КОНДЕНСАЦИОННЫЙ ТЕПЛООБМЕННИК

Изобретение относится к области конденсационных теплообменников, более конкретно настоящее изобретение касается конструкции кожуха таких теплообменников. Конденсационный теплообменник содержит по меньшей мере одну намотанную в виде спирали трубку, внутри которой может проходить нагреваемая текучая среда, отражатель, кожух, внутри которого установлена трубка. Кожух оснащен газоотводным патрубком, дном и фасадной частью, на которой установлены средства подачи и/или производства горячего газа внутри кожуха. В теплообменнике указанный кожух содержит: трубчатую обечайку, закрытую на своих двух концах фасадной частью и дном. Дно выполнено из композиционного пластического материала. Задний край трубчатой обечайки имеет множество крепежных язычков. Дно имеет на своей периферии множество крепежных щелей, расположенных вдоль по меньшей мере части его окружности, при этом вдоль каждой крепежной щели в продольном направлении проходит первое продольное ребро, которое выступает наружу. Каждый крепежный ...

УСТАНОВКА ТЕПЛООБМЕННИКА

Установка теплообменника (2) содержит по меньшей мере один теплообменник (4), включающий по меньшей мере один, преимущественно горизонтально ориентированный коллектор (6а, 6b), образующий верхнюю сторону по меньшей мере одного теплообменника (4), при этом по меньшей мере один коллектор (6а, 6b) имеет боковые концевые части (8) и опорную конструкцию (10), включающую основную часть, содержащую, по меньшей мере частично, металлический материал, и опорные части коллектора (14), связанные с соответствующими боковыми концевыми частями (8) по меньшей мере одного коллектора (6а, 6b). Опорные части коллектора (14) изготовлены, по меньшей мере частично, из неметаллического материала и выполнены с возможностью приема боковых концевых частей (8) по меньшей мере одного коллектора (6а, 6b) для предотвращения контакта по меньшей мере одного коллектора (6а, 6b) с любыми металлическими частями опорной конструкции (10). 14 з.п. ф-лы, 9 ил.

УПЛОТНИТЕЛЬНАЯ КОНСТРУКЦИЯ ДЛЯ РЕЗЕРВУАРА

СПОСОБ ПРИВАРИВАНИЯ ГРЕБЕНЧАТЫХ УПЛОТНИТЕЛЬНЫХ ПЛАНОК К ПЛАСТИНЧАТЫМ ТЕПЛООБМЕННИКАМ

... \ \ 1 Изобретение относится к способу приваривания гребенчатых уплотнительных планок к пластинчатым теплообменникам, состоящим из множества попарно соединенных в пары отдельных пластин, изготовленных предпочтительно из вызококоррозионностойкого материала, соединенных между собой, в свою очередь, в штабель и снабженных гребенчатыми планками для разделения участвующих в теплообмене газовых потоков. Для получения газонепроницаемых и коррозионностойких сварных швов сварку входящих в прорези уплотнительной планки краев отдельных пластин с уплотнительной планкой осуществляют по меньшей мере с частичным использованием выступающего за наружную поверхность уплотнительной планки материала торцевых кромок краев пластин. Примыкающие к соединенным между собой краям пластин торцевые кромки краевых зон отдельных пластин сваривают с наружной стороной уплотнительной планки без присадочного материала с использованием материала пластин. Непрерывно возникающее в процессе сварки тепло отводят за счет прилегания ...

ТЕПЛООБМЕННЫЙ БЛОК И СПОСОБ ОСУЩЕСТВЛЕНИЯ ТЕПЛООБМЕНА

Device for exchanging heat used especially for cooling combustion air in IC engines of vehicles has flow units arranged in a two-part profiled housing

Device for exchanging heat has flow units arranged in a two-part profiled housing. A first housing part has a U-shaped profile and a second housing part is closed on he open side of the first housing part. The housing has an inlet and an outlet for the combustion air. The flow units are spaced from each other using a frame.

WAERMETAUSCHER

Wärmeübertrager

Die vorliegende Erfindung betrifft einen Wärmeübertrager (1) für ein Kraftfahrzeug mit in jeweils einem Rohrboden (2) oder einem Sammler (14) gefangenen Rohren (3) sowie mit zwei Seitenteilen (4). Erfindungswesentlich ist dabei, dass wenigstens ein Seitenteil (4) wenigstens eine in Längsrichtung des Seitenteils (4) verlaufende eingeprägte Aussteifungssicke (6) aufweist, die sich über zumindest eine Teillänge L2 oder begrenzt auf eine Teillänge L2 des Seitenteils (4) erstreckt und die bis zumindest einem Längsende (7) des Seitenteils (4) durchgeht.

Rohr-Lamellen-Paket eines Verflüssigers oder Verdampfers für Kraftfahrzeuge sowie Herstellungsverfahren

Wärmetauscher mit aerodynamischen Eigenschaften zur Verbesserung der Leistung

Ein Gas-Flüssigkeit Wärmetauscher, wie ein Ladeluftkühler, weist einen Kern auf, der einen Stapel aus flachen Rohren, die Flüssigkeitskühlmittel-Strömungskanäle und eine Mehrzahl von offenen Gasströmungskanälen zwischen den flachen Rohren definieren. Ein letzter Gasströmungskanal ist zwischen einer Abschlussplatte des Kerns und einem benachbarten flachen Rohr definiert, derart dass der letzte Gasströmungskanal in Kontakt mit nur dem einen flachen Rohr ist. Ein Sperrelement erstreckt sich entweder entlang der Vorderseite oder der Rückseite des Kerns und blockiert zumindest teilweise den letzten Gasströmungskanal. Jedes flache Rohr kann ein Paar von Kernplatten umfassen, wobei mindestens eine Platte eine Lasche einschließt, die in einen Gasströmungskanal hereinragt und einen Gasbypasskanal zwischen dem Rand des turbulenzverstärkenden Einsatzes und den Seiten einer Kühlmittelsammelleitung abdeckt.

Abgaskühler

Abgaskühler (1) für eine Brennkraftmaschine,- mit einem Kühlergehäuse (14),- mit wenigstens einem am Kühlergehäuse (14) angeordneten Abgaseinlass (2) zum Zuführen eines Abgasstromes,- mit wenigstens einem am Kühlergehäuse (14) angeordneten Abgasauslass (3) zum Abführen des Abgasstromes,- wobei der Abgaseinlass (2) und der Abgasauslass (3) innerhalb des Kühler- gehäuses (14) fluidisch verbunden sind,- mit wenigstens einem am Kühlergehäuse (14) angeordneten Kühlfluideinlass (5) zum Zuführen eines Kühlfluidstroms,- mit wenigstens einem am Kühlergehäuse (14) angeordneten Kühlfluidauslass (6) zum Abführen des Kühlfluidstroms,- wobei der Kühlfluideinlass (5) und der Kühlfluidauslass (6) über wenigstens ein Kühlfluidrohr (7) fluidisch verbunden sind,- wobei das wenigstens eine Kühlfluidrohr (7) im Kühlergehäuse (14) im We- sentlichen quer zu einer Abgasströmungsrichtung (4) ausgerichtet ist,- wobei das wenigstens eine Kühlfluidrohr (7) wenigstens einen Turbulenzer- zeuger (8) aufweist, der zur ...

Heat exchanger used in vehicle

The heat exchanger (1) may be used in a motor vehicle. It has an inlet (6) for fluid at the bottom, leading into a distribution tank (2,5). The fluid flows through an array of flattened tubes (2). At the top the fluid is discharged into a collection tank (2,7) having an outlet (8).The sides (9,10) of the heat exchanger assembly are bowed inwards, and may form a curved or a shallow V-shape. The sides have corrugations bearing inwards against the outermost flattened heat exchanger tubes. The flattened tubes are spaced apart by a system of ribs (3).

Motor vehicle radiator with parallel tubes - has in one side wall clamping wedge retaining tie rod in fixed position

The radiator has a set of flat vertical cooling tubes (1) with zig-zag plates (2) between them, clamped together by a channel (3,4) at each end. The channels are tensioned by two horizontal tie rods (5) each side. The bent-over ends of the rods carry discs (7) for insertion into keyhole slots (10,16) through the flanges of the channels. The slots (10) at one end incorporate shoulders along one edge, which successively increase the width of the narrow part of the keyhole slot. The bent ends of the rods are square in cross section, to fit behind a selected shoulder. This enables a required tension to be applied.

Wärmeübertrager mit einem Wärmeübertragerblock

Die Erfindung betrifft einen Wärmeübertrager (1) mit einem Wärmeübertragerblock (3) mit Rohren (4) und dazwischen angeordneten Wärmeübertragerelementen (5). Erfindungswesentlich ist dabei, dass die Wärmeübertragerelemente (5) über eine elastische Verbindung (6) mit den Rohren (4) verbunden sind, wobei die Verbindung (6) derart ausgebildet und dimensioniert ist, dass sie eine temperaturabhängige Änderung eines Abstandes a und damit einen temperaturabhängigen Wärmeübertrag zwischen den Rohren (4) und den zugehörigen Wärmeübertragerelementen (5) ermöglicht.

Kuehler, insbesondere fuer Brennkraftmaschinen

VERTEILER FÜR PARALLELFLUSS-WÄRMETAUSCHER.

Seitenteil für Wärmetauscher und Wärmetauscher mit Seitenplatten

Wärmetauscherkern und dessen Herstellung

WÄRMETAUSCHER

Heat exchanger for use in motor vehicle, has flat tubes for providing flow path for fluid, and elastically deformable side part with integrally formed caps for closing openings in tanks, where fin is supported between tubes

The exchanger has a set of flat tubes (101) for providing a flow path for a fluid. A fin is supported between the tubes, and is positioned along a flow path for another fluid e.g. air. The fin and the tubes partially define a core. Tanics are positioned adjacent to opposite ends of the tubes. An elastically deformable side part (120) extends across a heat exchanger core, and has a pair of integrally formed caps for closing openings in tanks (104), where the caps contact the core. The side part has a rigid central part arranged between the caps, and contacts an outermost tube of the core. An independent claim is also included for a method of assembling a heat exchanger.

Air conditioning system for vehicle, particularly for buses, has fluid circuit with condenser device, evaporator device and compressor unit

The air conditioning system has a fluid circuit with a condenser device, a evaporator device and a compressor unit. An expansion device is provided between a low pressure side and a high pressure side of the fluid circuit and particularly a throttle device. The condenser device and a evaporator device has a heat exchanger, which is formed as a non-modular composed heat exchanger unit (1) or is composed of multiple heat exchanger units.

Wärmetauscher und Verfahren zur Herstellung desselben

Ein Wärmetauscher mit Seitenplatte (18, 20) und ein Verfahren zur Herstellung eines Wärmetauschers werden bereitgestellt. Die Seitenplatte (18, 20) des Wärmetauschers beinhaltet mindestens einen örtlichen Kontaktpunkt (36), der während der Montage des Wärmetauschers mit einem Kopfteil (10, 12) des Wärmetauschers verbunden werden kann. Der örtliche Kontaktpunkt (36) trennt sich unter relativ niedriger Spannung, die aufgrund der Wärmeausdehnung und Kontraktion des Wärmetauschers unter normalen Betriebsbedingungen bewirkt wird, vom Kopfteil (10, 12) ab, und daher können sich die Rohre des Wärmetauschers ausdehnen und zusammenziehen.

Vorrichtung zum Wärmeaustausch zwischen strömungfähigen Medien

Eine Vorrichtung zum Wärmetausch zwischen strömungsfähigen Medien, von denen zumindest eines im flüssigen Zustand ist, weist einen Wärmetauscher-Block auf, der auf einer Seite durch eine Einströmkammer 1 und auf der gegenüberliegenden Seite durch eine Ausströmkammer 3 für Zufuhr bzw. Abfuhr des flüssigen Mediums begrenzt ist, der Fluidwege 7 für das flüssige Medium, die sich durch den Block von der Einströmkammer 1 zur Ausströmkammer 3 erstrecken und durch zwischen ihnen befindliche Strömungswege 8 für das Hindurchleiten des anderen strömungsfähigen Mediums voneinander getrennt sind, sowie eine Deckplatte 9 aufweist, die sich, die Fluidwege 7 und Strömungswege 8 überdeckend, von Einströmkammer 1 zur Ausströmkammer 3 erstreckt und den Block an einem Ende abschließt, wobei die Deckplatte 9 zumindest einen inneren Durchgangskanal 13 aufweist, der sich, die Fluidwege 7 umgehend, als Nebenstromkanal von der Einströmkammer 1 zur Ausströmkamme 3 erstreckt, durch zumindest eine Druckbegrenzhungseinrichtung ...

IMPROVEMENTS RELATING TO HEAT EXCHANGERS

Heat exchangers

Devices for heat transfer

A device 1a for heat transfer between fluids, comprising: a two-part housing 2a, 3a formed with connection pipes 5a, 8a 6a, 9a for each fluid; and a heat exchanger (11a, fig.1c) enclosed by the housing, the housing directs the first fluid through, and the second fluid around, the heat exchanger. The pipes 8a, 9a, are on the first housing element 2a, and the pipes 5a, 6a are on the second housing 3a, and a flow path (23, fig.1e) is formed inside the second housing 3a for directing the first fluid. The flow path extends between a connection pipe 5a and a collecting region (17, 18, fig.1c), or the connection pipes for the fluids are arranged only on the first housing element (fig.3c), and the housing elements 2a, 3a are each formed as a one-piece element with the connection pipes 5a, 6a, 8a, 9a. The device may be used as part of an exhaust gas recirculation system.

Heat exchanger

A tube type heat exchanger 10 comprises a core 12 having a plurality of tubes (14, fig 1) through which a first fluid communicates. Each tube has an inlet and an outlet, wherein the tube inlets define an inlet plane 16 and the tube outlets define an outlet plane (18). The tubes are spaced from one another for receiving a second fluid therebetween for heat transfer between the first and second fluids. A jacket 20 provided adjacent the core contains the second fluid, and comprises a jacket inlet 22 for passage of the second fluid en-route to the core. The jacket extends between the inlet plane and the outlet plane, and the jacket inlet is offset from the inlet plane towards the outlet plane. The heat exchanger further comprises a deflector arrangement 26 for directing a flow of the second fluid from the jacket inlet towards the inlet plane prior to entering the core via one or more core openings 34. The jacket inlet may comprise one or more inlet apertures 40 upstream of the core openings ...

Heat exchange apparatus

IMPROVEMENTS IN OR RELATING TO HEAT EXCHANGERS

... 1,204,004. Plate heat-exchangers. SOC. ANON. DES USINES CHAUSSON. 9 Nov., 1967 [21 Nov., 1966], No. 51041/67. Heading F4S. A plate heat exchanger e.g. for cooling oil of vehicle motors, comprises an outer housing formed of two stamped, complementary parts 1, 2 having holes 18a for positioning locating pins 20, 21 on which hollow heat exchange elements are slid by means of aligned holes, are superposed above the other and thereafter the two housing parts are secured together by clips 10 engaging slideways 9 formed by end flaps of the sections, the assembled heat exchanger being subsequently submitted to a brazing operation. The heat exchanger is made of aluminium and the elements each comprise two complementary stamped parts having at least two fluid inlet and outlet chambers 13, 14 at each end connected by two ducts 15. Corrugated elements 22 which create turbulence may be positioned within the heat exchange elements, gills may be interposed between successive elements and bracing elements ...

HEAT EXCHANGER HAVING MEANS TO PROVIDE AN AIR SEAL BETWEEN ITSELF AND AN ADJACENT CASING PART

A THERMAL STORAGE TANK

A THERMAL STORAGE TANK

A THERMAL STORAGE TANK

MEHRZONIGE MOTOR VEHICLE AIR CONDITIONING SYSTEM

HALTERUNG EINES TEILS, INSBESONDERE EINES WÄRMETAUSCHERS, ZWISCHEN ZWEI HALTEWINKELN MITTELS BOLZEN

INTERCOOLER

HEAT EXCHANGER

AIR-COOLED CONDENSOR OR AIR-HEATED EVAPORATOR

HEAT EXCHANGER, IN PARTICULAR FOR CONDENSATION LAUNDRY DRYER

Membrane-integrated energy exchange assembly

A method of forming a membrane panel configured to be secured within an energy exchange assembly may include forming an outer frame defining a central opening, and integrating a membrane sheet with the outer frame. The membrane sheet spans across the central opening, and is configured to transfer one or both of sensible energy or latent energy therethrough. The integrating operation may include injection-molding the outer frame to edge portions of the membrane sheet. Alternatively, the integrating operation may include laser-bonding, ultrasonically bonding, heat-sealing, or the like, the membrane sheet to the outer frame. 1200b 208 208 200 300 100a y 4 1 8 - 4 1 6 4 0 0 206b 206a-, 206b 206a 402 206a 406---. 408 100 200 402 414 1 02 410404 403/'742-41 ...

DEVICE FOR EXCHANGING HEAT

Heat exchanger and method for manufacturing thereof

Heat exchanger including coil end close-off cover

A heat exchanger assembly including a heat exchanger that has a first end and a second end opposite the first end, and a cover coupled to the second end. The heat exchanger also includes a plurality of fins with a first fin disposed adjacent the first end and a second fin disposed adjacent the second end, and a continuous, serpentine coil. The coil includes first return bends projecting beyond the first fin and second return bends projecting beyond the second fin. The cover has a base plate and separate receptacles encasing one or more of the second return bends to permit airflow through the encased second return bends. The base plate is positioned on the second end to inhibit airflow from one of the receptacles to another of the receptacles 8563038_1 (GHMatters) P104904.AU rr ...

EXPLOSION-PROOF ENCLOSURES WITH ACTIVE THERMAL MANAGEMENT BY HEAT EXCHANGE

Enclosures for use in hazardous areas include heat exchangers for active thermal management. The enclosures are coupled to a device having heat transfer capabilities. Equipment within the enclosures produces heat within the enclosure. The heat exchanger removes heat produced from the equipment and manages the internal temperature of the enclosures to a level suitable for hazardous locations. The enclosures can be actively cooled or heated using the device.

CHARGE AIR COOLER MOUNTING ARRANGEMENT

... 20086 TITLE OF THE INVENTION CHARGE AIR COOLER MOUNTING ARRANGEMENT A charge air cooler for mounting within the intake manifold of a combustion engine. A pair of U-shaped mounting brackets are secured to opposite sides of the charge air cooler, and these brackets carry floating nuts for receiving bolts for mounting the charge air cooler securely within the intake manifold.

HEAT EXCHANGER

HEAT EXCHANGER

HEAT EXCHANGER ASSEMBLY

HEAT EXCHANGER

The present invention relates to a modular system for heat exchange between fluids, the system comprising a plurality of open elements (3) which by means of two end plates (2) are connected together. An open element (3) according to the present invention is constituted of a folded and sealed sheet material (13) that is arranged in an open frame (17).

CONVERSION SET FOR A TUBE BUNDLE HEAT EXCHANGER

The present invention relates to a conversion set for pipe bundle heat exchanger having a cylindrical housing. Using said conversion set, existing tube bundle heat exchangers can be changed over such that the efficiency and thus the heat transfer thereof is improved, large exchange surface areas are provided, and energy costs are reduced. The conversion set can also be used in high-pressure applications for pressures above 300 bar. According to the invention, the conversion set has at least one plate heat exchange unit for replacing the tube bundle unit, comprising at least the following components: a plate packet having at least two heat exchange plates, each comprising at least one through hole and welded to each other in pairs along the periphery thereof or along the periphery of the through holes, two mounting plates each having at least one through hole, wherein one each of the mounting plates is disposed at each end of the plate packet and is connected to each outermost heat exchanger ...

HEATING DEVICE

HEAT EXCHANGER AND HEAT EXCHANGE DEVICE

A heat exchanger including a tubular core case, a pair of end plates for closing opposite ends of the core case, and a plurality of heat exchange tubes supported at opposite ends thereof by the end plates and allowing flow of a first heating medium inside thereof. One end plate is disposed on an upstream side of the first heating medium as an upstream end plate while the other end plates is disposed on a downstream side of the first heating medium as a downstream end plate. The downstream end plate comprises a downstream bottom surface part for supporting downstream end parts of the heat exchange tubes, and a downstream wall part formed integrally with and rising from a peripheral edge of the downstream bottom surface part, and a top end part of the downstream wall part is oriented toward upstream of the flow of the first heating medium.

Sealed flat sheet type heat exchanger

A flat sheet type heat exchanger consists of sheets with regularly spaced embossed impressions, which are welded together along the edges to form spaces between pairs and which are also welded together in pairs to form tubular openings resembling honeycombs; the sheets are thus bonded together into stacks so that their spaces for the heat-exchanging media are diposed at an angle to each other. The sheets are held apart by slotted plates along the edges; the distance between adjacent teeth of the plates is the depth of the embossed features plus double the thickness of one sheet, edging frame plates hold the stacks firmly together, combined with angle type members along the stacks. The structure pref. also incorporates silicone sealing strips and a silicone covering for foamed glass.

HEAT EXCHANGER FOR LOW TEMPERATURE

AIR PURIFIER

热交换器

... 在具备一对中空集流管(1) (1)与该集流管(1) (1)相通连接的多根传热管(3)、配设在传热管(3)之间及最外侧的传热管(3)的外侧的波纹状散热片(4)和配设在最外侧的散热片(4)的外侧的侧板(5)的热交换器中，使侧板(5)的端部的横截面外周形状形成为与传热管(3)的端部的横截面外周形状相同或大致相同，并且使设置在集流管(1)上的侧板嵌合孔(7)和传热管嵌合孔(6)设成相同或大致相同的形状。由此，不必在侧板(5)的端部形成特殊的嵌合形状，并且可以提高集流管(1)中的侧板嵌合孔(7)、传热管嵌合孔(6)的形成作业的作业性，由此可以优化生产性以降低成本。 ...

Heat exchanger and method for producing same

Disclosed is a heat exchanger-configured from: an inlet tank provided to the inlet side to which a heating medium is sent via one external piping; an outlet tank provided to the outlet side from which the heating medium is sent via another external piping; a plurality of heat transfer tubes that are layered while interconnecting the inlet tank and the outlet tank to each other; and a side plate that is provided to one end in the layering direction of said heat transfer tubes and that joins with the end section of one end in the layering direction of the inlet tank and the outlet tank-characterized by a claw section being formed to the end section at one end in the layering direction of one tank of either the inlet tank or the outlet tank, and by said claw section being caulked to a first concavity provided to the end section of the aforementioned side plate. The heat exchanger provided with an outer surface shape having few irregularities is provided with simple and stable quality.

Heat exchanger

Echangeur de chaleur, notamment radiateur de refroidissement pour vehicule automobile

La presente invention concerne un echangeur de chaleur, notamment un radiateur de refroidissement, comportant un bloc 2 echangeur de chaleur constitue d'un faisceau de tubes ailetes 3, 6 debouchant dans au moins une boite collectrice de fluide 4, 5 et des parties laterales ou traverses 9 disposees sur les bords lateraux du bloc 2 et liees l'une a l'autre par un tirant 10. Selon l'invention le tirant 10 est une sangle formant une boucle fermee. Application notamment a un vehicule automobile.

PERFECTIONNEMENTS AUX ECHANGEURS DE TEMPERATURE A FLUX CROISES, NOTAMMENT POUR SYSTEMES DE VENTILATION MECANIQUE POUR LOCAUX

L'ECHANGEUR COMPREND UNE CARCASSE CUBIQUE 1 RENFERMANT LES PLAQUES 1A DELIMITANT LES DEUX CIRCUITS, ET QUATRE CAISSONS DEMONTABLES 2 A 5 PRESENTANT UNE OUVERTURE ETABLIE AU PROFIL CARRE DE LA CARCASSE. CES CAISSONS, DOTES D'UNE PAROI FILTRANTE 9 POUR LES UNS, D'UN MOTO-VENTILATEUR 6 POUR LES AUTRES, PORTENT DES BUSES LATERALES DE RACCORDEMENT 7, 8, 10, 11 QUI PEUVENT AFFECTER QUATRE ORIENTATIONS DIFFERENTES MOYENNANT UNE DISPOSITION CONVENABLE DE CHAQUE CAISSON.

A PLATE HEAT EXCHANGER, IN PARTICULAR COOLER FOR RECIRCULATED EXHAUST GASES, COMPRISING AN ENVELOPE DEFINING BOXES INPUT AND OUTPUT THEREOF

Multi tubular finned radiator for vehicle engine coolant - comprising metal tube between plastic reservoir manifolds of matched thermal expansion

HEAT EXCHANGERS APPARATUS FOR MAKING DEBOSSED DISPLAYS IN BLANKS

HEAT EXCHANGER, IN PARTICULAR RADIATOR FOR INTERNAL COMBUSTION ENGINES

COVER OF HEAT EXCHANGER CORE, ON A SUPPORT BEAM, THE HEAT EXCHANGER COMPRISING SUCH A BUNDLE AND AIR INTAKE MODULE INCLUDING SUCH EXCHANGER.

RADIATORS Of AIR OF OVERFEEDING FOR INTERNAL COMBUSTION ENGINES

Echangeur thermique comprenant des barres de fermeture.

La présente invention concerne un échangeur thermique comprenant des barres de fermeture. Des barres de fermeture 18, 20 solides reliées au noyau 10 de l'échangeur thermique ont une forme et sont disposées de telle façon que ces barres de fermeture forment un rebord en saillie continu au coin ou le long de la longueur de ce noyau 10 de l'échangeur thermique. Des conduits collecteurs ou distributeurs 24, 26 peuvent maintenant être soudés au rebord, évitant ainsi d'endommager les éléments brasés du noyau 10 de l'échangeur thermique et augmentant la flexibilité entre le noyau et les conduits collecteurs ou distributeurs 24, 26 peuvent maintenant être soudés au rebord, évitant ainsi d'endommager les éléments brasés du noyau 10 de l'échangeur thermique et augmentant la flexibilité entre le noyau et les conduits collecteurs ou distributeurs 24, 26 pendant les cycles thermiques. L'invention est par exemple utilisable en aéronautique.

HEAT EXCHANGER HAS PLATES

DISPOSITIF DE FIXATION RIGIDE POUR RADIATEUR DE VEHICULES AUTOMOBILES

L'INVENTION CONCERNE UN DISPOSITIF POUR FIXER RIGIDEMENT UN RADIATEUR DE VEHICULE, QUI COMPREND DES MANCHONS 14 MONTES SUR DES PARTIES OPPOSEES DU RADIATEUR, UNE TIGE DE LIAISON 20, ET DES PARTIES COURBES DE BORD 16 FORMEES SUR LES PARTIES OPPOSEES DU RADIATEUR; CHAQUE MANCHON COMPREND UN ALESAGE LONGITUDINAL 26 LE TRAVERSANT ET UNE GORGE LATERALE 34 A FOND COURBE 36, EST ADAPTE AUX PARTIES COURBES 16 ET EST MONTE DE FACON COULISSANTE SUR CES DERNIERES DE MANIERE QUE LEURS ALESAGES SOIENT EN ALIGNEMENT; UNE TIGE 20 EST DISPOSEE AU TRAVERS DU RADIATEUR, PASSEE DANS LES ALESAGES ALIGNES ET FIXEE A L'INTERIEUR DE CES DERNIERS PAR DES ECROUS 38 ENGAGES SUR LES EXTREMITES FILETEES ET SERRES CONTRE LES MANCHONS RESPECTIFS.

ECHANGEUR DE CHALEUR ET PROCEDE DE FABRICATION DE CELUI-CI

ECHANGEUR DE CHALEUR, EN PARTICULIER RADIATEUR POUR VEHICULES AUTOMOBILES. L'ECHANGEUR DE CHALEUR SELON L'INVENTION EST CARACTERISE EN CE QUE, DANS LA REGION DES EXTREMITES D'AILETTE 3 SONT PREVUES DES SURFACES FORMEES PAR DES PARTIES COUDEES 15, 16, 17 DES AILETTES 3, PARTIES QUI S'ETENDENT AU MOINS APPROXIMATIVEMENT PERPENDICULAIREMENT A LA DIRECTION LONGITUDINALE DES AILETTES 3. APPLICATION AUX RADIATEURS POUR VEHICULES AUTOMOBILES.

EXCHANGER OF HEAT HAS LIMPS COLLECTING TUBULAR AND MOUNTING FOOT

PLAYS FOR VEHICLE HEAT EXCHANGER

HEAT EXCHANGER TYPE ORTHOGONAL CROSSING OF TWO FLUIDS

COOLING DEVICE FOR AN INTAKE AIR OF AN INTERNAL COMBUSTION ENGINE

Heat exchanger e.g. charge air cooler, for motor vehicle, has end crosspieces i.e. flanges, extending between manifolds and comprising folded tabs with ends supported on lateral faces of tubes

L'échangeur de chaleur comprend un faisceau (10) de tubes (12) et d'intercalaires (14) monté entre deux collecteurs (16), ainsi qu'au moins une traverse d'extrémité (18) comportant au moins une languette (24) pliée présentant une extrémité en appui sur une face latérale d'un tube (12, 12e) et/ou d'un intercalaire (14, 14e). La ou les languettes (24) évitent tout contact du faisceau avec un support de brasage. L'invention concerne aussi un procédé d'assemblage d'un tel échangeur de chaleur. L'invention s'applique notamment aux échangeurs de chaleur pour véhicules automobiles.

HEAT EXCHANGER, IN PARTICULAR FOR MOTOR VEHICLE, AND RESPECTIVE AIR INLET DEVICE

HEAT EXCHANGER COMPRISING A HEAT EXCHANGER BUNDLE AND A HOUSING

Crossmember for mounting a vehicle radiator

La traverse (4) relie entre elles les deux boîtes à eau (2, 3) du radiateur et s'étend le long d'un flanc (22) du faisceau de tubes (1). Différentes séries de trous répartis le long de la traverse permettent son assemblage à l'une (3) des boîtes à eau en des emplacements différents pour obtenir des radiateurs de hauteurs différentes. Des volets (28, 29) découpés dans la semelle de la traverse peuvent être pliés en direction du faisceau pour barrer le passage de l'air entre ce dernier et la semelle lorsqu'un autre emplacement d'assemblage que celui le plus éloigné de l'extrémité de la traverse est utilisé.

INTAKE HOUSING COMPRISING A HEAT EXCHANGER

HEAT EXCHANGER HOUSING BEAM HAS ROUNDED CORNERS

EXCHANGER OF HEAT HAS LONG TUBES FOR VEHICLES HEAVY LORRIES

Exchanger of heat to radiator tanks connected for motor vehicles

L'échangeur de chaleur comprend un faisceau (10) de tubes (12) monté entre deux boites à eau (16 et 18), dont chacune est délimitée par une paroi (22; 30) en matière plastique moulée présentant deux faces latérales opposées (54; 56) sur lesquelles sont fixées les joues latérales (40) de deux montants (36) reliant les deux boites à eau et encadrant le faisceau. Pour réaliser la fixation d'une joue latérale (40) d'un montant (35) sur une paroi latérale (54; 56) d'une boite à eau (16; 18), on utilise à chaque fois au moins une vis auto-taraudeuse (46) qui traverse une ouverture (58; 60) ménagée dans ladite joue (40) et qui s'engage dans un alésage (62) ménagé dans la paroi de la boite à eau.

Radiator for motor vehicle has flexible matrix tubes supported between cross tubes connecting manifolds

Un échangeur de chaleur, en particulier pour véhicule automobile, comprend un faisceau (10) formé uniquement de tubes souples (12) en matière plastique, ainsi que deux blocs d'extrémité (22, 24) joignant ces tubes. Chaque bloc d'extrémité (22, 24) est fixé à deux traverses (36, 38) encadrant le faisceau (10) et propres à maintenir le faisceau (10) dans une configuration choisie.

Cover for heat exchange bundle of charge air cooler to cool air intake module of heat engine of car, has wall comprising flat peripheral edge to authorize removable fixing of cover on housing, and reinforcement unit to reinforce wall

L'invention concerne un couvercle (25) destiné à être fixé à un boîtier (2) d'échangeur de chaleur (1), ledit couvercle (25) comprenant une paroi (26) destinée à obturer un orifice (5) d'introduction d'un faisceau (7) d'échange de chaleur dans le boîtier (2), ladite paroi (26) présentant un bord périphérique (27), plan, configuré pour autoriser une fixation amovible du couvercle (25) sur le boîtier (2), caractérisé par le fait qu'il comprend des moyens (30) de renfort mécanique de ladite paroi (26). L'invention concerne également un faisceau (7) d'échange de chaleur comprenant un tel couvercle (25), un échangeur de chaleur (1) comprenant un tel faisceau (7) et un module d'admission d'air pour moteur thermique de véhicule automobile comprenant un tel échangeur (1).

HEAT EXCHANGER COMPRISING A HEAT EXCHANGER BUNDLE AND A HOUSING

INSTALLATION FOR MOTOR VEHICLE

HEAT EXCHANGER

A HEAT EXCHANGER COMPRISING A HOUSING AND MEANS FOR IMPROVING THE TIGHTNESS OF SAID HOUSING

[...] MOUNTING FOR HEAT EXCHANGER

Heat exchanger plate assembly

L'invention a pour objet un faisceau de plaques pour un échangeur thermique, du type comprenant un empilement de plaques (2) métalliques, parallèles les unes aux autres, et comportant chacune des bords à surface lisse et une partie centrale munie d'ondulations pour former avec les plaques (2) associées un double circuit de circulation de fluides indépendants et à contre-courant. Les plaques (2) sont reliées les unes aux autres au niveau de leurs bords longitudinaux par une couche de soudure (11) déposée sur toute la hauteur de chaque surface latérale du faisceau et l'empilement de plaques est placé entre une tôle supérieure 12 et une tôle inférieure 13 s'étendant sur toute la surface des plaques 52). Le faisceau comprend des moyens (20) de reprise des efforts perpendiculaires aux plaques (2) et des moyens (30) de reprise des contraintes entre les tôles (2) et les couches de soudure (11).

Heat exchanger with water (header) boxes connected by uprights

L'invention concerne un échangeur de chaleur comprenant un faisceau de tubes montés entre deux boîtes à eau (16) reliées par deux montants (34). Pour la fixation d'un montant (34) sur une boîte à eau (16), on prévoit une pièce intercalaire (44) propre à être fixée entre deux joues opposées (38) du montant (34) et à prendre appui contre une face d'extrémité (52) de la boîte à eau. Application notamment aux échangeurs de chaleur pour poids lourds.

PROCEEDED Of MAKING Of an EXCHANGER OF HEAT ASSEMBLY BY WELDING, IN PARTICULAR BY BRAZING, AND EXCHANGER BEING REFERRED TO it HAS

HOUSING FOR A HEAT EXCHANGER AND A HEAT EXCHANGER COMPRISING SAID HOUSING

Boitier adapté pour un premier fluide, destiné à circuler au sein d'un faisceau d'échange d'un échangeur de chaleur pour échanger une quantité déterminée de chaleur avec un deuxième fluide circulant au sein dudit faisceau d'échange, ledit boitier comprenant un boitier d'entrée pour guider ledit premier fluide vers l'intérieur de l'échangeur de chaleur, et un boitier de sortie pour guider ledit premier fluide vers l'extérieur de l'échangeur de chaleur, le faisceau d'échange comprenant une première extrémité latérale et une deuxième extrémité latérale, ledit boitier d'entrée comprenant au moins une paroi, le boitier de sortie comprenant au moins une paroi, de sorte que la paroi du boîtier d'entrée et la paroi du boîtier de sortie coopèrent le long d'une ligne de jonction pour recouvrir la première extrémité latérale du faisceau d'échange.

HEAT EXCHANGER ASSEMBLIES

HEAT EXCHANGER

Un ensemble échangeur de chaleur pour un système à gaz inerte comprend une bride d'entrée d'air dynamique (204), une bride de sortie d'air dynamique (206) et un noyau (200) couplé à la bride d'entrée d'air dynamique (204) et à la bride de sortie d'air dynamique (206). Le noyau (200) comprend un ensemble d'ailettes présentant une pluralité de couches d'air chaud (212) et de couches d'air dynamique (402). Les couches d'air chaud (212)présentent une longueur effective d'écoulement d'air chaud, les couches d'air dynamique présentent une longueur effective d'écoulement d'air froid, et l'ensemble d'ailettes présente une longueur de non-écoulement. Un rapport entre la longueur effective d'écoulement d'air chaud et la longueur effective d'écoulement d'air froid est compris entre 9,23 et 10,32. Un rapport entre la longueur de non-écoulement et la longueur d'écoulement d'air froid est compris entre 21,86 et 25,23.

Heat exchanger for motor vehicle

Cooling tower entry door structure

An adjustable support assembly is provided that includes a front left base support, a front left lower elongated support and a front left upper elongated support. Also included are a front right base support, a front right lower elongated support, and a front right upper elongated support. Such supports are designed to be placed in a structural wall, particularly the structural wall of the cooling tower, wherein an opening would be cut in the wall to receive an entry door. The support assembly provides structural integrity from the lower section of the cooling tower to the upper section of the cooling tower, and allows the door opening to be cut out without loss of such structural integrity.

Heat exchanger assembly having a seal

A heat exchanger assembly having first and second heat exchangers and a seal. The seal may be disposed on the first heat exchanger and may have an elongated portion that extends toward the second heat exchanger to direct the flow of cooling air.

Modular construction compressed air/gas dryer system with filtration

A modular compressed-gas dryer including in series: an inlet module, a precooler/reheater module, an evaporator module, and a sump module. The modules form columns where at least one column has a filtration chamber. Further provided are a gas outlet and gastight seals between modules. The system creates a first and second set of heat transfer passages where refrigerant passes through the second set in a heat exchange relationship in a direction perpendicular to incoming gas passing in the first set. The filtration chamber conducts chilled gas from the first set to a third set of heat transfer passages. The third set extends through the precooler/reheater in heat exchange relationship with the first set. Chilled gas passes in heat exchange relationship in a direction perpendicular to the incoming gas so that the incoming gas chilled in the evaporator exchanges heat with the incoming gas in the precooler/reheater.

MAIN HEAT EXCHANGER AND A PROCESS FOR COOLING A TUBE SIDE STREAM

A process for cooling a tube side stream in a main heat exchanger is described. The process comprises: a) supplying a first mass flow of a tube side stream to a first zone of individual tubes in the tube bundle; b) supplying a second mass flow of the tube side stream to a second zone of individual tubes in the tube bundle, the second zone being offset from the first zone; c) supplying a refrigerant stream on the shell side for cooling the first and second mass flows; d) removing the evaporated refrigerant stream from the warm end of the main heat exchanger; and, e) adjusting the first mass flow of the tube side stream relative to the second mass flow of the tube side stream to maximise the temperature of the removed evaporated refrigerant stream. 1. A process for cooling a tube side stream in a main heat exchanger having a warm end and a cold end , the main heat exchanger comprising a wall defining a shell side within which a coil-wound tube bundle is arranged around a central mandrel , the process comprising the steps of:a) supplying a first mass flow of a tube side stream to the warm end of a first zone of individual tubes in the tube bundle via a first nozzle;b) supplying a second mass flow of the tube side stream to the warm end of a second zone of individual tubes in the tube bundle via a second nozzle, the second zone being offset from the first zone along a radius extending from the central mandrel to the wall of the main heat exchanger;c) supplying a refrigerant stream on the shell side for cooling the first and second mass flows to form an evaporated refrigerant stream;d) removing the evaporated refrigerant stream from the warm end of the main heat exchanger; and,e) adjusting the first mass flow of the tube side stream relative to the second mass flow of the tube side stream to maximise the temperature of the evaporated refrigerant stream removed in step d).2. The process of wherein step e) comprises equalising the temperature of the first mass flow of the ...

HEAT EXCHANGER WITH ACCESSIBLE CORE

In at least some implementations, a heat exchanger includes a core and a shell. The core may have a periphery and a plurality of plates with a plurality of passages interleaved therebetween, a portion of the passages extending and open to the periphery of the core. The shell includes a plurality of panels releasably connected together to define a pressure vessel in which the core is received in assembly, and the shell is adapted to be at least partially disassembled to provided access to the core and enable cleaning of the passages and the plates, or to enable repair or replacement of the core. The shell also is adapted to be reassembled into a pressure vessel with the core inside for further use of the heat exchanger. 1. A heat exchanger , comprising:a core having a periphery and a plurality of plates with a plurality of passages interleaved therebetween, a portion of the passages extending and open to the periphery of the core; anda shell including a plurality of panels releasably connected together to define a pressure vessel in which the core is received in assembly, the shell being adapted to be at least partially disassembled to provided access to the core and enable cleaning of the passages and the plates, or to enable repair or replacement of the core, and the shell being adapted to be reassembled into a pressure vessel with the core inside for further use of the heat exchanger.2. The heat exchanger of wherein the panels are connected to another component by removable fasteners.3. The heat exchanger of wherein the shell also includes a plurality of posts coupled to the core and at least some of the panels of the shell are connected to the posts.4. The heat exchanger of wherein panels of the shell are connected to the posts and to another panel.5. The heat exchanger of wherein the panels define a generally cylindrical shell and the plates of the heat exchanger are circular and arranged in a stack within the shell.6. The heat exchanger of wherein the panels ...

Heat Exchanger Header and Related Methods and Apparatuses

A heat exchanger (such as a radiator) that provides for a consistent tank-to-header joint location. The header generally includes a drafted wall that is movable adjacent to or within a tank and may include a curved fillet to maintain header alignment.

SEAL FOR SEALING OFF THE GAP BETWEEN A HEAT EXCHANGER AND THE INSIDE WALL OF A GROOVE IN A FLUID CHANNEL

The invention concerns a seal () for sealing off the gap between a heat exchanger () and the inside wall of a groove () in a fluid channel for accommodating said heat exchanger [], the seal () comprising at least one fixing member () for fixing the seal () on at least part of the circumference of the heat exchanger () and at least a first () and second lip () adapted to contact opposite sides () of the groove () to thereby seal off the gap between the heat exchanger () and the fluid channel and to fix said at least part of the circumference of the heat exchanger () inside the groove (). 11715515251535471727117. A seal for sealing off the gap between a heat exchanger () and the inside wall of a groove () in a fluid channel for accommodating said heat exchanger (] , the seal () comprising at least one fixing member ( , ) for fixing the seal () on at least part of the circumference of the heat exchanger () and at least a first () and second lip () adapted to contact opposite sides ( , ) of the groove () to thereby seal off the gap between the heat exchanger () and the fluid channel and to fix said at least part of the circumference of the heat exchanger () inside the groove ().2. The seal according to claim 1 , wherein at least the first lip comprises a flexible material claim 1 , to allow the lip to bend under pressure.3. The seal according to claim 1 , wherein the second lip comprises material with a higher resistance against bending than the first lip.4. The seal according to claim 1 , wherein the seal comprises a first and second fixing member adapted to snap fit a part of the heat exchanger between the two members.5. The seal according to claim 1 , wherein the seal is obtained by means of extrusion.6. The seal according to claim 1 , wherein the seal is obtained by means of injection moulding.7. An assembly claim 1 , comprising:a heat exchanger;a fluid channel for guiding a fluid through said heat exchanger,wherein the fluid channel comprises a groove for receiving ...

HEAT-EXCHANGE ELEMENT SUITABLE FOR A HEAT EXCHANGE BETWEEN FIRST AND SECOND FLUIDS, AN EXCHANGER CORE INCLUDING THE HEAT-EXCHANGE ELEMENT AND A HEAT EXCHANGER INCLUDING THE EXCHANGER CORE

The present invention concerns a heat-exchange element () for a heat exchanger () enabling heat exchange between a first fluid and a second fluid, said heat-exchange element () being designed to guide said first fluid through the inside of said heat-exchange element () and said second fluid around the outside of said heat-exchange element, said heat-exchange element () including at least one first duct () having a first essentially cylindrical wall and a second duct () having a second essentially cylindrical wall, the at least first and second ducts () being connected to one another by a portion of the first wall adjacent to a portion of the second wall. 1. A heat-exchange element for a heat exchanger enabling heat exchange between a first fluid and a second fluid , said heat-exchange element comprising:at least one first duct having a first substantially cylindrical wall; anda second duct having a second substantially cylindrical wall,the heat-exchange element being configured to guide said first fluid through the inside of said heat-exchange element and to guide said second fluid around the outside of said heat-exchange element,the at least first and second ducts being connected to one another by a portion of the first substantially cylindrical wall adjacent to a portion of the second substantially cylindrical wall.2. The heat-exchange element as claimed in claim 1 , in which the heat-exchange element includes a plurality of ducts claim 1 , wherein odd-numbered ducts are positioned on a first level and even-numbered ducts are interconnected between the odd-numbered ducts on a second level.3. The heat-exchange element as claimed in claim 1 , in which the heat-exchange element extends from a first end towards a second end claim 1 , in which the heat-exchange element has at least one undulation between the first end and the second end.4. The heat-exchange element as claimed in claim 1 , in which the first and/or second ducts are of a constant thickness.5. An exchange ...

Cooling device and cooling device manufacturing method

A cooling device includes: a case that includes a supply port for supplying coolant to an interior of the case and a discharge port for discharging coolant at the interior of the case to an exterior of the case; plural fins that each have a plate shape, that are provided an exterior of at separations along their plate thickness direction, and that have coolant flowing between adjacent fins; projecting portions that are respectively formed at the fins, that project out along the plate thickness direction of the fins, and that abut adjacent fins; and restraining members that are respectively inserted through insertion holes respectively formed in the fins, that pierce through the plural fins, and that restrain relative movement between adjacent fins.

Heat exchanger

A heat exchanger has a structure in which a heat exchanger main body through which coolant flows is obliquely installed in a box-shaped enclosure, the heat exchanger main body is constituted by a header pipe and a plurality of heat transfer pipes connected to the header pipe and disposed at predetermined intervals along a surface of a part of the header pipe, the header pipe has an area adjacent to an inner surface of the enclosure, and a seal section is provided between the inner surface of the enclosure and the area of the header pipe adjacent to the enclosure.

SEAL STRUCTURE FOR TANK

In order to improve sealing performance when the open end of a tank is swaged and thereby secured inside an annular groove the surface of which is formed in a substantially rectangular shape with a seal material between the groove an the tank, flange parts protrude in a fan shape at the four corners of the seal material, and those flange parts are pressed by the corner sections of the annular groove, thereby preventing the seal material from moving in the corner sections. 1. A seal structure for a tank comprising:a core formed from a lamination of a plurality of flat tubes where a cross section of an outer periphery at an end part is formed into a rectangular shape;a casing fitted onto the outer periphery of the core, having a rectangular opening at the end part;a tank receiver positioned in alignment with an inner periphery of the open end part of the casing, formed in a planar frame shape and crank-shaped in cross section;an annular groove formed between the tank receiver and the casing; anda tank having an end part press fitted inside the annular groove with a seal material, having an outer periphery swaged and thereby secured.2. The seal structure for the tank according to claim 1 , wherein:a plurality of concave parts are arranged in parallel like windows in the outer periphery of the tank, and slits are formed in an outer periphery of the open end part of the casing at predetermined intervals wherein the open end sides are pressed from the slits of the casing to the concave parts in parallel; and whereinthe outer periphery of the tank is swaged and thereby secured.3. The seal structure for the tank according to claim 1 , wherein:the annular groove has corner sections each being made wider than other parts, and curved to have an arc shape at four corners each having a substantially rectangular shape; a pair of short-side parts,', 'a pair of long-side parts in parallel with each other, base parts circular in cross section, formed at the four corners, and', ' ...

HEAT EXCHANGER FOR AN EGR SYSTEM

The invention relates to a heat exchanger for an EGR (Exhaust Gas Recirculation) system, comprising a tube bundle of flat tubes, configured by combining two plates incorporating specific protrusions distributed according to the direction of the tube. These protrusions in both plates are in contact with one another or attached such that they establish internal channels. The present invention is characterized by the presence of either transverse projections or of transverse deviations generating disturbances in the flow through side walls of the internal channels, increasing the turbulence of the flow through said channels and thereby increasing heat exchange by convection. 2213212216213. The heat exchanger according to claim 1 , wherein the second protrusions (..) of the at least one tube (.) of the tube bundle () forming the channels (..) are distributed longitudinally in both plates claim 1 , and wherein said second protrusions (..) are complementary.32132131. The heat exchanger according to claim 1 , wherein the second protrusions (..) comprise projections (...) on both sides of the longitudinal direction (X-X′) arranged symmetrically.42132131. The heat exchanger according to claim 1 , wherein the second protrusions (..) comprise projections (...) on both sides that are offset according to the longitudinal direction (X-X′).5213214216. The heat exchanger according to claim 1 , wherein the second protrusions (..) have windows (..) for compensating for the pressure between channels (..).6213. The heat exchanger according to claim 1 , wherein the second protrusions (..) are longitudinal segments with an end in the form of a transverse projection alternating on both sides of the longitudinal direction (X-X′).7213. The heat exchanger according to claim 1 , wherein the second protrusions (..) are longitudinal segments with an end in the form of a transverse projection located on one side of the longitudinal direction (X-X′).8213. The heat exchanger according to claim 7 , ...

Air-cooling system for fluidic machine

An air-cooling system for fluidic machine includes a base frame, a first intercooler arranged above the base frame and in which a fluid for heat exchange flows, an oil cooler arranged adjacent to the first intercooler and in which oil flows, a second intercooler arranged above the base frame to face one of the first intercooler and the oil cooler and in which the fluid for heat exchange flows, an aftercooler arranged adjacent to the second intercooler to face the other of the first intercooler and the oil cooler and in which the fluid for heat exchange flows, and a blower supplying cooling air to a space between the first intercooler and the oil cooler, and the second intercooler and the aftercooler.

Transcritical air conditioning circuit with integrated expansion vessel

Air conditioning device ( 1 ) with transcritical operating cycle, the device comprising a circuit ( 4 ) conveying a refrigerant ( 5 ) and successively connecting: the outlet ( 6 ) of a compressor ( 7 ); a gas cooler ( 8 ); the cold circuit ( 9 ) of an intermediate cooler ( 10 ); an expansion valve ( 11 ); a second exchanger ( 12 ) having a volume ( 31, 71 ) for the circulation of a coolant ( 21 ) in a heat-exchange relationship with the refrigerant ( 5 ); the inlet ( 13 ) of the hot circuit ( 14 ) of the intermediate cooler ( 10 ); the air conditioning device ( 1 ) being characterized in that the second exchanger of type ( 12 ) comprises an expansion volume for the coolant ( 21 ).

Heating device

A device for heating a flowing medium (e.g., water), wherein the device comprises a heating module and a heat exchanger enclosed by an insulating material comprising a vacuum-packed core material. The heating module and the heat exchanger may further be received in a housing having a number of walls, wherein the vacuum-packed core material is arranged between one of the walls and the heating module and/or the heat exchanger.

HIGH PRESSURE CAPABLE LIQUID TO REFRIGERANT HEAT EXCHANGER

A liquid to refrigerant heat exchanger includes an enclosed coolant volume that is at least partially defined by a plastic housing and by a metal closure plate. The metal closure plate can be part of a brazed assembly containing a continuous refrigerant flow path. The refrigerant flow path is disposed within the coolant volume, where heat can be transferred between the refrigerant within the refrigerant flow path and the liquid within the coolant volume. The plastic housing can at least partially surround the refrigerant flow path to at least partially bound a liquid flow path along a portion of the coolant volume. An inlet diffuser and an outlet diffuser can be mounted to the housing to direct the liquid through the housing. The plastic housing is sealingly joined to the closure plate along an outer periphery of the closure plate. 1. A liquid to refrigerant heat exchanger comprising:a housing comprising a core opening, a first side opening, a second side opening, and a core cavity;a core disposed within the housing, the core comprising, a plurality of tubes and a plurality of fins;an inlet manifold connected to an inlet end of each of the plurality of tubes;an outlet manifold connected to an outlet end of each of the plurality of tubes;a closure plate joined to the inlet manifold and the outlet manifold;a first diffuser extending at least partially through the first side opening; anda second diffuser extending at least partially through the second side opening;wherein the housing and the closure plate define a coolant volume of the heat exchanger, andwherein the closure plate seals the coolant volume at the core opening and along an outer periphery of the closure plate.2. The liquid to refrigerant heat exchanger of claim 1 , wherein at least a portion of the inlet manifold is located within the coolant volume claim 1 , wherein at least a portion of the outlet manifold is located within the coolant volume; and wherein at least a portion of the inlet manifold and at ...

RECEPTACLE ASSEMBLY AND THERMAL-TRANSFER ASSEMBLY

Receptacle assembly includes a receptacle cage and a thermal-transfer module that is coupled to a thermal side of the receptacle cage. The thermal-transfer module has a base portion and a plurality of heat-transfer fins coupled to the base portion. The thermal-transfer module is configured to absorb thermal energy from a pluggable transceiver in the receptacle cage and transfer the thermal energy through the base portion and to the heat-transfer fins. The receptacle assembly also includes a retention clip configured to hold the thermal-transfer module to the receptacle cage. The retention clip includes a resilient beam that extends across the thermal-transfer module. The resilient beam directly engages at least some of the heat-transfer fins and applies a resilient force against the heat-transfer fins. 1. A receptacle assembly comprising:a receptacle cage having a front end and a receiving cavity that opens to the front end, the receiving cavity being sized and shaped to receive a pluggable transceiver;a thermal-transfer module being coupled to a side of the receptacle cage, the thermal-transfer module having a base portion and a plurality of heat-transfer fins coupled to the base portion, the thermal-transfer module configured to absorb thermal energy from the pluggable transceiver and transfer the thermal energy through the base portion and to the heat-transfer fins, the heat-transfer fins having corresponding fin heights that extend between the base portion and a corresponding distal surface; anda retention clip configured to hold the thermal-transfer module to the receptacle cage, the retention clip including a resilient beam that extends across the thermal-transfer module, the resilient beam directly engaging at least some of the heat-transfer fins and applying a resilient force against the heat-transfer fins in a direction from the distal surfaces to the receptacle cage.2. The receptacle assembly of claim 1 , wherein the heat-transfer fins have respective ...

Heat exchanger for a motor vehicle

The invention relates to a heat exchanger ( 1 ) for the exchange of heat between a first and a second fluid, notably for supplying air to a motor vehicle combustion engine, comprising at least one heat exchange core bundle ( 5 ) through which the first fluid passes and a casing ( 7 ) in which said heat exchange core bundle ( 5 ) is housed so that the second fluid can pass through it, said heat exchanger ( 1 ) comprising at least one seal ( 9 ) placed between said heat exchange core bundle ( 5 ) and said casing ( 7 ) so as to limit the extent to which the second fluid can bypass the core bundle ( 5 ).

EGR COOLER FOR VEHICLE

An exhaust gas recirculation (EGR) cooler for a vehicle may include an intake pipe through which EGR gas flows; a core unit having an inlet connected to the intake pipe and may have a plurality of channels into which EGR gas flows through the intake pipe; a cooler housing that covers the core unit and through which cooling water flows to cool the cover unit; and a water jacket that covers the intake pipe, is connected to the cooler housing, and through which the cooling water flows to cool the intake pipe. 1. An exhaust gas recirculation (EGR) cooler for a vehicle , the EGR cooler comprising:an intake pipe through which EGR gas flows;a core unit having an inlet connected to the intake pipe and having a plurality of channels into which EGR gas flows through the intake pipe;a cooler housing that covers the core unit and through which cooling water flows to cool a cover unit; anda water jacket that covers the intake pipe and is connected to the cooler housing, and through which the cooling water flows to cool the intake pipe.2. The EGR cooler of claim 1 , wherein the core unit includes aluminum.3. The EGR cooler of claim 1 , wherein a cooling water inlet is formed at the water jacket and the cooler housing receives cooling water from the water jacket.4. The EGR cooler of claim 3 , wherein the cooling water inlet is positioned to face an inlet of the intake pipe such that cooling water is discharged toward the inlet of the intake pipe.5. The EGR cooler of claim 1 , wherein a plurality of heat dissipation fins having lengths extending in a flow direction of the EGR gas is positioned in the intake pipe.6. The EGR cooler of claim 5 , wherein the heat dissipation fins are arranged perpendicular to the flow direction of the EGR gas and a distance between the heat dissipation fins decreases moving toward the core unit so that a flow cross-sectional area of the EGR gas decreases.7. The EGR cooler of claim 6 , wherein a thickness of the heat dissipation fins increases moving ...

HEAT EXCHANGER

A heat exchanger includes a duct, a stacked core, and a coupling plate. The duct includes a first plate that is disposed to face at least one of end faces of the stacked core in a core width direction, and a second plate that is disposed to face at least one of the end faces of the stacked core in a tube stacking direction. The second plate includes a second-plate end plate portion disposed to face the end face of the stacked core in the core width direction and brazed to a wall surface of the first plate, a second-plate center plate portion that is disposed to face the end face of the stacked core in the tube stacking direction, and a flange portion that extends in the tube stacking direction and is brazed to a bottom wall surface of a groove portion of the coupling plate. 1. A heat exchanger , comprising:a duct including at least two plates combined into a cylindrical shape, a first fluid flow channel provided inside the duct through which a first fluid passes, an inflow port for the first fluid on one end of the first fluid flow channel, and an outflow port for the first fluid on another end of the first fluid flow channel;a stacked core that is accommodated in the duct and includes a plurality of tubes having flat shapes and being stacked, a second fluid flow channel provided inside each of the plurality of tubes through which a second fluid passes, and outer fins arranged between adjacent tubes of the plurality of tubes, the tubes and the outer fins being brazed to each other; anda coupling plate that is brazed to the duct and has a groove portion defining a peripheral edge of the inflow port or the outflow port, whereina direction intersecting with a tube stacking direction and a first fluid flow direction is defined as a core width direction,the duct includes a first plate disposed to face at least one of end faces of the stacked core in the core width direction, and a second plate disposed to face at least one of end faces of the stacked core in the tube ...

Heat exchanger and heat exchange device

A heat exchanger including a tubular core case, a pair of end plates for closing opposite ends of the core case, and a plurality of heat exchange tubes supported at opposite ends thereof by the end plates and allowing flow of a first heating medium inside thereof. One end plate is disposed on an upstream side of the first heating medium as an upstream end plate while the other end plates is disposed on a downstream side of the first heating medium as a downstream end plate. The downstream end plate comprises a downstream bottom surface part for supporting downstream end parts of the heat exchange tubes, and a downstream wall part formed integrally with and rising from a peripheral edge of the downstream bottom surface part, and a top end part of the downstream wall part is oriented toward upstream of the flow of the first heating medium.

PROCESS FOR PRODUCING A PLATE HEAT EXCHANGER AND PLATE HEAT EXCHANGER

A plate heat exchanger has two metal plates brought into abutment, with a solder material between the plates. The plates are heated up to a first temperature. The plates are placed into a mold, the mold surfaces of which have cavities for envisaged channel structures. Channel structures are formed by local internal pressure forming of at least one plate under pressurization by the tool. The plates are heated up to a second temperature. The plates are solder bonded at the abutted surfaces. A plate heat exchanger has two metal plates, wherein channel structures have been formed in at least one plate and the plates are bonded to one another by soldering away from the channel structures. Eutectic microstructures having a longest extent of less than 50 micrometers are formed in the solder layer. 1. Process for producing a plate heat exchanger having the following steps:providing two plates of a metallic material, wherein the plates are brought into abutment with a solder material disposed between the plates,heating the plates to a first temperature,inserting the plates into a mold having mold surfaces that have cavities for envisaged channel structures,forming channel structures by local internal pressure forming of at least one plate under pressurization by the mold,heating the plates to a second temperature,solder bonding of the plates in the abutted areas.2. Process according to claim 1 , wherein the mold is heatable and the heating to the first temperature is effected in the mold.3. Process according to claim 1 , wherein the solder bonding of the plates is likewise effected in the mold under pressurization by the mold.4. Process according to claim 2 , wherein the mold is preheated claim 2 , especially to a temperature of 550° C. to 700° C. claim 2 , preferably to a temperature of 600° C. to 650° C. claim 2 , more preferably to a temperature of 615° C. to 625° C.5. Process according to claim 1 , wherein the first temperature is 200° C. to 550° C. claim 1 , preferably ...

Heat Exchanging Apparatus

A case of a heat exchanging apparatus includes an opening section provided on the sidewall and a plate-like lid member for opening and closing the opening section. A heat exchange section of a heat transfer medium circulation pipe is fixed to the inner surface of a lid member via a frame body formed by combining bar-like members. When the lid member is at a position where the opening section is closed, the heat exchange section of the heat transfer medium circulation pipe is housed fixedly in the case, and when the lid member is at a position where the opening section is open, the heat exchange section of the heat transfer medium circulation pipe is withdrawn from the opening section out of the case. This can reduce labor for cleaning and maintenance of the apparatus effectively and improve efficiency of heat exchange of the apparatus. 1. A heat exchanging apparatus comprising:a boxy case open upward; anda heat exchange unit having a heat transfer medium circulation pipe installed at least in part in the case,wherein the heat exchanging apparatus performs heat exchange between heated fluid guided into the case and heat transfer medium circulating in the heat transfer medium circulation pipe,wherein the heat exchanging apparatus is a falling liquid film type for exchanging heat with the heat transfer medium circulating in the heat transfer medium circulation pipe while dropping heated fluid from an opening of the case open upward into the case so as to be distributed and flown down in a liquid film form following an outer surface of the heat transfer medium circulation pipe,wherein the case comprises: an opening section provided on a sidewall of the case; and a plate-like lid member for opening and closing the opening section,wherein the heat transfer medium circulation pipe of the heat exchange unit has a heat exchange section wound in a spiral,wherein the heat exchange section is fixed to an inner surface of the lid member using a frame body formed by combining bar ...

Indirect Gas Cooler

An indirect gas cooler is constructed from stacked pairs of plates with fins arranged in between. The stack is arranged in a housing into which the gas flows, flows through the fins, and leaves the housing again. The gas is in thermal exchange with the liquid that flows in the plate pairs and that is introduced into the plate pairs via at least one inlet and is discharged via at least one outlet. A ventilating member is provided in the stack for discharging entrained gases from the liquid. The ventilating member is formed from aligned plate openings which produce a ventilating duct that is hydraulically connected with a liquid space in the stack. The indirect gas cooler can be used to cool compressed charge air for an internal combustion engine.

STRUCTURALLY INTEGRAL HEAT EXCHANGER WITHIN A PLASTIC HOUSING

A heat exchanger having a core defining a plurality of first fluid flow passages and a plurality of second fluid flow passages arranged in alternating order, and a housing enclosing the core. The housing has a top wall arranged opposite to the top of the core, and a bottom wall arranged opposite to the bottom of the core. A plurality of connecting structures which together provide a rigid connection between the core and the housing, wherein each of the connecting structures provides a connection between the top of the core and the top wall of the housing, or between the bottom of the core and the bottom wall of the housing. Wherein each of the connecting structures has a first connecting element and a second connecting element. The first connecting element is associated with the core and the second connecting element is associated with the housing. 121-. (canceled)22. A heat exchanger comprising:(a) a core defining a plurality of first fluid flow passages and a plurality of second fluid flow passages arranged in alternating order, wherein the core is comprised of metal and has a top and a bottom;(b) a housing enclosing the core, the housing having a top wall arranged opposite to the top of the core, and a bottom wall arranged opposite to the bottom of the core, wherein at least the top wall and the bottom wall of the housing are comprised of plastic;(c) a plurality of connecting structures which together provide a rigid connection between the core and the housing, wherein each of the connecting structures provides a connection between the top of the core and the top wall of the housing, or between the bottom of the core and the bottom wall of the housing;wherein each of the connecting structures comprises a first connecting element and a second connecting element, wherein the first connecting element is associated with the core and the second connecting element is associated with the housing.23. The heat exchanger according to claim 22 , wherein the first and second ...

LIQUID-COOLED HEAT SINK HEAD AND HEAT SINK SYSTEM HAVING THE SAME

A liquid-cooled heat sink head includes a metal substrate, a first cover, and a plurality of heat dissipation fins. The first cover covers the metal substrate to form a heat exchange chamber and includes a first liquid inlet and a liquid outlet to allow a working fluid to flow in the heat exchange chamber. The heat dissipation fins are disposed on the metal substrate, are placed between the first liquid inlet and the liquid outlet, and are arranged sequentially from the first liquid inlet toward the liquid outlet. A liquid passage is disposed between each two adjacent heat dissipation fins. A portion of the heat dissipation fins are connected to the heat exchange portion, and at least one heat dissipation fin includes one opening to communicate with the liquid passages at two sides of the at least one heat dissipation fin. 1. A liquid-cooled heat sink head , including a heat exchange portion for contacting a heating element , the liquid-cooled heat sink head comprising:a metal substrate, the heat exchange portion being disposed thereon;a first cover covering the metal substrate to form a heat exchange chamber, the first cover including a first liquid inlet and a liquid outlet to allow a working fluid to flow in the heat exchange chamber; anda plurality of heat dissipation fins disposed on the metal substrate and in the heat exchange chamber, the heat dissipation fins being disposed between the first liquid inlet and the liquid outlet and arranged sequentially from the first liquid inlet toward the liquid outlet, a liquid passage being disposed between each two adjacent ones of the heat dissipation fins, wherein at least a portion of the heat dissipation fins is connected to the heat exchange portion, at least one heat dissipation fin includes an opening through which the liquid passages at two sides of the at least one heat dissipation fin communicate with each other, and the at least one heat dissipation fin having the opening is disposed close to the first liquid ...

Heat exchanger device

A multilayer heat exchanger device a frame constructed of multiple laminate layers that are bonded together. The device has a first fluid inlet manifold and a first fluid outlet manifold for connection to a supply and a return for the first fluid, the first fluid inlet manifold and the first fluid outlet manifold extending through the laminate layers of the frame; a second fluid inlet manifold and a second fluid outlet manifold for connection to a supply and a return for the second fluid, the second fluid inlet manifold and the second fluid outlet manifold extending through the laminate layers of the frame.

HEAT EXCHANGER ARRANGEMENT

A heat exchanger arrangement having at least a first heat exchanger and having a second heat exchanger, wherein the first heat exchanger has a first heat transfer matrix with a first air intake surface and with a first air outlet surface, and wherein the second heat exchanger has a second heat transfer matrix with a second air intake surface and with a second air outlet surface, wherein the first heat exchanger and the second heat exchanger are arranged adjacent to one another in such a manner that the first air outlet surface is opposite the second air intake surface and the two heat exchangers are arranged one behind the other in a primary direction of airflow, wherein at least one sealing strip is arranged on at least one lateral side region of the two heat exchangers or on both lateral side regions of the heat exchangers. 1. A heat exchanger arrangement comprising:at least a first heat exchanger having a first heat transfer matrix with a first air intake surface and with a first air outlet surface; anda second heat exchanger having a second heat transfer matrix with a second air intake surface and with a second air outlet surface,wherein the first heat exchanger and the second heat exchanger are arranged adjacent to one another such that the first air outlet surface is opposite the second air intake surface and the two heat exchangers are arranged one behind the other in a primary direction of airflow,wherein at least one sealing strip is arranged on at least one lateral side region of the two heat exchangers or on both lateral side regions of the heat exchangers, which strip achieves a lateral sealing between the first heat exchanger and the second heat exchanger,wherein the sealing strip is an injection-molded sealing strip that has an injection-molded hard component on which a soft component is molded.2. The heat exchanger arrangement according to claim 1 , wherein at least one sealing strip is arranged on both lateral side regions of the two heat exchangers ...

END-PIECE & PLATE HEAT EXCHANGER COMPRISING, AND METHOD OF MAKING, SUCH END-PIECE

A method of making an end-piece for a plate heat exchanger, wherein the end-piece includes a frame part having inner and outer portions, and an intermediate portion arranged between the inner and outer portions, with the outer wall surface of the inner portion being arranged to face a first surface of a package of heat transfer plates comprising the plate heat exchanger, and the first surface having a center portion and a peripheral portion encircling the center portion. The method includes extruding the frame part with plural cavities in the intermediate portion of the frame part that extend in the extrusion direction of the frame part and that are parallel to the frame part axis, with outer dimensions of the outer wall surface of the inner portion configured to be at least as large as outer dimensions of the center portion of the first surface heat transfer plate package. 1. A method of making an end-piece for a plate heat exchanger , the end-piece comprising a frame part , which frame part has an inner portion , an outer portion and an intermediate portion arranged between the inner and outer portions , an outer wall surface of the inner portion being arranged to face a first surface of a package of heat transfer plates comprised in the plate heat exchanger , the first surface having a center portion and a peripheral portion encircling the center portion , the method comprising extruding the frame part with a number of cavities comprised in the intermediate portion of the frame part , the cavities extending in an extrusion direction of the frame part , which extrusion direction is parallel to an axis of the frame part , and with outer dimensions of the outer wall surface of the inner portion at least configured to be as large as outer dimensions of the center portion of the first surface of the package of heat transfer plates.2. The method according to claim 1 , wherein the extruding of the frame part comprises extruding the frame part so that the intermediate ...

AIR CONDITIONER

An air conditioner having an improved assembly structure of panels includes a lower panel located at a bottom surface thereof, an upper panel located at an upper surface thereof, front and rear panels located at front and rear surfaces thereof, and side panels to couple the front and rear panels. One side of each of the lower panel and at least one panel is provided with a protrusion and the other side thereof is provided with a coupling groove, so that the lower panel is coupled to at least one of the front panel and the side panels by coupling of the protrusion and the coupling groove. It may be possible to provide an air conditioner capable of reducing the number of fastening members coupled to respective panels and being free from restraint of an installation space. 1. An air conditioner comprising:a lower panel located at a bottom surface of the air conditioner;a front panel and a rear panel located at front and rear surfaces of the air conditioner, respectively; andside panels to couple the front and rear panels,wherein a side of the lower panel is provided with a protrusion and a side of at least one of the front panel, rear panel and side panels is provided with a coupling groove, to couple the lower panel to at least one of the front panel, rear panel and the side panels by coupling of the protrusion and the coupling groove.2. The air conditioner according to claim 1 , wherein first protrusions provided in the lower panel are fitted into first coupling grooves provided in the side panels to couple the lower panel to the side panels.3. The air conditioner according to claim 2 , wherein the first protrusions protrude toward the side panels and the first coupling grooves are provided on inner surfaces of the side panels.4. The air conditioner according to claim 1 , wherein second protrusions provided in the front and rear panels are coupled to second coupling grooves provided in the lower panel.5. The air conditioner according to claim 4 , further comprising: ...

HEAT EXCHANGER AND CORE FOR A HEAT EXCHANGER

A heat exchanger includes a heat exchanger core having two core sections, each core section having coolant flow passages. A mounting bracket is arranged between the core sections, being joined to each core section. A housing for the heat exchanger core includes multiple housing sections joined together to define an air flow path. The mounting bracket is secured between the multiple housing sections. 1. A core for a heat exchanger comprising:a first plurality of plate pairs arranged to form a first stack section, coolant flow passages extending through each plate pair in the first plurality of plate pairs and air flow passages extending between adjacent plate pairs in the first plurality of plate pairs;a second plurality of plate pairs arranged to form a second stack section, coolant flow passages extending through each plate pair in the second plurality of plate pairs and air flow passages extending between adjacent plate pairs in the second plurality of plate pairs; anda mounting bracket arranged between the first stack section and the second stack section, the mounting bracket including a first face joined to a terminal end of the first stack section and a second face opposite the first face joined to a terminal end of the second stack section.2. The core of claim 1 , wherein the first stack section extends over a first height dimension in a stacking direction and the second stack section extends over a second height dimension in a stacking direction claim 1 , the first height dimension being greater than the second height dimension.3. The core of claim 2 , wherein the ratio of the first height dimension to the second height dimension is not greater than four.4. The core of claim 1 , further comprising:first and second fluid manifolds extending through the first stack section, the coolant flow passages of the first plurality of plate pairs providing a fluid connection between the first and second fluid manifolds; andthird and fourth fluid manifolds extending ...

PRIME SURFACE HEAT EXCHANGER WITH CONTOURED SEPARATOR MEMBERS

A heat exchanger includes a plurality of interconnected separator members that respectively include a first surface and an opposite second surface. The separator members respectively include an array of wave features. Also, the separator members are stacked and disposed in an alternating arrangement with the first surfaces of adjacent separator members facing each other and attached at the respective wave features, and with the second surfaces of adjacent separator members facing each other and attached at the respective wave features. The heat exchanger also includes a plurality of first flow passages for first fluid flow and second flow passages for second fluid flow. The second fluid and the first fluid are configured to exchange heat through the separator members. 1. A method of manufacturing a heat exchanger for a first fluid and a second fluid , the method comprising:forming a plurality of interconnected separator members, the separator members respectively including a first surface and an opposite second surface;forming an array of wave features of the plurality of separator members, the wave features making the first surface and the second surface uneven and making the first surface inverse to the second surface;arranging the separator members in an alternating arrangement with the first surfaces of adjacent separator members facing each other and attached at the respective wave features, and with the second surfaces of adjacent separator members facing each other and attached at the respective wave features;defining a plurality of first flow passages between respective first surfaces of the separator members, the first flow passages configured to direct flow of the first fluid therethrough; anddefining a plurality of second flow passages between respective second surfaces of the separator member, the second flow passages configured to direct flow of the second fluid therethrough, the second fluid and the first fluid being configured to exchange heat through ...

Sterile Apparatus for Rapid Cooling of Hot Water

An apparatus for cooling liquids comprises an external tank and several internal cooling flasks. The external tank is shaped like a closed tank with a top opening. The internal cooling flasks are designed to be set inside the external tank in such a way that very narrow spaces are formed between the external walls of each cooling flask and the adjacent flasks, thus forming an internal cooling space, in a way that enables the user to pour of hot water into the internal cooling space, and the coolant in the cooling flasks adsorbs the heat of said hot water. 1. An apparatus for cooling liquids, comprising: an external tank and at least three internal cooling flasks;wherein the external tank is shaped like a closed container with a top opening;wherein said internal flasks are similar to each other in their structure; wherein said internal flasks have two longitudinal walls and two lateral walls; wherein said internal flasks are designed to contain coolant material;wherein said internal recesses constitute a means for fixing said cooling flasks inside of said external tank; wherein said lateral walls of said internal cooling flasks constitute a means for fixing said cooling flasks inside of said external tank;wherein the internal cooling flasks are designed to be set within the external tank in such a way that very narrow spaces are formed between the external walls of each cooling flask and the adjacent flasks, creating an internal cooling space; wherein a user may pour hot water into said internal cooling space and the coolant material within said internal cooling flasks will adsorb heat from said hot water.wherein said external tank has two longitudinal walls and two lateral walls; wherein each said longitudinal wall of said external tank has internal recesses; wherein said internal recesses match the size of said lateral walls of said internal cooling flasks; The present invention refers to a sterile apparatus for the rapid cooling of hot water.It is often necessary ...

OUTDOOR UNIT OF AIR CONDITIONER

A limiter is connected to an accumulator leg near a first header collection pipe in an outdoor unit. The limiter extends from the accumulator leg toward the first header collection pipe to limit movement of the first header collection pipe. 1. An outdoor unit of an air conditioner , the outdoor unit comprising:a casing;a heat exchanger including two header collection pipes standing in the casing, a plurality of flat pipes arranged in a vertical direction between the two header collection pipes, each of which is inserted in one of the header collection pipes at one end, and is inserted in the other header collection pipe at the other end, and a plurality of fins joined to the flat pipes;a support provided on a bottom plate of the casing to support one of the header collection pipes from below; anda limiter extending from a part near the one of the header collection pipes toward the one of the header collection pipes to limit movement of the one of the header collection pipes.2. The outdoor unit of the air conditioner of claim 1 , whereinan insulating externally contacting part is provided to externally contacts the one of the header collection pipes, andthe limiter limits the movement of the one of the header collection pipes through the externally contacting part.3. The outdoor unit of the air conditioner of claim 2 , whereinthe limiter is in surface contact with the externally contacting part to limit the movement of the one of the header collection pipes.4. The outdoor unit of the air conditioner of claim 2 , whereinthe support is insulative, and supports the one of the header collection pipes from below with a top surface of the support in contact with a lower surface of the one of the header collection pipes, andthe externally contacting part is formed continuously with the support, and protrudes upward from the top surface of the support to externally contact the one of the header collection pipes.5. The outdoor unit of the air conditioner of claim 1 , ...

ENCLOSED HEAT SINK WITH SIDE WALL STRUCTURE

An enclosed heat sink with a side wall structure is provided. The side wall structure includes a welding body having a first welding plane and a side wall structure having a second welding plane. The first welding plane and the second welding plane are pressured and welded to each other, such that the welding body and the side wall structure encapsulate a cavity. A width of the second welding plane is smaller than a width between two side surfaces of the side wall structure. 1. An enclosed heat sink with a side wall structure , comprising:a welding body having a first welding plane; anda side wall structure having a second welding plane, and the first welding plane and the second welding plane being pressured and welded to each other, such that the welding body and the side wall structure encapsulate a cavity;wherein a width of the second welding plane is smaller than a width between two side surfaces of the side wall structure.2. The enclosed heat sink according to claim 1 , wherein the first welding plane and the second welding plane are pressured and welded to each other through a pre-disposed solder.3. The enclosed heat sink according to claim 2 , wherein the solder is one of a welding rod claim 2 , a solder lug claim 2 , a solder paste claim 2 , or a composite material.4. The side wall structure according to claim 2 , wherein the solder is a solder preform coated with soldering flux.5. The enclosed heat sink according to claim 1 , wherein the two side surfaces of the side wall structure converge toward the second welding plane to form two inclined wall surfaces.6. The enclosed heat sink according to claim 5 , wherein a ratio of a width of the inclined wall surfaces to a height between the inclined wall surfaces and the first welding plane is 3:1.7. The enclosed heat sink according to claim 1 , wherein a vertical plane is formed between the second welding plane and each of the two side surfaces of the side wall structure.8. The enclosed heat sink according to ...

HEAT EXCHANGER ASSEMBLY

A heat exchanger assembly includes a shell, a first inlet duct, and a second inlet duct. The shell has a core that is provided with a plurality of first fluid channels and a plurality of second fluid channels. The first inlet duct has a plurality of first feed channels extending towards and fluidly connected to the plurality of first fluid channels. The second inlet duct has a plurality of second feed channels extending towards and fluidly connected to the plurality of second fluid channels. The plurality of first feed channels are interwoven with the plurality of second feed channels proximate an intersection region between the first inlet duct and the second inlet duct. 1. A heat exchanger assembly , comprising:a shell having a core disposed therein, the core being provided with a plurality of first fluid channels and a plurality of second fluid channels;a plurality of first feed channels extending towards and fluidly connected to the plurality of first fluid channels; anda plurality of second feed channels extending towards and fluidly connected to the plurality of second fluid channels, the plurality of first feed channels being interwoven with the plurality of second feed channels.2. The heat exchanger assembly of claim 1 , wherein the plurality of first feed channels and the plurality of second feed channels are interwoven in an alternating arrangement.3. The heat exchanger assembly of claim 1 , wherein a first feed channel of the plurality of first feed channels that is disposed adjacent to a second feed channel of the plurality of second feed channels share a common wall.4. The heat exchanger assembly of claim 3 , wherein the common wall segregates a first fluid flow within the first feed channel from a second fluid flow within the second feed channel.5. The heat exchanger assembly of claim 1 , wherein the shell is at least one of a spherical shell and an elliptical shell.6. The heat exchanger assembly of claim 1 , wherein the plurality of first feed ...

HEAT EXCHANGER

Provided is a heat exchanger including a core portion configured to include an inlet header tank and an outlet header tank having a space, in which cooling water is stored and flows, formed therein and formed in a height direction, a plurality of tubes having both ends connected to the header tanks to form a cooling water channel, and fins interposed between the tubes, in which a core portion of the heater exchanger is formed to block only a part of a bypass area of a part where inlet/outlet header tanks are positioned to reduce a pressure loss of air which is a cooled fluid while minimizing a reduction in heat radiation performance of the heat exchanger and structural rigidity of the core portion is increased by a reinforcing structure formed at an outer side of the core portion to improve durability. 1. A heat exchanger , comprising:a core portion configured to include an inlet header tank and an outlet header tank having a space, in which cooling water is stored and flows, formed therein and formed in a height direction, a plurality of tubes having both ends connected to the header tanks to form a cooling water channel, and fins interposed between the tubes;a side reinforcing plate configured to be disposed on a side surface of the core portion in a longitudinal direction and joined to the tubes of the core portion; anda blocking plate configured to extend in from the side reinforcing plate in a longitudinal direction to block an air inflow side of the core portion corresponding to a bypass area B where the header tanks and are formed,wherein the blocking plate is formed to block only a part in a longitudinal direction of an area where the header tanks and are formed.2. The heat exchanger of claim 1 , further comprising: a blocking plate configured to extend in the longitudinal direction from the side reinforcing plate to block an air discharge side of the core portion corresponding to the bypass areas B where the header tanks and are formed and block only the ...

EXHAUST GAS RECIRCULATION COOLER WITH DAMPING RODS

An Exhaust Gas Recirculation (EGR) cooler assembly and an EGR cooler conduit assembly are provided. Heat exchange tubes in EGR cooler assemblies may vibrate and contact the EGR cooler shell, thereby leading to the tube fretting and potentially failing. The current disclosure is directed to the use of damping rods to absorb vibratory impacts and reduce or eliminate tube fretting. 1. An EGR cooler assembly comprising:a first member and a second member, said first member and said second member each having a leading surface opposite a trailing surface;a plurality of cooling tubes disposed between the trailing surface of the first member and the leading surface of the second member;a shell configured to be disposed around the plurality of cooling tubes; andat least one damping rod positioned between the shell and the plurality of cooling tubes, and said at least one damping rod having a hardness less than a material used to make the shell or the plurality of cooling tubes.2. The EGR cooler assembly of claim 1 , wherein the at least one damping rod has a first end configured to attach to the leading surface of the first member and a second end configured to attach to the second member.3. The EGR cooler assembly of wherein a space is defined between the shell and the plurality of cooling tubes and the at least one damping rod is sized to be disposed within the space without contacting the shell or the plurality of cooling tubes.4. The EGR cooler assembly of claim 1 , wherein the at least one damping rod is configured to have a first end and a second end attached to the shell.5. The EGR cooler assembly of claim 2 , wherein the at least one damping rod is linear.6. The EGR cooler assembly of claim 2 , wherein the at least one damping rod is non-linear.7. The EGR cooler assembly of claim 5 , wherein the at least one damping rod is connected to an inner surface of the shell.8. The EGR cooler assembly of having at least two damping rods claim 1 , a first damping rod disposed ...

Heat exchanger constructive arrangement

A heat exchanger constructive arrangement including a quadrangular based vertical vessel with inlet and output ducts and removable lid having heat exchange elements supported by parallel plates and vertically arranged in the form of a comb that interleave with existing baffles in the container, forming a chicane which forces the fluid to be heated to maintain contact with the entire surface of heat exchange.

MAIN HEAT EXCHANGER AND A PROCESS FOR COOLING A TUBE SIDE STREAM

A process for cooling a tube side stream in a main heat exchanger is described. The process comprises: a) supplying a first mass flow of a tube side stream to a first zone of individual tubes in the tube bundle; b) supplying a second mass flow of the tube side stream to a second zone of individual tubes in the tube bundle, the second zone being offset from the first zone; c) supplying a refrigerant stream on the shell side for cooling the first and second mass flows; d) removing the evaporated refrigerant stream from the warm end of the main heat exchanger; and, e) adjusting the first mass flow of the tube side stream relative to the second mass flow of the tube side stream to maximise the temperature of the removed evaporated refrigerant stream. 1. A process for cooling a tube side stream in a main heat exchanger having a warm end and a cold end , the main heat exchanger comprising a wall defining a shell side within which a coil-wound tube bundle is arranged around a central mandrel , the process comprising the steps of:a) supplying a first mass flow of a tube side stream to the warm end of a first zone of individual tubes in the tube bundle via a first nozzle;b) supplying a second mass flow of the tube side stream to the warm end of a second zone of individual tubes in the tube bundle via a second nozzle, the second zone being offset from the first zone along a radius extending from the central mandrel to the wall of the main heat exchanger;c) supplying a refrigerant stream on the shell side for cooling the first and second mass flows to form an evaporated refrigerant stream;d) removing the evaporated refrigerant stream from the warm end of the main heat exchanger; and,e) adjusting the first mass flow of the tube side stream relative to the second mass flow of the tube side stream to maximise the temperature of the evaporated refrigerant stream removed in step d)wherein step e) comprises equalizing the temperature of the first mass flow of the tube side stream at ...

Heat exchanger panel and method for mounting thereof to a rack structure

A heat exchanger stack includes a rack structure and heat exchangers disposed above one another and supported thereby. Each heat exchanger includes: a frame; a tubing arrangement configured to circulate fluid therein; a plurality of fins; and a plurality of wheels mounted to the frame for guided mounting of the heat exchanger panel on the rack structure including first and second upper wheels spaced apart from one another and first and second lower wheels spaced apart from one another. Each upper wheel engages a corresponding upper wheel guiding member of the rack structure, and each lower wheel engages a horizontal portion of a corresponding lower wheel guiding member of the rack structure so that the heat exchanger panel is translatable horizontally. A method for mounting a heat exchanger panel to a rack structure is also provided.

SADDLE TYPE VEHICLE

Left and right radiators in a saddle type vehicle are formed in a trapezoidal shape and disposed such that a shorter one of two side portions of each of the radiators which extend in parallel or substantially in parallel to each other as viewed in front elevation is positioned at the inner side in the vehicle widthwise direction. A longer one of the side portions is disposed at the outer side in the vehicle widthwise direction. Forward projections of an exhaust pipe projecting forwardly from an engine pass below the shorter side portions at the inner side in the vehicle widthwise direction of the radiators. 1. A saddle type vehicle , comprising:left and right main frames extending rearwardly from a head pipe;a down frame extending downwardly from the head pipe;an engine disposed below the left and right main frames in a rear of the down frame, and a pair of left and right radiators attached to the down frame; andan exhaust pipe connected to the engine includes left and right forward projections extending forwardly from the engine, passing a left and right of the down frame and being curved downwardly, whereinat least one of the left and right radiators is formed in a trapezoidal shape, and the one of the radiators which is formed in the trapezoidal shape is disposed in a state in which, as viewed in front elevation, a shorter one of two side portions extending in parallel or substantially in parallel to each other is positioned at an inner side in a vehicle widthwise direction, and a longer one of the side portions is disposed at an outer side in the vehicle widthwise direction, and whereinthe forward projection positioned at a same side as the radiator formed in the trapezoidal shape is placed in a state in which the forward projection passes below the shorter side portion at the inner side in the vehicle widthwise direction of the radiator formed in the trapezoidal shape.2. The saddle type vehicle according to claim 1 , wherein a lower end of the radiator is ...

Heat exchanger for flammable refrigerants

A heat exchanger for flammable refrigerants has a housing in which refrigerant lines are situated. The housing is provided with fins on the inside of a closed side face, and at least a portion of the outside of the closed side face can be brought into operative connection with a passenger compartment of a vehicle. The housing is designed as a module which can be partitioned off from the passenger compartment in a gas-tight manner, where only permanently sealed sections of the refrigerant lines are situated in the interior of the housing, the connection points of which refrigerant lines are each situated completely outside the housing. The housing has sealing frame and/or sealing plates such that the connections of the refrigerant lines are sealed off from the passenger compartment and are ventilated outward to the surroundings.

U-SHAPED HOUSING AND COVER CONCEPT FOR PLATE FIN HEAT EXCHANGERS

A housing for a heat exchanger comprising includes a first housing portion having and a second housing portion. The first housing portion has a U-shaped cross-section. The second housing portion cooperates with the first housing portion to define a chamber. The chamber receives a heat exchange assembly. The second housing portion is configured as a plate. 1. A housing for a heat exchanger comprising:a first housing portion having a U-shaped cross-section; anda second housing portion cooperating with the first housing portion to define a chamber receiving a heat exchange assembly, the second housing portion configured as a plate.2. The housing of claim 1 , wherein the first housing portion has a flange extending outwardly from an outer surface of each of opposing ends thereof.3. The housing of claim 2 , wherein the second housing portion has a lip extending outwardly from a surface of each of opposing ends thereof.4. The housing of claim 3 , wherein the flanges of the first housing portion and the lips of the second housing portion cooperate to define a frame configured for coupling to at least one of a header and a tank.5. The housing of claim 4 , wherein a tab extends outwardly from an engagement surface of the frame.6. The housing of claim 1 , wherein the first housing portion and the second housing portion are formed from one of aluminum and plastic.7. The housing of claim 1 , wherein the first housing portion is coupled to the second housing portion by one of a brazing process claim 1 , a welding process claim 1 , and a crimping process.8. A core assembly for a heat exchanger comprising:a two-component housing including a first housing portion and a second housing portion cooperating to define a chamber with a first open end and a second open end; anda heat exchange assembly received in the chamber.9. The core assembly of claim 8 , wherein the heat exchange assembly includes a plurality of plate assemblies interposed between a plurality of fins.10. The core ...

OUTDOOR ELECTRONICS ENCLOSURE WITH DUAL HEAT EXCHANGERS

An electronics cabinet includes: an enclosure having a floor, a ceiling, a rear wall, opposed side walls, and a front wall that define an interior cavity; a divider panel that divides the interior cavity into upper and lower chambers; a first cooling system mounted to the enclosure to cool the upper chamber; and a second cooling system mounted to the enclosure to cool the lower chamber. 1. An electronics cabinet , comprising:an enclosure having a floor, a ceiling, a rear wall, opposed side walls, and a front wall that define an interior cavity;a divider panel that divides the interior cavity into upper and lower chambers;a first cooling system mounted to the enclosure to cool the upper chamber; anda second cooling system mounted to the enclosure to cool the lower chamber.2. The electronics cabinet defined in claim 1 , wherein the front wall comprises a door hingedly attached to one of the side walls.3. The electronics cabinet defined in claim 1 , wherein the first and second cooling systems are first and second heat exchangers.4. The electronics cabinet defined in claim 3 , wherein the first and second heat exchangers are finned heat exchangers.5. The electronics cabinet defined in claim 3 , wherein the first heat exchanger is mounted above the second heat exchanger.6. The electronics cabinet defined in claim 1 , wherein the upper and lower chambers are relatively airtight relative to each other.7. The electronics cabinet defined in claim 1 , further comprising a battery chamber that is separated from the lower chamber by a second divider panel.8. The electronics cabinet defined in claim 1 , further comprising a controller operatively connected to the first and second cooling systems.9. An electronics cabinet claim 1 , comprising:an enclosure having a floor, a ceiling, a rear wall, opposed side walls, and a door hingedly attached to one of the side walls that define an interior cavity;a divider panel that divides the interior cavity into upper and lower chambers;a ...

Motor vehicle air conditioning unit

A motor vehicle air conditioning unit having a housing, a heat exchanger, at least two manifolds and cooling tubes arranged therebetween forming a tube block, the heat exchanger is sealed with respect to bypass air inexpensively and with little technical effort. The housing has at least one V-shaped sealing rib oriented substantially parallel to an imaginary plane spanned by the tube block and/or one H-shaped sealing rib oriented substantially parallel to an imaginary plane spanned by the tube block for sealing a front and/or rear side of the tube block, and the at least one H-shaped sealing rib is oriented substantially perpendicular to the at least one V-shaped sealing rib.

Header for a Heat Exchanger, and Method of Making the Same

A header for a heat exchanger includes a first and a second cylindrical portion. The first cylindrical portion has a first diameter, and extends over a first length portion of the header. The second cylindrical portion has a second diameter that is smaller than the first diameter, and extends over a second length portion of the header. Tube receiving slots are arranged along the first length portion. An end cap is received into an open end of the first cylindrical portion, and is joined thereto to seal a first end of the header. An open end of the second cylindrical portion is arranged at a second end of the header opposite the first end to allow for fluid flow into or out of the header. A circumferential bead is located between the first and second cylindrical portions, and extends radially outward of the first cylindrical portion. 1. A header for a heat exchanger , comprising:a first cylindrical portion having a first diameter extending over a first length portion of the header;a plurality of tube receiving slots arranged along the first length portion;an end cap received into an opening at an end of the first cylindrical portion and joined thereto to seal a first end of the header;a second cylindrical portion having a second diameter that is smaller than the first diameter, the second cylindrical portion extending over a second length portion of the header coaxial with the first cylindrical portion;an open end of the second cylindrical portion arranged at a second end of the header opposite the first end to allow for fluid flow into or out of the header; anda circumferential bead located between the first and second cylindrical portions and extending radially outward of the first cylindrical portion.2. The header of claim 1 , further comprising a hose bead formed into the second end of the header.3. The header of claim 1 , wherein ends of flat tubes of the heat exchanger are received into the plurality of tube receiving slots and are sealingly joined to the ...

CONNECTION MEMBER FOR COOLANT PASSAGES AND COOLER SYSTEM

A connection member for coolant passages is provided. The connection member includes: a first end portion configured to be connected to the first opening via a shaft seal member; a second end portion configured to be connected to the second opening via a face seal member; a communication portion providing communication between the first end portion and the second end portion; a first fastening portion provided at a position in one direction such that a distance between the first fastening portion and the second end portion is larger than a distance between the first fastening portion and the first end portion; and a second fastening portion provided around the second end portion, and configured to be fastened to the case. 1. A connection member for coolant passages , the coolant passages including a first coolant passage and a second coolant passage , the first coolant passage being provided in a case , the first coolant passage communicating with a first opening provided in the case , and the second coolant passage being provided in the case at a distance in one direction from the first opening , and the second coolant passage communicating with a second opening , the connection member comprising:a first end portion configured to be connected to the first opening via a shaft seal member, the first end portion having a tubular shape;a second end portion configured to be connected to the second opening via a face seal member, the second end portion having a tubular shape;a communication portion that provides communication between the first end portion and the second end portion;a first fastening portion provided at a position in the one direction such that a distance between the first fastening portion and the second end portion being larger than a distance between the first fastening portion and the first end portion, the first fastening portion being configured to be fastened to the case; anda second fastening portion provided around the second end portion, the ...

Heat exchanger for low temperatures

Heat exchanger for low temperatures. The heat exchanger comprises a body, a tube pack fitted inside the body for circulating a heat-transfer medium in the heat exchanger, connections for leading the heat-transfer medium to the tube pack, and from the tube pack, and connections for leading the heat-transfer medium into the body and out of the body. According to the invention, the heat exchanger's body is manufactured from planar profile sheet. An opening is fitted to at least one long side of the body, and is dimensioned to be large enough for the tube pack forming at least one circuit of the heat exchanger to be fitted inside the body through the opening, so that the tube pack can be easily lifted out from inside the body for the replacement of individual tubes or tube rows. A cover is arranged to cover the opening. 2. The heat exchanger according to claim 1 ,wherein the tube pack is formed of tube profiles, which are made from plastic material.3. The heat exchanger according to claim 1 , wherein the body and tube profiles are made from polyolefins claim 1 , such as polyethylene or polypropylene or a combination of these.4. The heat exchanger according to claim 1 , wherein the cover is openable.5. The heat exchanger according to claim 1 , wherein the body of the heat exchanger is made from planar cavity-profile sheet.6. The heat exchanger according to claim 5 , wherein the cavities of the cavity-profile sheet are filled at least partly with a filler claim 5 , for example claim 5 , a thermally insulating substance or a substance that is heavier than water.7. The heat exchanger according to claim 1 , wherein there are protrusions on the surface of the profiles of the tubes of at least one tube pack.8. The heat exchanger according to claim 1 , wherein the inner surface of the tubes of the tube pack is smooth.9. The heat exchanger according to claim 1 , wherein at least the inner surface of the tubes of the tube pack is surfaced or mixed with a substance that prevents ...

PROCESS FOR PRODUCING A PLATE HEAT EXCHANGER AND PLATE HEAT EXCHANGER

A plate heat exchanger has two metal plates brought into abutment, with a solder material between the plates. The plates are heated up to a first temperature. The plates are placed into a mold, the mold surfaces of which have cavities for envisaged channel structures. Channel structures are formed by local internal pressure forming of at least one plate under pressurization by the tool. The plates are heated up to a second temperature. The plates are solder bonded at the abuted surfaces. A plate heat exchanger has two metal plates, wherein channel structures have been formed in at least one plate and the plates are bonded to one another by soldering away from the channel structures. Eutectic microstructures having a longest extent of less than 50 micrometers are formed in the solder layer. 1. A plate heat exchanger , comprising two metal plates , whereinat least one of the plates has channel structures,the plates are joined to one another by a solder layer away from the channel structures, andthe solder layer comprises eutectic microstructures having a longest dimension of less than 50 micrometers.2. The plate heat exchanger according to claim 1 , wherein the eutectic microstructures are formed in solder accumulations in a transition region from abutted areas of the plates to the channel structures.3. The plate heat exchanger according to claim 1 , wherein one of the plates is a base plate claim 1 , and the other plate is a forming plate.4. The plate heat exchanger according to claim 3 , wherein the forming plate comprises the channel structures.5. The plate heat exchanger according to claim 1 , wherein the plates comprise an aluminum alloy.6. The plate heat exchanger according to claim 5 , wherein the aluminum alloy is a high strength aluminum alloy.7. The plate heat exchanger according to claim 1 , wherein at least one of the plates comprises a connection opening.8. The plate heat exchanger according to claim 1 , wherein at least one of the plates comprises a ...

Water-Cooled EGR Cooler

A water-cooled EGR cooler is to be supplied with exhaust gas from an exhaust line and is to re-circulate the cooled exhaust gas to an intake line. A housing has an exhaust inlet, an exhaust outlet, a coolant inlet, and a coolant outlet. A heat exchange member is disposed in the housing and includes exhaust gas passages from the exhaust inlet to the exhaust outlet at a predetermined interval and also includes a coolant passage through which coolant can flow from the coolant inlet to the coolant outlet between the exhaust gas passages. A pipe member includes a bypass passage formed between an upper surface of the heat exchange member and an inside upper surface of the housing to allow the exhaust gas to bypass the heat exchange member and flow between the upper surface of the heat exchange member and the coolant outlet. 1. A water-cooled EGR (exhaust gas recirculation) cooler to be supplied with an exhaust gas from an exhaust line and to re-circulate the cooled exhaust gas to an intake line , the water-cooled EGR cooler comprising:a housing having an exhaust inlet at a first end and an exhaust outlet at an opposite second end through which the exhaust gas can pass in and out of the housing, a lower portion of the first end of the housing provided with a coolant inlet and an upper portion of the second end of the housing provided with a coolant outlet;a heat exchange member disposed in the housing, the heat exchange member including exhaust gas passages from the exhaust inlet to the exhaust outlet at a predetermined interval, and also including a coolant passage through which coolant can flow from the coolant inlet to the coolant outlet between the exhaust gas passages; anda pipe member that includes a bypass passage formed between an upper surface of the heat exchange member and an inside upper surface of the housing to allow the exhaust gas to bypass the heat exchange member and flow between the upper surface of the heat exchange member and the coolant outlet.2. The ...

Marine Engine Heat Exchanger

A heat exchanger for a marine engine has a housing with an internal cavity. Twisted tubes snake back and forth inside the cavity and carry a first fluid to cool a second engine cooling fluid flowing through the cavity. Each of the twisted tubes has a plurality of ridges to increase the surface area of the tube exposed to the second fluid. Dividers inside the cavity direct the flow of the second fluid through the cavity. The housing may have a removable cover to access the housing cavity. 1. A heat exchanger for a marine engine , the heat exchanger comprising:a housing shell having a front wall having mounting blocks formed therein, a continuous sidewall having multiple openings and an interior cavity;twisted tubes inside the interior cavity of the housing shell for carrying a first liquid, each of said twisted tubes having a twisted configuration with a tube body and a plurality of hollow, continuous ridges surrounding the tube body and extending outwardly from the tube body to increase a surface area of the twisted tube;dividers inside the interior cavity to direct the flow of a second liquid through the interior cavity;inlet and outlet ports for the first liquid secured to the continuous sidewall of the housing shell, each of the inlet and outlet ports for the first liquid covering one of the openings extending through the continuous sidewall of the housing shell;inlet and outlet ports for the second liquid;a removable housing cover secured to the housing shell; andmounting brackets for securing the heat exchanger to the marine engine with fasteners extending through tabs in the mounting brackets and through the mounting blocks of the front wall of the housing shell, wherein at least one of the dividers is held in place in the interior cavity by at least one threaded fastener extending through the removable cover of the housing, through an opening in the divider and into a boss formed in the front wall of the housing shell.2. The heat exchanger of claim 1 , ...

Radiator

A radiator includes a main body, two connecting members and two taps. The two connecting members are disposed on opposite sides of the main body. Each of the two taps is rotatably connected to one of the two connecting members, such that the two taps are rotatably disposed on opposite sides of the main body.

METHOD FOR PRODUCING A PLATE-SHAPED HEAT EXCHANGER, PLATE-SHAPED HEAT EXCHANGER, AND ASSEMBLY COMPRISING PLATE-SHAPED HEAT EXCHANGERS

Disclosed is a method for producing a plate-shaped heat exchanger for batteries or converters for generating electricity, to a plate-shaped heat exchanger for batteries or converters for generating electricity, and to an assembly of plate-shaped heat exchangers and converter or battery cells. A plate-shaped heat exchanger includes two frame parts, which peripherally surround one profiled heat-conducting element each, wherein the profiles of the profiled heat-conducting elements form channels in the connected state of the frame parts, through which channels a fluid can be conducted. In the connected state, the frame parts form at least two supply channels for feeding and leading away of fluid, from which supply channels openings extend to the channels of the profiled heat-conducting elements. The frame parts have at least one connection for the feeding and leading away of fluid for each supply channel, which connection can be connected to a connection of a frame part of a further heat exchanger. 118-. (canceled)20. The method according to claim 19 , wherein the connecting of the plastics material of the first frame part with the plastics material of the second frame part is carried out by way of welding.21. The method according to claim 19 , wherein the connecting of the profiled thermal conduction elements is carried out by adhesion under applied heat.22. The method according to claim 20 , wherein the welding is carried out by heating plates or infrared radiation welding.23. A plate-shape heat exchanger for batteries or converters for power generation claim 20 , consisting of two interconnected frame parts of plastics material claim 20 , which each surround a profiled thermal conduction element by encircling and which are connected with the profiled thermal conduction elements at the outer circumference thereof claim 20 , wherein the profiles of the profiled thermal conduction elements in the connected state of the frame parts form channels through which a fluid can ...

Manufacturing method for vapor chamber without injection tube and apparatus thereof

A manufacturing method for a vapor chamber without an injection tube and an apparatus thereof, includes the steps of preparing two plates for covering onto each other to form a vapor chamber housing, injecting a working fluid between the two plates, and further preparing a sealed space having a refrigeration device installed therein, and then placing the two plates having the working fluid injected therein onto the refrigeration device, thereby maintaining a temperature of the working fluid below a boiling point under a vacuum state; next, performing evacuation on the sealing space, and then sealing perimeters of the two plates. Consequently, a vapor chamber without any injection tube can be obtained through such manufacturing method.

Baseboard Heater Radiator Cover

A radiator heater cover includes a cover formed of thermoplastic in a shape that fits over at least a portion of a radiator heater. The radiator heater cover defines a plurality of apertures in at least a portion of an outer surface of the cover that are dimensioned and spaced to provide desired convective heat transfer away from predetermined areas of the radiator heater. 125-. (canceled)26. A method of covering an existing radiator heater comprising hot water pipes , the method comprising:a) forming a cover from a thermoplastic material in a shape comprising a front panel, a side flap formed at an angle relative to the front panel, and an angled portion, the angled portion positioned so that the angled portion connects the side flap to the front panel of the cover such that the angled portion forms an obtuse angle with the side flap, wherein a ratio of the area of the front panel to the sum of the areas of the angled portion and the side flap portion is in a range of 0.33 to 2.25 so that the cover provides a desired amount of insulation and convective heat transfer away from the cover;b) forming a plurality of apertures in the angled portion of the cover that provide the desired amount of convective heat transfer away from the cover; andc) mounting the cover over the existing radiator heater comprising hot water pipes such that the cover is proximate to a surface of the existing radiator heater and adjacent to the hot water pipes, wherein the cover provides the desired amount of insulation to the hot water pipes and heat transfer away from the hot water pipes.27. The method of covering an existing radiator heater of wherein the mounting the cover over the existing radiator heater comprising mounting the cover over a baseboard radiator.28. The method of covering over an existing radiator heater of wherein the mounting the cover over the existing radiator heater comprises mounting the cover over a free standing radiator.29. The method of covering an existing ...

HEAT EXCHANGER FOR A POWER GENERATION SYSTEM

The present disclosure relates to heat exchanger for a power generation system and related methods that use supercritical fluids, and in particular to a heat exchanger configured to minimize axial forces during operation. 1. A heat exchanger configured for a power generation system , the heat exchanger:a. at least one plate assembly including a first end, a second end opposed to the first end along an axial direction, each plate assembly including a plurality of plates stacked with respect to each other, the at least one plate assembly defining a first flow configuration and a second flow configuration that is separate from the first flow configuration, the first and second flow configurations extending from the first end to the second end so as to direct first and second fluids, respectively, through the at least one plate assembly; andb. a casing assembly that applies a tension force to the at least one plate assembly along the axial direction, such that, when the at least one plate assembly is exposed to at least predetermined temperature, each plate expands at least partially along the axial direction so as to reduce the tension force applied to the plate assembly.2. The heat exchanger of claim 1 , wherein the at least one plate assembly includes a first platform segment that defines the first end claim 1 , a second platform segment that defines the second end claim 1 , and at least one serpentine segment that extends between the first platform segment and the second platform segment.3. The heat exchanger of claim 2 , wherein the at least one serpentine segment is a first serpentine segment and a second serpentine segment that is separate from the first serpentine segment.4. The heat exchanger of claim 1 , wherein the at least one plate assembly is a first plate assembly and a second plate assembly claim 1 , such that the first and second plate assembly can independently expand along the axial direction when is exposed to at least the predetermined temperature.5 ...

HEAT EXCHANGER WITH ENHANCED END SHEET HEAT TRANSFER

A heat exchanger with increased heat transfer capability is provided. The heat exchanger includes first and second end plates, tubes extending between the first and second end plates and fins disposed between the tubes. The heat exchanger is disposable within and differs in shape from a space defined between first and second walls such that end corners of the first end plate abut the first wall and a point of the second end plate abuts the second wall, the first wall diverges from the end corners of the first end plate to define a first open region and the second wall diverges from the point of the second end plate to define second open regions. At least one of the first end plate and the second end plates includes enhancements fluidly communicative with the at least one corresponding one of the first open region and the second open regions. 1. A heat exchanger with increased heat transfer capability , the heat exchanger comprising:first and second end plates;tubes extending between the first and second end plates; andfins disposed between the tubes,the heat exchanger being disposable within and differing in shape from a space defined between first and second walls such that:end corners of the first end plate abut the first wall and a point of the second end plate abuts the second wall,the first wall diverges from the end corners of the first end plate to define a first open region, andthe second wall diverges from the point of the second end plate to define second open regions, andat least one of the first end plate and the second end plates comprises enhancements fluidly communicative with the at least one corresponding one of the first open region and the second open regions.2. The heat exchanger according to claim 1 , wherein the space is annular and the heat exchanger is rectangular.3. The heat exchanger according to claim 1 , wherein:the first open region is an annular segment, andthe second open regions have an increasing dimension with increasing distance ...

POOL TYPE LIQUID METAL FAST SPECTRUM REACTOR USING A PRINTED CIRCUIT HEAT EXCHANGER CONNECTION TO THE POWER CONVERSION SYSTEM

A printed circuit heat exchanger for use in a reactor includes a core formed from a stack of plates diffusion bonded together. The core has: a top face, a bottom face disposed opposite the top face, a first side face extending between the top face and the bottom face, and a second side face disposed opposite the first side face. The printed circuit heat exchanger includes: a plurality of primary channels defined in the core, each of the primary channels extending from a primary inlet defined in the first side face to a primary outlet defined in the second side face; and a plurality of secondary channels defined in the core, each of the secondary channels extending among at least some of the primary channels from a secondary inlet defined in the top face to a secondary outlet defined in the top face. 113-. (canceled)14. A reactor , comprising:a vessel comprising a lid, wherein the vessel houses a volume of a primary coolant therein, and wherein the volume of the primary coolant defines a maximum level within the vessel;a reactor core disposed in the vessel, wherein the reactor core defines a lower plenum and an upper plenum; a core comprising a stack of plates bonded together, wherein the core comprises a top face, a bottom face, a first side face, and a second side face;', 'a primary channel defined in the core, wherein the primary channel extends from a primary inlet defined in the first side face to a primary outlet defined in the second side face; and', 'a secondary channel defined in the core, wherein the secondary channel extends among the primary channel from a secondary inlet defined in the top face to a secondary outlet defined in the top face., 'a micro-channel heat exchanger at least partially submerged below the maximum level of the primary coolant, wherein the micro-channel heat exchanger comprises15. The reactor of claim 14 , wherein the micro-channel heat exchanger further comprises an inlet plenum in fluid communication with the secondary inlet claim ...

HEAT EXCHANGER FRAME

An external frame for a heat exchanger, the external frame being for holding a heat exchanger core; wherein the external frame is a single integrated structure including: inlet and outlet couplings for connection to a first fluid circuit for supply and return of a first fluid to the heat exchanger core; a first tank at a first end of the external frame for fluid communication with a first end of the heat exchanger core; a second tank at a second end of the external frame for fluid communication with a second end of the heat exchanger core; and a gallery extending along the external frame between the first tank and the second tank providing fluid communication between the first tank and the second tank; wherein the external frame is arranged to be sealed to the heat exchanger core so that the first fluid flows from the inlet, through the heat exchanger core and the tanks, and to the outlet. 1. An external frame for a heat exchanger , the external frame being for holding a heat exchanger core; wherein the external frame is a single integrated structure including:inlet and outlet couplings for connection to a first fluid circuit for supply and return of a first fluid to the heat exchanger core;a first tank at a first end of the external frame for fluid communication with a first end of the heat exchanger core;a second tank at a second end of the external frame for fluid communication with a second end of the heat exchanger core; anda gallery extending along the external frame between the first tank and the second tank providing fluid communication between the first tank and the second tank;wherein the external frame is arranged to be sealed to the heat exchanger core so that the first fluid flows from the inlet, through the heat exchanger core and the tanks, and to the outlet.2. The external frame as claimed in claim 1 , wherein the external frame is arranged to provide a supporting structure for holding the heat exchanger core by encircling the heat exchanger core.3. ...

VEHICLE CONDENSER

A vehicle condenser in which a notch portion of each coupling part of a pair of supports installed at the outermost sides of radiation fins extends so as to have a certain length from the tip of a body part to the inside end of the notch portion, or a through-hole is formed so as to be spaced by a predetermined distance toward the inside of the body part from the tip thereof, thereby preventing the radiation fins from melting when the clad on a header of a header tank is melted during the brazing of the radiation fins and flows along an embossing part, regardless of a method for manufacturing the supports. Consequently, it is possible to reduce the failure rate of the condenser and increase the efficiency of the condenser by maintaining the original state of the radiation fins.

MULTI-DISK HEAT EXCHANGER AND FAN UNIT

Disclosed herein are devices, methods, and systems for heat exchange, comprising one or more multi-disk rotors, one or more finned thermal elements, and a cover, which, even without an external fan, are combined in one apparatus to form a directed movement of fluid and heat exchange. Additional embodiments comprise an additional circulation chamber, integrated with/within said apparatus and/or external fans and/or at least one baffle in a circulation chamber for further directing and intensifying a changing of temperature of fluid passing through the apparatus. A highly efficient heat exchange is achieved by a high temperature gradient near the heat transferring surface and by a high-volume pumping capability of the multi-disk fan. The devices, methods, and systems are particularly applicable in fields that require compactness and low noise levels during operation, such as air conditioning and CPU cooling. 1. A heat exchanging device , comprising:at least one thermal element coupled to a plurality of heat transferring spaced fins, said fins extending into a first area,at least one multi-disk rotor, comprising a plurality of disks fixedly mounted to a shaft, wherein a portion of each disk inserts into said first area and between said fins, said disks rotating around an axis of rotation freely between said fins, anda housing, said housing at least partially encasing said at least one rotor, fins, and at least one thermal element, said housing creating a first opening forming a fluid inlet and a second opening forming a fluid outlet, the combination of the rotor, housing, and openings forming a multi-disk fan,wherein a portion of said disks rotating inside said first area cause a heat exchange to occur between said fins and said rotating disks and/or a fluid moving through said first area,wherein a portion of said disks rotating outside said first area create a flow of fluid into said inlet and out of said outlet, wherein a heat exchange occurs between said rotating ...

Heat exchange unit

A heat exchange unit includes a first heat exchanger and a second heat exchanger. The first heat exchanger has a plurality of first flattened tubes communicating at different heights with an individual space including a flow channel through which refrigerant is spouted upward when installation is in a first attitude. The second heat exchanger has a plurality of second flattened tubes communicating at different heights with an individual space including a flow channel through which refrigerant is spouted upward when installation is in the first attitude. The first heat exchanger is disposed so that refrigerant is spouted upward in a flow channel of the individual space also in the case of installation in a second attitude, and the second heat exchanger is disposed so that refrigerant is spouted upward in a flow channel of the individual space also in the case of installation in the second attitude.

Exhaust heat recovery unit

An exhaust heat recovery unit, includes: a heat exchanger that is provided inside an exhaust pipe through which exhaust gas flows, the heat exchange being formed from silicon carbide, and the heat exchanger performing heat exchange between the exhaust gas and a heat medium; and a retention member that is provided at the periphery of the heat exchanger, is formed of a ceramic sheet or an expandable graphite sheet, and is sandwiched between the exhaust pipe and the heat exchanger, thereby retaining the heat exchanger in the exhaust pipe.

LOW PROFILE SUPPORT STRUCTURE FOR A ROTARY REGENERATIVE HEAT EXCHANGER

A support structure for a rotary regenerative heat exchanger includes an upper section, a lower section, and a plurality of support members. The upper section includes an upper ring having a first exterior surface, an upper hub and at least three upper spokes each extending between and secured at respective ends thereof to the upper ring and the upper hub. Each of the plurality of support members are fixedly secured, directly or indirectly, to the upper ring and the lower section. An annular space is between the upper ring and the lower ring, which is configured to receive compartments of a rotor assembly. The upper hub, the upper spokes and the support members cooperate to provide rigidity to the support structure by cooperating to support and transmit the weight of the upper spokes, the upper ring and the upper hub to the lower section. 117-. (canceled)18. A support structure for a rotary regenerative heat exchanger , the support structure comprising:an upper section comprising an upper ring having a first exterior surface, an upper hub and at least three upper spokes each extending between and secured at respective ends thereof to the upper ring and the upper hub;a first rotor assembly support area located substantially axially below an upper axial boundary of the upper ring and the upper spokes of the upper section of the support structure;an upper bearing disposed in the first rotor assembly support area;a lower section configured to be supportable in use by a foundation mounting structure mounted on a foundation, with the lower section being spaced apart from the upper section; anda plurality of support members, each of the plurality of support members being fixedly secured, directly or indirectly, to the upper ring and the lower section thereby creating an annular space between the upper ring and the lower section, the annular space being configured to receive compartments of a rotor assembly;wherein the upper hub, the upper spokes and the support members ...

Heat Exchanger and Method of Making the Same

A heat exchanger for transferring heat from a hot gas to a fluid includes two or more corrugated fin structures defining a plurality of hot gas flow channels extending in a generally linear first direction. A fluid conduit includes an outer wall at least partially bonded to at least two of the corrugated fin structures. The fluid conduit defines a plurality of sequentially arranged flow passes for the fluid traveling therethrough. Each of the plurality of flow passes directs the fluid in a direction generally perpendicular to the first direction. 1. A heat exchanger for transferring heat from a hot gas to a fluid , comprising:two or more corrugated fin structures defining a plurality of hot gas flow channels, each of the plurality of hot gas flow channels extending in a generally linear first direction; anda fluid conduit having an outer wall at least partially bonded to at least two of the corrugated fin structures and defining a plurality of sequentially arranged flow passes for the fluid traveling therethrough, each of the plurality of flow passes directing the fluid in a direction generally perpendicular to the first direction,wherein each of the plurality of sequentially arranged flow passes is oriented at an angle of inclination to the first direction, the angle of inclination being no greater than two degrees.2. The heat exchanger of claim 1 , wherein the outer wall of the fluid conduit has an annular cross-section.3. The heat exchanger of claim 1 , wherein the two or more corrugated fin structures comprise a first claim 1 , a second claim 1 , and a third corrugated fin structure claim 1 , wherein the first corrugated fin structure is arranged between the second corrugated fin structure and the third corrugate fin structure claim 1 , sequential ones of the plurality of flow passes being arranged between the first and second corrugated fin structures claim 1 , and the first and third corrugated fin structures claim 1 , in alternating fashion.4. The heat ...

Heat exchange cell and method

A heat exchange cell is described comprising a containment casing ( 11 ) comprising a rear wall ( 11 d ), a front wall ( 22 ) and a peripheral side wall ( 11 c ), a helically-shaped heat exchanger ( 13 ) comprising at least one tubular duct for the flow of a first heat transfer fluid coiled about a longitudinal axis of the helix according to a plurality of coils and mounted in the containment casing ( 11 ); a feeding zone of a second heat transfer fluid, intended for the heat exchange with the first heat transfer fluid, defined in the casing ( 11 ) coaxially and internally with respect to the heat exchanger ( 13 ); a first chamber ( 15 ) for collecting the second heat transfer fluid externally defined with respect to the heat exchanger ( 13 ) between a radially outer wall thereof and the peripheral side wall ( 11 c ) of the containment casing ( 11 ); and a second chamber ( 16 ) for collecting the second heat transfer fluid at least partially delimited by at least one separating element ( 14 ). The separating element ( 14 ) is mounted at an axially external position with respect to the heat exchanger ( 13 ) in such a way as to define the second chamber ( 16 ) for collecting the second heat transfer fluid between the separating element ( 14 ), the peripheral side wall ( 11 c ) and the rear wall ( 11 d ) or the front wall ( 22 ) of the containment casing ( 11 ); in this way, the first ( 15 ) and the second ( 16 ) collection chambers are in fluid communication with each other by means of at least one passage ( 17 a, 17 a′, 17 b - 17 g; 14 e ) configured to allow a flow of the second heat transfer fluid substantially in parallel to the peripheral side wall ( 11 c ) of the casing ( 11 ) and in proximity thereto. The separating element ( 14 ) comprises a heat exchange portion in contact with at least one portion of an end coil of the heat exchanger ( 13 ) and configured to allow a heat exchange between the coil-shaped portion of the heat exchanger ( 13 ) and the second ...

END CAP FOR PANEL ASSEMBLY OF AN HVAC SYSTEM

A heating, ventilation, and/or air conditioning (HVAC) system includes a panel assembly having a first face and a second face terminating in a corner. The HVAC system also includes an end cap having a first surface and a second surface that are joined at a vertex. The end cap extends over the corner of the panel assembly such that the first surface of the end cap extends along the first face and the second surface of the end cap extends along the second face. The end cap includes a rib extending from the vertex and into a slot formed at the corner between the first face and the second face. 1. A heating , ventilation , and/or air conditioning (HVAC) system , comprising:a panel assembly having a first face and a second face terminating in a corner;an end cap having a first surface and a second surface that are joined at a vertex and that extends over the corner of the panel assembly such that the first surface of the end cap extends along the first face and the second surface of the end cap extends along the second face, wherein the end cap includes a rib extending from the vertex and into a slot formed at the corner between the first face and the second face.2. The HVAC system of claim 1 , wherein the rib and the slot engage with one another in an interference fit arrangement.3. The HVAC system of claim 1 , wherein the end cap comprises a protrusion extending from the first surface claim 1 , the second surface claim 1 , and the vertex claim 1 , wherein the protrusion is configured to extend into a notch in the corner that is adjacent to the slot.4. The HVAC system of claim 3 , wherein the protrusion has an oblong or circular cross-sectional geometry.5. The HVAC system of claim 3 , wherein the rib and the protrusion connect to one another along the vertex.6. The HVAC system of claim 3 , wherein the protrusion has a boundary defining an open interior claim 3 , wherein the boundary is made from deformable material.7. The HVAC system of claim 1 , wherein the panel ...

Counter-flow fin plate heat exchanger for gas-gas heat exchange

A counter-flow fin plate heat exchanger for gas-to-gas heat exchange includes several outer channel fins, an outer channel bending plate, an inner channel fin and an inner channel bending plate. The outer channel bending plate is a flat plate with two sides bending upward vertically. The inner channel bending plate is a cuboid box without a cap on the top, and the top of the inner channel bending plate is hermetically fixed with the bottom of the outer channel bending plate. The several outer channel fins are arranged in parallel inside the outer channel bending plate. The inner channel fins are arranged inside the inner channel bending plate. Ends of a side surface corresponding to two long sides of the inner channel bending plate are respectively provided with an opening, and the two openings are respectively disposed at different ends of the two side surfaces.

Cooling Module with Integral Surge Tank

A cooling module includes multiple heat exchangers, at least one of which is a coolant radiator. The cooling module further includes a structural frame channel extending along an end of the cooling module, with the heat exchangers being at least partially secured to the structural frame channel. A coolant surge tank is integral to the cooling module, and is in fluid communication with the coolant radiator. The coolant surge tank has a coolant volume bounded by several walls, and at least one of those walls is provided by the structural frame channel. A method of making the cooling module is also described. 1. A cooling module comprising:a plurality of heat exchangers, at least one of which is a coolant radiator;a structural frame channel extending along an end of the cooling module, the plurality of heat exchangers being at least partially secured to the structural frame channel; anda coolant surge tank integral to the cooling module and in fluid communication with the coolant radiator, the coolant surge tank having a coolant volume bounded by a plurality of walls, at least one of said walls being provided by the structural frame channel.2. The cooling module of claim 1 , wherein the structural frame channel defines a planar wall extending along a width dimension of the cooling module claim 1 , the plurality of heat exchangers and the coolant surge tank being located on a common side of the planar wall.3. The cooling module of claim 2 , wherein the coolant surge tank is arranged between the planar wall and the coolant radiator.4. The cooling module of claim 1 , wherein each of the plurality of heat exchangers includes a heat exchanger core claim 1 , and the structural frame channel is non-overlapping with the heat exchanger cores.5. The cooling module of claim 1 , wherein the structural frame channel comprises:a first planar wall having first and second opposing long edges;a second planar wall extending along the first long edge and oriented perpendicular to the ...

POOL TYPE LIQUID METAL FAST SPECTRUM REACTOR USING A PRINTED CIRCUIT HEAT EXCHANGER CONNECTION TO THE POWER CONVERSION SYSTEM

A printed circuit heat exchanger for use in a reactor includes a core formed from a stack of plates diffusion bonded together. The core has: a top face, a bottom face disposed opposite the top face, a first side face extending between the top face and the bottom face, and a second side face disposed opposite the first side face. The printed circuit heat exchanger includes: a plurality of primary channels defined in the core, each of the primary channels extending from a primary inlet defined in the first side face to a primary outlet defined in the second side face; and a plurality of secondary channels defined in the core, each of the secondary channels extending among at least some of the primary channels from a secondary inlet defined in the top face to a secondary outlet defined in the top face. 1. A printed circuit heat exchanger comprising:a core formed from a stack of plates diffusion bonded together, the core having: a top face, a bottom face disposed opposite the top face, a first side face extending between the top face and the bottom face, and a second side face disposed opposite the first side face;a plurality of primary channels defined in the core, each of the primary channels extending from a primary inlet defined in the first side face to a primary outlet defined in the second side face; anda plurality of secondary channels defined in the core, each of the secondary channels extending among at least some of the primary channels from a secondary inlet defined in the top face to a secondary outlet defined in the top face.2. The printed circuit heat exchanger of claim 1 , further comprising:an inlet plenum defining a first space therein, the first space in fluid communication with the secondary inlets; andan outlet plenum defining a second space therein, the second space in fluid communication with the secondary outlets.3. The printed circuit heat exchanger of claim 2 , wherein the inlet plenum comprises a main inlet structured to be fluidly coupled to ...

Adjacently-Installed Temperature Equalizer with Single Side Heat Transferring

The present invention provides an adjacently-installed temperature equalizer with single side heat transferring formed with a heat transferring adjacent surface and a heat insulation surface oriented towards the exterior and a fluid channel transferring heat with the passing fluid, wherein one or more than one adjacently-installed temperature equalizer with single side heat transferring is adjacently installed at a selected location at the exterior and/or the interior of a temperature equalizing object, and through pumping the external fluid for cooling or heating, the fluid is enabled to pass the heat transferring adjacent surface of the adjacently-installed temperature equalizer with single side heat transferring for transferring the cooling or heating thermal energy to the temperature equalizing object; and beside a thermal energy transferring surface ( 1005 ), other opened surfaces are respectively formed with a heat insulation layer ( 1010 ) for preventing or reducing the heat transfer of radiating, transferring and convecting to the exterior.

Heat Exchanger and Method of Making the Same

A heat exchanger for transferring heat from a hot gas to a fluid includes two or more corrugated fm structures defining a plurality of hot gas flow channels. Each of the plurality of hot gas flow channels extends in a generally linear first direction. A fluid conduit includes an outer wall at least partially bonded to at least two of the corrugated fin structures. The fluid conduit defines a plurality of sequentially arranged flow passes for the fluid traveling therethrough. Each of the plurality of flow passes directs the fluid in a direction generally perpendicular to the first direction. 131-. (canceled)32. A fluid connection for a heat exchanger , comprising:a connector body having a brazeable outer surface;a fluid manifold located within the connector body;an externally accessible port connection fluidly coupled to the fluid manifold;a plurality of flow conduit access channels extending between the outer surface and the manifold; anda braze alloy chamber at least partially intersecting each of the plurality of flow conduit access channels between the outer surface and the manifold.33. The fluid connection of claim 32 , wherein each one of the plurality of flow conduit access channels is circular in cross-section.34. The fluid connection of claim 32 , wherein centroidal axes of the plurality of flow conduit access channels are aligned in a plane and wherein the braze alloy chamber is offset from that plane.35. The fluid connection of claim 32 , wherein the plurality of flow conduit access channels extend in a first longitudinal direction and the braze alloy chamber extends in a second longitudinal direction perpendicular to the first longitudinal direction.36. A method of making a heat exchanger claim 32 , comprising:arranging a plurality of flow conduits interior to a heat exchanger casing;extending an end of each of the plurality of flow conduits through an aperture within a wall of the casing;inserting said ends into a connector body; andin a common brazing ...

HEAT EXCHANGER FOR A MOTOR VEHICLE

The invention relates to a heat exchanger () for exchanging heat between a first and a second fluid, in particular for supplying the combustion engine of a motor vehicle with air, the heat exchanger comprising at least one heat-exchanging nest () through which flows the first fluid F and a casing () in which the heat-exchanging nest () is accommodated such that the second fluid F can flow therethrough. The heat-exchanging nest () comprises plates () for the circulation of the first fluid F the plates being stacked one on top of the other, at least one of the plates () having a rim () disposed between the heat-exchanging nest () and the casing () so as to restrict the second fluid F in its flow about the nest. 115175252312329572. A heat exchanger () for the exchange of heat between a first and a second fluid , notably for supplying air to a motor vehicle combustion engine , comprising at least one heat exchange core bundle () through which the first fluid F passes and a casing () in which said heat exchange core bundle () is housed so that the second fluid F can pass through it , the heat exchange core bundle () comprising plates () for the circulation of the first fluid F which are stacked on one another , at least one of said plates () having a rim () placed between said heat exchange core bundle () and said casing () so as to limit the extent to which the second fluid F can bypass the core bundle.2. The heat exchanger as claimed in claim 1 , in which the rim or rims are perpendicular to a plane of extension of their respective plate.3. The heat exchanger as claimed in claim 1 , in which said core bundle has lateral faces and the rims extend between at least one of said lateral faces and said casing.4. The heat exchanger as claimed in the preceding claim 3 , in which claim 3 , at least at one of said lateral faces claim 3 , the rims are arranged in succession along one and the same direction parallel to a direction of stacking of said plates.5. The heat exchanger ...

Heat exchanger comprising an exchange bundle equipped with means for improving attachment of said exchange bundle to the walls of a housing

The invention relates to a heat exchanger comprising a housing suitable for enclosing a heat exchange bundle ( 40 ), said housing having an opening for receiving said heat exchange bundle ( 40 ) inside said housing, said heat exchange bundle ( 40 ) comprising a first extremity designed to plug the opening of the housing when the heat exchange bundle ( 40 ) is inserted into said housing ( 30 ). According to the invention, a first element is provided on the second extremity ( 80 ) of the heat exchange bundle ( 40 ) opposite said first extremity or on the lower wall ( 50 ) of the housing and is provided with at least one projecting rim ( 70 ) and a second element is provided on said second extremity of the heat exchange bundle ( 40 ) or on said lower wall ( 50 ) of the housing ( 30 ) and is provided with a groove ( 51 ) designed to receive and attach said at least one projecting rim ( 70 ), and said at least one projecting rim ( 70 ) and said at least one groove ( 51 ) are designed to attach the at least one projecting rim ( 70 ) in the at least one groove ( 51 ) using an adhesive. Application in the automobile field.

HEAT EXCHANGER AND MANUFACTURING METHOD THEREFOR

A heat exchanger includes a tube expansion portion provided on a heat transfer tube such that an outer peripheral surface of the heat transfer tube is pressed against an inner peripheral surface of a first hole provided in a side wall portion of a case, and a first concave surface portion that is provided in a part of an outer surface of the tube expansion portion and forms a first gap, into which brazing material of a first brazed portion advances, between the outer surface of the tube expansion portion and the inner peripheral surface of the first hole. Thus, the attachment strength of the heat transfer tube can be improved by means of a simple configuration. 1. A heat exchanger comprising:a case into which a heating medium is supplied;a heat transfer tube drawn out to the outside from the interior of the case such that an end portion thereof is inserted into a first hole provided in a side wall portion of the case;a first brazed portion provided on the side wall portion to bond the heat transfer tube to a peripheral edge portion of the first hole;a tube expansion portion provided on the heat transfer tube such that an outer peripheral surface of the heat transfer tube is pressed against an inner peripheral surface of the first hole; anda first concave surface portion that is provided in a part of an outer surface of the tube expansion portion and forms a first gap, into which brazing material of the first brazed portion advances, between the outer surface of the tube expansion portion and the inner peripheral surface of the first hole.2. The heat exchanger according to claim 1 , whereinthe tube expansion portion includes first and second step portions that are positioned respectively on the inside and the outside of the side wall portion so as to sandwich the side wall portion in an axial length direction of the heat transfer tube, and bonded to the side wall portion, andthe first concave surface portion extends to respective outer surfaces of the first and ...

Adjustable Tool Holder

Disclosed is an adjustable tool holder for holding elongate hand held tools. The tool holder comprises a telescopically adjustable base member comprising an elongate, rectangular, hollow outer member and an elongate rectangular inner member configured to be snugly and slidably received within the outer member, the inner member adapted to be secured to the outer member at a plurality of lock positions thereby rendering the length of the base member adjustable. The tool holder further comprises a compression spring, one end of which is secured at the free end of the outer member and the other end of which is secured at the free end of the inner member. The length of the spring is subject to change in accordance with the change in the length of the base member. A tool is adapted to be held between two consecutive loops of the spring. 1. An adjustable tool holder comprising: (i) an elongate, rectangular, hollow outer member; and', '(ii) an elongate rectangular inner member configured to be slidably received within the outer member, the inner member adapted to be secured to the outer member at a plurality of lock positions, thereby rendering the length of the base member adjustable;, '(a) a telescopically adjustable base member comprising(b) a compression spring having one end secured at a free end of the outer member and the other end secured at a free end of the inner member;whereby the length of compression spring is subject to change in accordance with the change in the length of the base member;consecutive loops of the compression spring adapted to hold a handheld tool therebetween;the inner member comprising at least one spring support member secured thereto such that the support member is adapted to slide along the length thereof;the support member comprising a narrow slit that serves as a receptacle for receiving a portion of the loop of the spring therewithin so as to support to the spring;the spring support member comprising:(a) an elongate central member ...

Plate and frame heat exchanger

A plate and frame heat exchanger includes a plate package having individually removable plates positioned between opposed end frame portions synchronously movable toward each other for forming a compressed plate package by a drive linkage of the plate and frame heat exchanger in response to the drive linkage being drivingly actuated in one direction by a drive unit selectively connected to the drive linkage. The end frame portions are synchronously movable away from each other for forming an uncompressed plate package such that individual plates from the plate package are removable from the plate and frame heat exchanger in response to the drive linkage of the plate and frame heat exchanger being drivingly actuated in a direction opposite the one direction by the drive unit. The drive unit is selectively separable from the plate and frame heat exchanger without disassembly of the drive linkage.

BULK SOLIDS HEAT EXCHANGER

A heat exchanger has a housing that includes an inlet for receiving bulk solids, and an outlet for discharging the bulk solids. A plurality of heat transfer tubes are disposed between the inlet and the outlet and extend generally transversely in the housing, and are arranged in rows such that the heat transfer tubes in a row of the rows are generally parallel and are spaced apart to facilitate the flow of bulk solids through the spaces between the heat transfer tubes. Supports are disposed in the housing, between the plurality of heat transfer tubes and the outlet, for supporting the plurality of heat transfer tubes thereon. The rows of heat transfer tubes are stacked in contact with adjacent rows of heat transfer tubes such that heat transfer tubes of a first row of the stack are in contact with and are supported by the supports and heat transfer tubes of each subsequent row of the stack are in contact with and supported by a previous row of the stack. 1. A heat exchanger comprising:a housing including an inlet for receiving bulk solids, and an outlet for discharging the bulk solids;a plurality of heat transfer tubes disposed between the inlet and the outlet and extending generally transversely in the housing;supports disposed in the housing, between the plurality of heat transfer tubes and the outlet, for supporting the plurality of heat transfer tubes thereon;wherein heat transfer tubes of the plurality of heat transfer tubes are in contact with adjacent heat transfer tubes such that a first heat transfer tube is supported on at least one of the supports, a second heat transfer tube is in contact with and supported by the first heat transfer tube, and a third heat transfer tube is in contact with and supported by the second heat transfer tube.2. The heat exchanger according to claim 1 , wherein the second heat transfer tube is supported by more than one of the plurality of heat transfer tubes claim 1 , including the first heat transfer tube.3. The heat exchanger ...

Header Tank, Heat Exchanger And Corresponding Method Of Assembly

A header tank for a heat exchanger comprises a header plate ( 11 ) having openings ( 17 ) for the passage of a plurality of heat exchange tubes ( 5 ) and at least two end plates ( 7 ) on either side of the tubes ( 5 ), an elastic sealing means ( 13 ) arranged around the peripheral contour of the header plate ( 11 ), and a cover ( 15 ) having a cover base ( 25 ) which closes the header tank, thereby compressing the sealing means ( 13 ). The end plates ( 7, 107, 207 ) have, on the inside of the header plate ( 11, 111, 211 ), an axial extension of length (L′) greater than or equal to the height (h) of the sealing means ( 13, 113, 213 ). The sealing means ( 13, 113, 213 ) is arranged resting, under tension, against the end plates ( 7, 107, 207 ). The invention also relates to a heat exchanger comprising at least one such header tank, and to the method of assembling this heat exchanger.

SYSTEM FOR COOLING A FLUID WITH A MICROCHANNEL EVAPORATOR

A microchannel evaporator includes a plurality of microchannels. Each of the plurality of microchannels includes a first end and a second end. A first end-tank is coupled to each first end of the plurality of microchannels and a second end-tank is coupled to each second end of the plurality of microchannels. An inlet is coupled to the first end-tank for receiving a fluid into the microchannel evaporator and an outlet is coupled to the second end-tank for expelling the fluid from the microchannel evaporator. Each microchannel of the plurality of microchannels is substantially U-shaped. 1. A microchannel evaporator comprising:a plurality of microchannels, each of the plurality of microchannels comprising a first end and a second end;a first end-tank coupled to each first end of the plurality of microchannels;a second end-tank coupled to each second end of the plurality of microchannels;an inlet coupled to the first end-tank for receiving a fluid into the microchannel evaporator;an outlet coupled to the second end-tank for expelling the fluid from the microchannel evaporator; andwherein each microchannel of the plurality of microchannels is substantially U-shaped.2. The microchannel evaporator of claim 1 , wherein a diameter of the outlet is larger than a diameter of the inlet.3. The microchannel evaporator of claim 1 , wherein each microchannel of the plurality of microchannels is spaced apart from an adjacent microchannel of the plurality of microchannels such that at least one gap is formed.4. The microchannel evaporator of comprising at least one fin disposed in the at least one gap.5. The microchannel evaporator of claim 4 , wherein the at least one fin extends along only a portion of a length of a microchannel of the plurality of microchannels.6. The microchannel evaporator of claim 1 , wherein each microchannel of the plurality of microchannels has a rectangular cross-section.7. The microchannel evaporator of claim 1 , wherein the microchannel evaporator ...

Air handling unit with internal support system

An air handling unit, includes: an outer casing defining an air passage from a first opening on a first side of the outer casing to a second opening on a second side of the outer casing; a first supporting member in the air passage and affixed to the outer casing; a heat-exchanging coil affixed to a surface of the first supporting member facing the second opening; a second supporting member located such that the heat-exchanging coil is located between the first supporting member and the second supporting member; a first connection member connecting the first supporting member and the second supporting member; and insulation material adjacent to the outer casing at least between the first supporting member and the second opening, the insulation material being located between the first connection member and the outer casing, wherein the insulation material is unperforated between the first supporting member and the second opening.

STAMPED THERMAL EXPANSION RELIEF FEATURE FOR HEAT EXCHANGERS

A heat exchanger having at least one of side plates embodying a polygonal aperture through the planar base thereof, located at a predetermined position, and at least two corresponding shear-apertures located at the interface between the planar base and a first wall and a second wall of the side plate, each adjacent to the base aperture, providing at least one flexing location to accommodate thermal expansion of the heat exchanger during thermal cycling. 1. A heat exchanger comprising:a core unit including a plurality of tubes and a plurality of fins stacked alternately with each other;tanks arranged at the ends in a longitudinal direction of the tubes of the core unit and communicating with the multiplicity of the tubes; andat least one side plate arranged at one end in the stacking direction of the tubes of the core unit and having the ends thereof coupled to the tanks;wherein the side plate includes a base portion in contact with the fins and side walls extending perpendicular from the base portion in the stacking direction of the tubes;wherein the base portion comprises at least one elongated polygonal aperture, perpendicular to the longitudinal direction of the tubes extending a predetermined distance in both directions towards an interface between the base portion and the side walls;wherein a pair of interface apertures staggered in a latitudinal direction of the tubes on either side of the polygonal aperture, each extending a predetermined distance up the side wall, and across the base portion a predetermined distance so as to each overlap in a longitudinal planar direction with the polygonal aperture in the base portion relative to the tubes.2. The heat exchanger of claim 1 , wherein the polygonal aperture is a rhombus.3. The heat exchanger of claim 1 , wherein the polygonal aperture is stamped prior to assembly with the heat exchanger.4. The heat exchanger of further defining a flexible bridge in the latitudinal direction of the tubes located between each ...

EVAPORATOR

The present invention is a cross-flow evaporator adapted to generate vapor from the heat of the exhaust gases from an internal combustion engine. The evaporator is constituted, among other elements, by two plates spaced from one another which contain chambers. The heat exchange tubes alternately communicate the chambers of both plates, establishing a specific path for the fluid intended to change phase. The tubes extending between the chambers of the two plates are arranged transverse to the flow of the hot gas. This evaporator is suitable for heat recovery systems using a Rankine cycle, making use of the heat from the exhaust gases. 1. An evaporator for the evaporation of a first fluid by means of the heat provided by a second fluid , the second fluid being a hot gas , wherein said evaporator comprises:{'b': 1', '2', '1', '2', '1', '1', '2', '1, 'a first plate () and a second plate () facing one another and arranged spaced from one another, defining an inner face, the face facing the other plate, and an outer face opposite the inner face; wherein each of the plates (, ) comprises a plurality of chambers (., .);'}{'b': 4', '5', '1', '1', '2', '1', '1', '2, 'an intake manifold () of the first fluid and an exhaust manifold () of the first fluid situated in fluid communication with one another and with at least one different chamber (., .) of any of the plates (, );'}{'b': 3', '3', '1', '1', '1', '2', '1', '2', '1', '1', '2', '1', '1', '2', '1', '1', '2', '1', '1', '2', '3', '1', '1', '2', '1', '4', '5, 'a plurality of heat exchange tubes () wherein each of the heat exchange tubes () extends between a chamber (.) of the first plate () and a chamber (.) of the second plate (); wherein each chamber (., .) of one plate (, ) is in fluid communication with two or more chambers (., .) of the other plate (, ) by means of at least two heat exchange tubes (), except the chambers (., .) in fluid communication with the intake manifold () or the exhaust manifold ();'}{'b': 3', '4 ...

HEAT EXCHANGER

A heat exchanger for cooling a flow of media, comprising a plurality of pipes. The pipes are each received in a respective pipe base at the ends, and the pipes are received in a housing between the two pipe bases, the housing being connected to the pipe bases in a fluid-tight manner. A coolant channel is formed by a shaped region oriented outwards along an outer wall which delimits the housing. The coolant channel has an opening oriented in the direction of the inner volume of the housing, and the coolant channel is in fluidic communication with the inner volume of the housing via the opening. The opening is at least partly covered by a panel, and the panel is arranged on the housing outer wall surface oriented inwards, the outer wall having the coolant channel. A gap is formed between an edge, which delimits the opening, and the panel. 1. A heat exchanger for cooling a media flow , the heat exchanger comprising:a plurality of tubes, at least a portion of the plurality of tubes being received at ends in a respective tube sheet, wherein the tubes between two tube sheets are received in a housing, which is connected to the tube sheets in a fluid-tight manner;a coolant channel formed by an outwardly directed shaped region along an outer wall delimiting the housing, the coolant channel having an opening that is directed in a direction of an inner volume of the housing and via which the coolant channel is in fluid communication with the inner volume of the housing, wherein the opening is at least partially covered by a panel that is disposed on an inwardly directed surface of the outer wall of the housing, which has the coolant channel; anda gap formed between an edge delimiting the opening and the panel.2. The heat exchanger according to claim 1 , wherein the coolant channel is disposed at a first end region of the housing claim 1 , the first end region being closed off by one of the tube sheets.3. The heat exchanger according to claim 1 , wherein a width of the gap ...

HEAT EXCHANGER

A heat exchanger includes crimping plates fixed to an inlet and an outlet of a duct and having frame shapes corresponding to opening shapes of the inlet and the outlet. Each of the crimping plates includes a beam connecting two different positions on an inner periphery of the crimping plate. The beam has a rib. 1. A heat exchanger comprising:a duct configured to receive first fluid through an inlet and emit the first fluid through an outlet;a core housed in the duct and configured to be capable of exchanging heat between second fluid and the first fluid flowing through the duct;crimping plates fixed to the inlet and the outlet and having frame shapes corresponding to opening shapes of the inlet and the outlet; andtanks crimping-fixed to the crimping plates,wherein:each of the crimping plates includes a beam connecting two different positions on an inner periphery of the crimping plate;the beam has a rib protruding in one or both of directions toward and away from the core;the rib includes a center of the beam being recessed;each of the crimping plates includes a side wall fixed to an outer wall face of the duct; andthe rib extends to the side wall.2. The heat exchanger according to claim 1 , wherein the rib extends continuously from one end portion to another end portion claim 1 , the end portions being connected to the inner periphery.36.-. (canceled)7. A heat exchanger comprising:a duct configured to receive first fluid through an inlet and emit the first fluid through an outlet;a core housed in the duct and configured to be capable of exchanging heat between second fluid and the first fluid flowing through the duct;crimping plates fixed to the inlet and the outlet and having frame shapes corresponding to opening shapes of the inlet and the outlet; andtanks crimping-fixed to the crimping plates,wherein:each of the crimping plates includes a beam connecting two different positions on an inner periphery of the crimping plate;the beam has a rib protruding in one or ...

Outdoor device and refrigeration cycle device

An outdoor device is provided which has: a heat exchanger including a heat exchange portion having multiple heat transfer pipes and multiple heat transfer fins joined to the heat transfer pipes, and a pair of header pipe assemblies arranged substantially in parallel along the upper-to-lower direction to face each other and configured to bundle end portions of the heat transfer pipes extending from the heat exchange portion; and a housing configured to support the heat exchanger via a support bracket. The support bracket includes a heat exchange side holding portion, a housing side holding portion, and a fin contact portion provided integrally with the heat exchange side holding portion or the housing side holding portion and arranged in contact with or in proximity to an edge portion of the heat exchange portion adjacent to one of the header pipe assemblies.

Plate For Heat Exchanger And Heat Exchanger Including The Plate

A plate for a heat exchanger, intended to be arranged in a stack of plates, includes: - a main panel having a first edge and a second edge, opposite the first edge, and at least one first fin protruding from the main panel and capable of delimiting, with the main panel and an adjacent plate, a fluid flow path, wherein the first fin extends from the first edge of the main panel towards the second edge, without extending up to the second edge, so as to provide a first fluid passage between one end of the first fin and the second transverse edge where the fluid flow path forms a first baffle.

HEAT EXCHANGER HAVING BYPASS SEAL WITH RETENTION CLIP

A heat exchanger comprises a stack of flat tubes defining first and second fluid flow passages, and a housing having side covers over the sides of the core, and being spaced from the sides of the core. The heat exchanger further comprises a bypass seal comprising a pair of side seals and a pair of clip members. The side seals are received between the sides of the core and the housing. Each side seal has an inner surface engaging the first side of the core and an outer surface engaging the first side wall of the housing. Each clip member has a middle portion to which a side seal is connected, as well as opposed first and second end portions which engage inwardly extending surfaces of the core. 1. A heat exchanger comprising: a plurality of first fluid flow passages for flow of a first fluid and a plurality of second fluid flow passages for flow of a second fluid, the first and second fluid flow passages arranged in alternating order along a height of the core;', 'a top and an opposed bottom, and a first side and an opposed second side, the first and second sides each extending between the top and the bottom along the height of the core, wherein the top, the bottom and the sides extend at least generally along an axis defined by a flow direction of the first fluid;', 'a first end and an opposed second end spaced apart along the axis;', 'a first fluid inlet and a first fluid outlet, each of the first fluid inlet and the first fluid outlet being located in one of the first and second ends of the core, and facing the axis;', 'each of the first fluid flow passages having opposed first and second sides which are substantially closed, wherein a first side plane passes through at least some of the first sides of the first fluid flow passages, and a second side plane passes through at least some of the second sides of the first fluid flow passages;', 'wherein the first side of the core defines a first inwardly extending surface and a second inwardly extending surface which ...

HEADER FOR EXCHANGER BUNDLE OF A HEAT EXCHANGER

The present invention relates to a header usable with an exchanger bundle of a heat exchanger. Said exchanger bundle includes at least one first row of tubes and one second row of tubes. The tubes are suitable for enabling the flow of a first fluid in the exchanger bundle. The header includes at least: —one first contact element for supporting the top side of a first end of the first row of tubes; —one second contact element for supporting the bottom side of said first end of the first row of tubes and supporting the top side of a first end of the second row of tubes, the thickness of the second contact element defining the distance between said first and second rows of tubes; and —one third contact element for supporting the bottom side of said first end of the second row of tubes. 1. A header which is designed to be used with an exchanger bundle of a heat exchanger , said exchanger bundle comprising: a first contact element to retain the upper side of a first end of the first row of tubes;', 'a second contact element to retain the lower side of said first end of the first row of tubes, and in order to retain the upper side of a first end of the second row of tubes, the thickness of the second contact element defining the distance between said first and second rows of tubes; and', 'a third contact element to retain the lower side of said first end of the second row of tubes,', 'wherein:', 'the first, second and third contact elements are equidistant,', 'the first end of the first contact element is connected to the first end of the second contact element by at least a first bent connector, and', 'the second end of the second contact element is connected to the second end of the third contact element by at least a second bent connection element., 'at least a first row of tubes and a second row of tubes, the tubes being designed to permit the circulation of a first fluid in the exchanger bundle−, the header comprising at least2. The header as claimed in claim 1 , ...

HEAT EXCHANGER FOR A POWER GENERATION SYSTEM

The present disclosure relates to heat exchanger for a power generation system and related methods that use supercritical fluids, and in particular to a heat exchanger configured to minimize axial forces during operation. 1. A heat exchanger configured for a power generation system , the heat exchanger comprising:at least one plate assembly including a first end and a second end opposed to the first end along an axial direction, each plate assembly including a plurality of plates stacked with respect to each other, the at least one plate assembly defining a first flow configuration and a second flow configuration that is separate from the first flow configuration, the first and second flow configurations extending from the first end to the second end so as to direct first and second fluids, respectively, through the at least one plate assembly; anda casing assembly that applies a compression force to the at least one plate assembly along a lateral direction that is perpendicular to the axial direction,wherein the at least one plate assembly is preloaded with a tension force in the axial direction, such that, when the at least one plate assembly is exposed to a predetermined temperature, each plate of the plurality of plates in the at least one plate assembly expands at least partially along the axial direction so as to reduce the tension force applied to the at least one plate assembly.2. The heat exchanger of claim 1 , wherein each plate is stacked with respect to each other along a lateral direction that is perpendicular the axial direction.3. The heat exchanger of claim 1 , wherein the at least one plate assembly is a plurality of plate assemblies arranged end-to-end along the axial direction.4. The heat exchanger of claim 1 , wherein the casing assembly includes a pair of compression rails and each compression rail includes a first end and a second end opposed to the first end along the axial direction claim 1 , wherein the pair of compression rails apply the ...

UNIT FOR CONVERSION OF THERMAL ENERGY

Described herein is a unit for conversion of thermal energy including:—a first heat-exchange unit defining a first flow path for a first thermovector fluid; and—a second heat-exchange unit defining a second flow path for a second thermovector fluid. The second flow path is obtained by a plurality of cartridge elements each including at least one element made of thermoelectric material. The second heat-exchange unit includes a first manifold element and a second manifold element, each including a connection interface to said plurality of cartridge elements, which is configured for providing a hydraulic connection with inlet orifices and outlet orifices of the cartridge elements, and an electrical connection to first electrodes and second electrodes of said plurality of cartridge elements electrically connected to the elements made of thermoelectric material. 1. A unit for conversion of thermal energy including:a first heat-exchange unit defining a first flow path for a first thermovector fluid; anda second heat-exchange unit defining a second flow path for a second thermovector fluid,wherein:said first heat-exchange unit includes a first inlet port for said first thermovector fluid, and a first outlet port for said first thermovector fluid, said first inlet port and first outlet port being located on a same side of said first heat-exchange unit and having a baffle set therebetween so as to give a substantially “U”-shaped geometry to said first flow path;said second heat-exchange unit includes a second inlet port and a second outlet port for said second thermovector fluid, and further includes a plurality of cartridge elements, said second flow path developing from said second inlet port, through said plurality of cartridge elements, to said second outlet port, said plurality of cartridge elements being at least partially immersed in the first flow path;said plurality of cartridge elements are in fluid communication with a first manifold element and a second manifold ...

HEAT EXCHANGER, INFORMATION PROCESSING DEVICE, AND FLAT TUBE MANUFACTURING METHOD

An electronic device includes a heat exchanger that includes a flat tube through which fluid flows. The flat tube includes a tube main body section, a connecting wall portion, and a flange portion. The tube main body section has a join portion at which an outer face at one end side of the tube main body section and an inner face at another end side of the tube main body section are joined together in an overlapping state to form a flat tube shape. The connecting wall portion extends from the one end of the tube main body section toward the inside of the tube main body section. The flange portion extends along the inner face of the tube main body section from a leading end part of the connecting wall portion toward an opposite side from the join portion, and is joined to the inner face. 1. A heat exchanger , comprising: a tube main body section having a join portion at which an outer face at one end side of the tube main body section and an inner face at another end side of the tube main body section are joined together in an overlapping state to form a flat tube shape,', 'a connecting wall portion that extends from the one end of the tube main body section toward the inside of the tube main body section, and', 'a flange portion that extends along the inner face of the tube main body section from a leading end part of the connecting wall portion toward an opposite side from the join portion, and that is joined to the inner face., 'a flat tube through which fluid flows, the flat tube including2. The heat exchanger of claim 1 , wherein the flat tube is formed from a single sheet member.3. The heat exchanger of claim 1 , wherein the tube main body section includes a flat-sheet-shaped join portion that is disposed at one side in a thickness direction of the tube main body section and that is joined to the other end side of the tube main body section in an overlapping state.4. The heat exchanger of claim 3 , wherein the tube main body section includes an outside flat- ...

Multi-fluid heat exchanger

A heat exchanger is provided. The heat exchanger includes a first wall manifold. The heat exchanger further includes a second wall manifold spaced apart from the first wall manifold. The heat exchanger further includes a plurality of vanes that extend generally circumferentially between the first wall manifold and the second wall manifold. The heat exchanger further includes a plurality of fluid circuits defined within the heat exchanger. Each fluid circuit in the plurality of fluid circuits includes an inlet channel portion and an outlet channel portion defined within the first wall manifold. A return channel portion defined within the second wall manifold. At least one passage portion of a plurality of passage portions defined within each vane of the plurality of vanes. The at least one passage portion extends between the return channel portion and one of the inlet channel portion and the outlet channel portion.

HEAT EXCHANGER

The invention relates to a heat exchanger () for indirect heat transfer between a first medium (F) and a second medium (F), comprising: a shell () which has a shell space () for receiving the first medium (F), a heat transfer block () which is disposed in the shell space () and which during correct operation is surrounded by the first medium (F), wherein the heat transfer block () is designed to cool the second medium (F) against the first medium (F), such that a gaseous phase of the first medium (G) forms in the shell space (). According to the invention a collecting channel () located in the shell space () is provided for drawing off the gaseous phase of the first medium (G) from the shell space (). 1112. A heat exchanger () for the indirect heat transfer between a first medium (F) and a second medium (F) , with:{'b': 2', '3', '1, 'a shell () which has a shell space () for receiving the first medium (F),'}{'b': 4', '3', '1', '4', '2', '1', '1', '3', '4, 'at least one heat transfer block () which is arranged in the shell space () and enveloped by the first medium (F) during a design-specified operation, wherein the heat transfer block () is designed for cooling and/or for at least partially liquefying the second medium (F) against the first medium (F) so that a gaseous phase of the first medium (G) is formed in the shell space (), wherein the at least one heat transfer block () is a plate heat exchanger,'}characterized in that{'b': 1', '3', '5', '3, 'for extracting the gaseous phase of the first medium (G) from the shell space (), provision is made for a collecting channel () which is located in the shell space ().'}241414214. The heat exchanger as claimed in claim 1 , characterized in that the heat transfer block () is designed so that the first medium (F) can rise in the heat transfer block () during operation of the heat exchanger () claim 1 , wherein the heat transfer block () is especially designed for conducting the second medium (F) in counterflow or ...

HEAT EXCHANGER

A mount configured for use with a recirculation heat exchanger of an aircraft environmental control is provided including a rectangular base having a length of about 14 inches (35.56 cm) and a width of about 6 inches (15.24 cm). A support extends vertically from the base. A top surface of the support is arranged at a 10° angle below a horizontal plane. 1. A mount configured for use with a recirculation heat exchanger of an aircraft environmental control system , comprising:a rectangular base having a length of about 14 inches (35.56 cm) and a width of about 6 inches (15.24 cm); anda support extending vertically from the base, wherein a topmost surface of the support is non parallel to a bottommost surface of the base, the support configured to receive a recirculation heat exchanger.2. The mount according to claim 1 , wherein one or more corners of the base have a radius of about 0.500 inches (1.27 cm) and one or more corners of the support have a radius of about 0.250 inches (0.635 cm).3. The mount according to claim 1 , wherein the base includes a left foot arranged adjacent a left side thereof and a right foot adjacent a right side thereof claim 1 , each of the feet extending 0.200 inches (0.508 cm) perpendicular to a horizontal plane in a first direction and 0.375 inches (0.9525 cm) perpendicular to a horizontal plane in a second claim 1 , opposite direction claim 1 , the left foot and right foot having an upper surface with a length of about 1.025 inches (2.6035 cm) and a lower surface with a length of about 1.300 inches (3.302 cm).4. The mount according to claim 3 , wherein a distance from a right side of the base to the upper surface of the left foot is about 12.975 inches (32.957 cm) and a distance from a right side of the base to the lower surface of the left foot is about 12.7000 inches (32.258 cm).5. The mount according to claim 3 , wherein at least one opening is formed in the lower surface of the base claim 3 , the at least one opening being positioned ...

STACKED PLATE EXCHANGER CASING AND EXCHANGER COMPRISING SUCH A CASING

A housing of a stacked-plate heat exchanger is disclosed, the housing defining a volume for accepting a plurality of stacked plates that are configured for the circulation of a fluid that is to be cooled and of a coolant. The housing defines an interface able to accept a header tank for the fluid that is to be cooled and comprising a first part able to move in the direction in which the plates are stacked when the stacked plates are being brazed, and a second part that has at least one flank defining the interface, the first and second parts being able to be assembled with one another when the plates are being brazed. A heat exchanger comprising the housing is also disclosed. 1. A housing of a stacked-plate heat exchanger , said housing defining a volume for accepting a plurality of stacked plates that are configured for the circulation of a fluid that is to be cooled and of a coolant , said housing defining an interface able to accept a header tank for the fluid that is to be cooled and comprising a first part able to move in the direction in which the plates are stacked when the stacked plates are being brazed , and a second part that has at least one flank defining said interface , said first and second parts being able to be assembled with one another when the plates are being brazed.2. The housing according to claim 1 , wherein said second part has two flanks defined as first and second flanks claim 1 , wherein the first flank defines a first interface able to accept an inlet header tank for the fluid that is to be cooled and wherein the second flank defines a second interface able to accept an outlet header tank for the fluid that is to be cooled.3. The housing according to claim 1 , wherein said second part comprises a bottom intended to lie facing an end plate of the plurality of stacked plates claim 1 , the bottom and the flank or flanks forming a unit assembly.4. The housing according to claim 1 , wherein said interface defines a surround in the middle of ...

EVAPORATOR

An evaporator includes a first descending flow tube group provided between a first upper header and a first lower header, and a second descending flow tube group provided between a second upper header and a second lower header to be located windward of the first descending flow tube group. The first upper header includes a first compartment communicating with the upper end of the first descending flow tube group, and the second upper header includes a third compartment communicating with the upper end of the second descending flow tube group. A first flow distribution control section having a first refrigerant passage section for communication between the first and third compartments is disposed between these compartments. The area of a portion of the first refrigerant passage section on the upstream side is larger than the area of a portion of the first refrigerant passage section on the downstream side. 1. An evaporator comprising:a first upper header;a first lower header disposed below the first upper header to be parallel to the first upper header;a plurality of first heat exchange tubes which are disposed between the first upper header and the first lower header and whose upper and lower end portions are connected to the first upper header and the first lower header, respectively;a first descending flow tube group which is composed of a plurality of the first heat exchange tubes and in which refrigerant flows from an upper side toward a lower side thereof;a first ascending flow tube group which is composed of a plurality of the first heat exchange tubes, in which the refrigerant flows from a lower side toward an upper side thereof, and which is provided adjacent to the first descending flow tube group;a first compartment which is provided in the first upper header and with which an upper end portion of the first descending flow tube group communicates;a second compartment which is provided in the first upper header to be located adjacent to the first ...

HEAT EXCHANGER

In some examples, a heat exchanger includes an outer shell defining an open cavity configured to receive heat exchanger core components. The heat exchanger core components may include a layer of hot passageway components configured to be separated from a layer of cold passageway components by a tube sheet. In some examples, the outer shell defines one or more alignment features on an inner wall of the open cavity, the one or more alignment features being configured to align the heat exchanger core components within the open cavity when inserted in the open cavity. The heat exchanger further comprises a cover configured to be attached to the outer shell via one or more braze joints to enclose the core components within the open cavity of the outer shell. 1. A method of assembling a heat exchanger , the method comprising:inserting heat exchanger core components into an open cavity of a preformed outer shell, wherein the outer shell defines one or more alignment features on an inner wall of the open cavity configured to align the heat exchanger core components within the open cavity when inserted in the open cavity, the heat exchanger core components comprising a layer of hot passageway components configured to be separated from a layer of cold passageway components by a tube sheet; andattaching a cover to the outer shell via one or more braze joints to enclose the heat exchanger core components within the open cavity of the outer shell.2. The method of claim 1 , wherein the heat exchanger core components comprise a plurality enclosure bars claim 1 , a plurality of fins claim 1 , and a plurality of tube sheets.3. The method of claim 2 , wherein the one or more alignment features comprise one or more grooves in the inner wall of the preformed outer shell claim 2 , wherein inserting the heat exchanger core components into the open cavity of the preformed outer shell comprises inserting an end portion of an enclosure bar of the plurality of enclosure bars into a ...

LIGHTWEIGHT LIQUID-COOLING-PLATE ASSEMBLY HAVING PLASTIC FRAME AND HEAT DISSIPATION SYSTEM USING SAME

The present invention relates to a lightweight liquid-cooling-plate assembly having a plastic frame and a heat dissipation system using the same. The liquid-cooling-plate assembly includes a plastic frame and at least one coolant chamber unit. The plastic frame includes a plurality of lateral walls, at least one accommodation opening, and a plurality of fastening elements. The lateral walls are connected with each other to form and define the at least one accommodation opening. The fastening elements are disposed on a part of the lateral walls. The coolant chamber unit is connected with the plastic frame and embedded in the at least one accommodation opening, and includes at least one surface exposed. 1. A liquid-cooling-plate assembly comprising:a plastic frame including a plurality of lateral walls, at least one accommodation opening, and a plurality of fastening elements, wherein the lateral walls are connected with each other to form and define the at least one accommodation opening, and the fastening elements are disposed on a part of the lateral walls, wherein the lateral walls of the plastic frame comprises a first lateral wall and a second lateral wall, and the first lateral wall is opposite to the second lateral wall, wherein the first lateral wall of the plastic frame comprises an outer side including a plurality of first position recesses, and the second lateral wall of the plastic frame comprises an outer side including a plurality of second position recesses, wherein the first position recesses are aligned with the second position recesses; andat least one coolant chamber unit connected with the plastic frame, embedded in the at least one accommodation opening, and including at least one surface exposed.2. The liquid-cooling-plate assembly according to claim 1 , wherein the plastic frame is connected with the coolant chamber unit by an adhesive layer.3. The liquid-cooling-plate assembly according to claim 1 , wherein the plastic frame is directly ...