion into a pipe transporting gas and a method for making such an insertion-type probe main body are provided. The probe main body includes: an elongate upper tubular portion; an elongate lower tubular portion which is integral with and having a diameter smaller than the upper tubular portion; a bore which extends between the upper and lower tubular portions; and helical fins integrally formed on the lower tubular portion and which wind along and around an outer surface of the lower tubular portion and which overlap each other. A radial extension of the lower tubular portion plus helical fins corresponds to an external radius of the upper tubular portion, so that the helical fins extend in a streamline fashion from the upper tubular portion. Numerous other aspects are provided. 1. An insertion-type probe main body for insertion into a pipe transporting gas , the probe main body comprising:an elongate upper tubular portion;an elongate lower tubular portion which is integral with and having a diameter smaller than the upper tubular portion;a bore which extends between the upper and lower tubular portions; anda plurality of helical fins integrally formed on the lower tubular portion and which wind along and around an outer surface of the lower tubular portion and which overlap each other,wherein a radial extension of the lower tubular portion plus helical fins corresponds to an external radius of the upper tubular portion, so that the helical fins extend in a streamline fashion from the upper tubular portion.2. The insertion-type probe main body of claim 1 , wherein each of the plurality of helical fins originates on the outer surface of the lower tubular portion at a separate location.3. The insertion-type probe main body of claim 1 , wherein the outer surface of an inlet end of the elongate lower tubular portion is treated using a passivation process to reduce surface activity and particulate adhesion.4. The insertion-type ...

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Номер записи: 95
21-04-2016 дата публикации

DISTRIBUTED BRILLOUIN SENSING USING CORRELATION

Номер: US20160109223A1
Автор: Wang Ting, Weng Yi
Принадлежит:

Methods and systems for sensing conditions of a fiber include splitting a light signal into two branches. A first branch is converted to have a mode different from that of the second branch. Both branches are mode multiplexed into a single fiber. An output of the fiber is mode demultiplexed into the two branches. The first branch is mode converted to its original mode. Brillouin scattering patterns of the two branches are compared to determine a temperature and strain profile of the fiber. 1. A method for sensing conditions of a fiber , comprising:splitting a light signal into two branches;converting a first branch to have a mode different from that of the second branch;mode multiplexing both branches into a single fiber;mode demultiplexing an output of the fiber into the two branches;mode converting the first branch to its original mode;comparing Brillouin scattering patterns of the two branches to determine a temperature and strain profile of the fiber.2. The method of claim 1 , further comprising polarizing each of the two branches to have orthogonal polarizations.3. The method of claim 1 , further comprising coherently detecting the output of the fiber in the two branches.4. The method of claim 1 , wherein comparing the Brillouin scattering patterns comprises determining a Brillouin frequency shift of each branch.6. The method of claim 1 , wherein the fiber is a few-mode fiber.7. A sensor for sensing conditions of a fiber claim 1 , comprising:a light source;a coupler configured to split an output of the light source into two branches;a mode converter configured to convert light in a first branch between a mode shared by the second branch and a different mode;a mode multiplexer configured to multiplex both branches onto a single fiber;a mode demultiplexer configured to demultiplex an output of the fiber into the two branches, with light on the first branch being passed to the mode converter for conversion back to the mode shred by the second branch;a processor ...

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Номер записи: 96
19-04-2018 дата публикации

RETURN AIR SUPERHEAT DEGREE TEST METHOD FOR MULTI-SPLIT SYSTEM AND MULTI-SPLIT SYSTEM

Номер: US20180106518A1
Автор: LI Yuanyang, Luo Bin
Принадлежит:

A return air superheat degree test method for a multi-split system. A multi-split system comprises a re-cooling loop composed of a first heat exchanger () and a second heat exchanger (), a first temperature sensor (), a second temperature sensor () and a third temperature sensor (). The return air superheat degree test method comprises the following steps: acquiring a first temperature value (T) detected by the first temperature sensor (), a second temperature value (T) detected by the second temperature sensor () and a third temperature value (T) detected by the third temperature sensor (); acquiring a minimum value between the first temperature value (T) and the second temperature value (T), and acquiring a maximum value between the third temperature value (T) and the second temperature value (T); and calculating a superheat degree according to the minimum value and the maximum value. 1. A method for measuring a degree of superheat of return air of a VRF air conditioning system , wherein the VRF air conditioning system comprises a re-cooling circuit constituted of a first heat exchanger and a second heat exchanger , and a first temperature sensor , a second temperature sensor and a third temperature sensor , in which the first temperature sensor is provided at an inlet of a second heat exchange flow path of the second heat exchanger , the second temperature sensor is provided between an outlet of the second heat exchange flow path of the second heat exchanger and an inlet of a second heat exchange flow path of the first heat exchanger , and the third temperature sensor is provided at an outlet of the second heat exchange flow path of the first heat exchanger , and wherein the method comprises:obtaining a first temperature value detected by the first temperature sensor, a second temperature value detected by the second temperature sensor, and a third temperature value detected by the third temperature sensor;obtaining a minimum value between the first temperature ...

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Номер записи: 97
19-04-2018 дата публикации

SYSTEM AND METHOD FOR ACCRETION DETECTION

Номер: US20180106683A1
Автор: SINGH Bashisht Narayan
Принадлежит: TATA CONSULTANCY SERVICES LIMITED

This disclosure relates generally to accretion detection, and more particularly to system and a method for accretion detection within an iron kiln. The iron kiln includes a cylindrical body for holding and processing molten iron ore. In one embodiment, method includes receiving, in real-time, a first plurality of temperature values from a plurality of sensors configured on distinct locations on the outer surface of the iron kiln and is associated with a distinct sensor ID. The plurality of temperature values are compared with a reference temperature value to identify deviation in temperature gradient associated with the outer surface. Subsequently on identifying the deviation corresponding to one or more sensors, a second plurality of temperature values of surrounding locations of the one or more sensors is recorded and the presence of the accretion in the iron kiln is determined based on the second plurality of temperature values. 1. A system for accretion detection within an iron kiln , the iron kiln comprising a cylindrical body for holding and processing molten iron ore , the system comprising:a plurality of sensors configured on a plurality of distinct locations on the outer surface of the cylindrical body to measure temperature at the outer surface, the plurality of sensors associated with a distinct sensor ID;one or more memories to store the plurality of distinct locations and respective sensor ID corresponding to the plurality of sensors, and a reference temperature value associated with the outer surface; and receive, in real-time, a first plurality of temperature values of the plurality of distinct locations from the plurality of sensors;', 'compare the plurality of temperature values with the reference temperature value to identify deviation in temperature gradient associated with the outer surface;', 'on identifying the deviation corresponding to one or more sensors of the plurality of sensors, record a second plurality of temperature values of a ...

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Номер записи: 98
30-04-2015 дата публикации

Phosphor Thermometer with Two Waveguides

Номер: US20150113942A1
Автор: Hockaday Bruce
Принадлежит:

A phosphor thermometer is disclosed. The phosphor thermometer may comprise a light source configured to emit an excitation light, and an input waveguide configured to transmit at least a portion of the excitation light from the light source to a temperature sensing end. A phosphor may be located at the temperature sensing end and it may be configured to emit a fluorescence signal upon absorption of at least a portion of the excitation light transmitted by the input waveguide. The phosphor thermometer may further comprise an output waveguide configured to transmit at least a portion of the fluorescence signal from the phosphor to a detector. The detector may determine a fluorescence decay constant from the time dependent decay of the fluorescence signal, and the fluorescence decay constant may be correlated with a temperature. 1. A phosphor thermometer , comprising:a light source configured to emit an excitation light;an input waveguide configured to transmit at least a portion of the excitation light from the light source to a temperature sensing end;a phosphor located at the temperature sensing end, the phosphor being configured to emit a fluorescence signal upon absorption of at least a portion of the excitation light; andan output waveguide configured to transmit at least a portion of the fluorescence signal from the phosphor to a detector.2. The phosphor thermometer of claim 1 , wherein the input waveguide comprises a transmitting end proximal to the phosphor and the output waveguide comprises a receiving end proximal to the phosphor.3. The phosphor thermometer of claim 2 , wherein the transmitting end of the input waveguide comprises a tip having a surface extending at about a 90° angle with respect to a longitudinal axis of the transmitting end claim 2 , the surface being spaced from the phosphor by a distance along the longitudinal axis.4. The phosphor thermometer of claim 2 , wherein the receiving end of the output waveguide comprises a tip having a surface ...

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Номер записи: 99
29-04-2021 дата публикации

OPTICAL FIBER IDENTIFICATION AND DISTANCE MEASUREMENT

Номер: US20210123817A1
Автор: CHAMPAVERE Andre
Принадлежит: Viavi Solutions France SAS

In some examples, optical fiber identification and distance measurement may include utilizing a reflectometer and optical fiber connection device that includes a Rayleigh wavelength pass filter to pass, in one direction, an optical reflectometer signal to an optical fiber. The reflectometer and optical fiber connection device may include a Raman wavelength pass filter to filter out, in another direction, Rayleigh backscattering from the optical reflectometer signal. Further, the Raman wavelength pass filter may pass, in the another direction, a Raman Anti-Stokes signal from the optical fiber. 1. A system comprising: a Rayleigh wavelength pass filter to pass, in one direction, an optical reflectometer signal to an optical fiber; and', filter out, in another direction, Rayleigh backscattering from the optical reflectometer signal; and', 'pass, in the another direction, a Raman Anti-Stokes signal from the optical fiber., 'a Raman wavelength pass filter to], 'a reflectometer and optical fiber connection device comprising2. The system according to claim 1 , further comprising: generate the optical reflectometer signal;', 'receive the Raman Anti-Stokes signal from the optical fiber; and', 'identify, based on the received Raman Anti-Stokes signal and a temperature stimulus applied to the optical fiber, the optical fiber from a plurality of optical fibers., 'a fiber optic optical reflectometer to3. The system according to claim 2 , wherein the fiber optic optical reflectometer includes an optical time domain reflectometer (OTDR).4. The system according to claim 2 , wherein the fiber optic optical reflectometer includes an optical frequency domain reflectometer.5. The system according to claim 2 , wherein the fiber optic optical reflectometer is to identify claim 2 , based on the received Raman Anti-Stokes signal and the temperature stimulus applied to the optical fiber claim 2 , the optical fiber from the plurality of optical fibers by:comparing the received Raman Anti- ...

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Номер записи: 100