DE102011054578A1 - Heat exchanger with an integrated temperature setting element - Google Patents

Abstract

A heat exchanger includes a plurality of plates in stacked relationship that define a plurality of fluid channels therebetween. The through openings formed in each of the plates are arranged and substantially aligned to form an inlet manifold and an outlet manifold for receiving a working fluid therein, the inlet manifold in fluid communication with an inlet conduit and the outlet manifold in fluid communication with an outlet conduit stands. A temperature adjusting member is disposed in at least one of the inlet pipe and the outlet pipe to adjust a temperature of the working fluid flowing therethrough.

Description

FIELD OF THE INVENTION

The present invention relates to a heat exchanger. In particular, the invention relates to a cooling heat exchanger having at least one temperature adjusting element integrated in at least one of a fluid inlet line and a fluid outlet line.

GENERAL PRIOR ART

Plate heat exchangers are used to transfer thermal energy between heat exchange working fluids. At least two streams of heat exchange working fluid flow through separate flow passages defined between the heat exchanger plates in the plate heat exchanger. Usually, the heat exchanger plates are arranged in a stacked relationship and are part of the plate heat exchanger. The separate flow passages are defined by through holes formed in the heat exchanger plates and flow channels formed between the heat exchanger plates.

The heat transfer between the working fluid streams takes place in the region of a central heat transfer section of the heat exchanger plates. In order to transfer thermal energy, a first working fluid flow flows through the passage openings on one side of the heat exchanger into a multiplicity of first flow channels, which are formed by alternating heat exchanger plates. At the same time, a second working fluid stream flows through the through holes on an opposite side of the heat exchanger into a plurality of second flow channels, which are also formed by the alternating heat exchanger plates and are separated from the first flow channels. Thus, heat is exchanged between the two working fluid streams in counterflow through the heat exchanger.

Such a plate heat exchanger is a cooling heat exchanger. The cooling heat exchanger is typically used to cool the working fluids flowing through the cooling heat exchanger from a heat source, such as an internal combustion engine, an electric motor, or a battery of a vehicle. However, in certain colder areas, it is desirable to also heat the working fluids flowing from the heat source. At present, the working fluids are heated either by separate heating elements that are remote in the structure of the fluid system from the cooling heat exchanger, or by heating elements disposed in a body of the heat exchanger.

It would be desirable to develop a heat exchanger having a temperature adjusting element integrated with its fluid line that adjusts a temperature of a working fluid while minimizing costs and maximizing heat exchanger manufacturability, regardless of line orientation, working fluid flow or heat exchanger size ,

BRIEF SUMMARY OF THE INVENTION

In accordance with and in accordance with the present invention, it has surprisingly been found a heat exchanger having a temperature adjusting element integrated into its fluid conduit which adjusts a temperature of a working fluid while minimizing costs and maximizing manufacturability.

In one embodiment, the heat exchanger comprises: a plurality of plates in a stacked relationship having a plurality of first fluid flow channels and a plurality of form second fluid flow channels therebetween, the plates having at least one first through-hole formed therein in fluid communication with the first fluid flow channels and at least one second through-hole formed therein in fluid communication with the second fluid flow channels, the at least one first through-hole the plates being substantially aligned with the at least one first through opening of another of the plates to form a first manifold to receive a first working fluid therein and the at least one second through opening of one of the plates substantially onto the at least one second through port of another the plate is aligned to form a second manifold to receive a second working fluid therein; a first conduit in fluid communication with the first manifold to receive the first working fluid therein; a second conduit in fluid communication with the second manifold to receive the second working fluid therein; and a temperature adjusting element disposed in at least one of the first line and the second line to adjust a temperature of the respective working fluid flowing through the at least one of the first line and the second line.

In another embodiment, the heat exchanger comprises: a plurality of end plates, wherein at least one of the end plates comprises a plurality of first through holes formed therein and a plurality of second through holes formed therein; a plurality of inner plates disposed in a stacked relationship between the end plates and defining a plurality of first fluid flow channels and a plurality of second fluid flow channels therebetween, the inner plates having a plurality of first through holes formed therein in fluid communication with the first fluid flow channels; a plurality of second through holes formed therein in fluid communication with the second fluid flow channels, the first through holes of each of the plates being substantially aligned to form an inlet manifold and an outlet manifold to receive the first working fluid therein; second through holes of each of the plates are substantially aligned to form an inlet manifold and an outlet manifold to receive the second working fluid therein; a first inlet line in fluid communication with the inlet manifold to receive the first working fluid therein; a first outlet conduit in fluid communication with the outlet manifold to receive the first working fluid therein; a second inlet line in fluid communication with the inlet manifold to receive the second working fluid therein; a second outlet conduit in fluid communication with the outlet manifold to receive the second working fluid therein; and a temperature adjusting element disposed in at least one of the first inlet line, the first outlet line, the second inlet line and the second outlet line to adjust a temperature of the respective working fluid passing through the at least one of the first inlet line, the first outlet line, the second inlet line and the second outlet line flows.

In another embodiment, the heat exchanger includes: a plurality of first plates including a pair of first through holes and a pair of second through holes formed therein; a plurality of second plates disposed adjacent the first plates in an alternating pattern to form a plurality of first fluid flow channels and a plurality of second fluid flow channels therebetween, each of the first fluid flow channels receiving a first working fluid therein and each of the second fluid flow channels second working fluid therein, and wherein each of the second plates comprises a pair of first through holes and a pair of second through holes formed therein, and wherein the first through holes of each of the plates are substantially aligned to an inlet manifold and an outlet manifold forming to receive the first working fluid therein, and wherein the second passage openings of each of the plates are substantially aligned to form an inlet manifold and an outlet manifold to receive the second working fluid therein; a first inlet line in fluid communication with the inlet manifold to receive the first working fluid therein; a first outlet conduit in fluid communication with the outlet manifold to receive the first working fluid therein; a second inlet conduit in fluid communication with the fin manifold to receive the second working fluid therein; a second outlet conduit in fluid communication with the outlet manifold to receive the second working fluid therein; and at least one temperature adjusting element disposed in the second inlet line and the second outlet line to adjust a temperature of the second working fluid flowing through the lines.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other advantages of the present invention will be readily apparent to those skilled in the art from the following detailed description of the preferred embodiment, when considered in light of the accompanying drawings. Show it:

1 an upper perspective schematic view of a heat exchanger according to an embodiment of the invention.

2 a side elevational view in cross section of the in 1 pictured heat exchanger along the line 2-2 along it.

DETAILED DESCRIPTION OF THE INVENTION

The following detailed description and the accompanying drawings describe and illustrate an embodiment of the invention. The description and drawings serve to enable one skilled in the art to make and use the invention, and are not intended to limit the scope of the invention in any way.

1 and 2 show a heat exchanger 10 according to an embodiment of the present invention. The heat exchanger shown 10 is a cooling heat exchanger, but it is understood that the heat exchanger 10 may be any type of heat exchanger used for any desired application, such as automotive, business, residential, marine, aerospace and recreational vehicle applications. The heat exchanger 10 includes a corner plate 16 and a variety of inner plates 18a . 18b that between a pair of end plates 19 . 20 arranged in stacked relationship. As needed, more or fewer plates than shown may be used, such as spacer plates or transfer plates.

As shown, have the corner plate 16 and the end plates 19 . 20 a greater thickness than the inner plates 18a . 18b to the heat exchanger 10 to give a structural stiffness. The plates 16 . 18a . 18b . 19 . 20 are mounted along their outer peripheries in a substantially fluid-tight manner. It is understood that the plates 16 . 18a . 18b . 19 . 20 as required by any suitable means such as brazing, soldering, welding, use of gaskets, and the like. Each of the plates shown 18a . 18b . 19 . 20 has a jacket section 21 which extends upwards and outwards to embedding adjacent plates 18a . 18b . 19 . 20 to facilitate in the stack and to maximize a seal between them.

In the embodiment shown, the plates 16 . 18a . 18b . 19 . 20 a generally rectangular shape, although it is understood that the plates 16 . 18a . 18b . 19 . 20 can have any shape and size as needed. It is further understood that the plates 16 . 18a . 18b . 19 . 29 [sic] may be formed of any suitable material, such as a metal material. Width and length of the shown heat exchanger 10 are of shape and size of the plates 18a . 18b . 19 . 20 dependent, and the height of the heat exchanger 10 is of the number of plates 18a . 18b . 19 . 20 in the stack. The number of inner plates 18a . 18b in the stack is based on a desired cooling, heating and flow capacity of the heat exchanger 10 certainly. The illustrated heat exchanger 10 includes twenty-four (24) inner plates 18a . 18b , It is understood, however, that more or less inner plates as needed 18a . 18b can be used as shown.

As in 2 Shown are the inner plates 18a next to the inner plates 18b arranged in an alternating pattern. The corner plate 16 is next to the end plate 20 arranged. It is understood that the corner plate 16 as needed next to one of the inner plates 18a . 18b or next to the end plate 19 can be arranged. A variety of flow channels 22a . 22b is between the alternating inner plates 18a . 18b and between the end plate 20 and the inner plate 18b educated. A first working fluid (not shown) is in the flow channels 22a added. A second working fluid (not shown) is in the flow channels 22b added. The working fluids may be any of the working fluids as needed, such as any fluid used in an automotive application, a refrigerant (eg, R12, R134a, etc.), a refrigerant (eg, ethylene glycol), an engine oil , a transmission oil, a power steering fluid, and the like. In one non-limiting example, the first working fluid is a refrigerant and the second working fluid is an engine or battery coolant.

asperity 24 in the inner plates 18a . 18b are formed, touching the adjacent inner plates 18a . 18b or at least one of the end plates 19 . 20 thereby providing a plurality of non-linear flow paths within the flow channels 22a . 22b to maximize heat transfer between the working fluids. It is understood that the surface irregularities 24 can have any shape and size as needed.

Each of the plates 18a . 18b . 20 further includes a pair of first working fluid passage openings 30 . 32 and a pair of second working fluid passage openings 34 . 36 , It is understood that the end plate 19 as required may have working fluid passage openings formed therein. The first working fluid ports 30 . 32 each of the plates 18a . 18b . 20 are arranged and substantially aligned to each an inlet manifold 40 and an outlet manifold 42 to build. The first working fluid inlet manifold 40 allows the first working fluid into the flow channels 22a to flow in, and the first working fluid outlet manifold 42 allows the first working fluid, from the flow channels 22a to flow out. An inlet pipe 50 is with the heat exchanger 10 coupled and in fluid communication with the first working fluid inlet manifold 40 In order to allow the first working fluid into the heat exchanger 10 to flow into it. An outlet pipe 52 is with the heat exchanger 10 coupled and in fluid communication with the first working fluid outlet manifold 42 to allow the first working fluid from the heat exchanger 10 to flow out. As shown, the wires are 50 . 52 accommodated in respective openings in the corner plate 16 are formed to form a fluid-tight connection therebetween. It is understood that the wires 50 . 52 with the corner plate 16 or one of the end plates 19 . 20 can be coupled as desired by any means such as brazing, soldering, welding, use of seals and the like.

The second working fluid passage openings 34 each of the plates 18a . 18b . 20 are arranged and substantially aligned to a second working fluid inlet manifold 54 to build. The second working fluid inlet manifold 54 allows the second working fluid into the flow channels 22b to flow into it. The second working fluid passage openings 36 each of the plates 16 . 18a . 18b . 20 are arranged and substantially aligned to a second working fluid outlet manifold 56 to build. The second working fluid outlet manifold 56 allows the second working fluid, from the flow channels 22b to flow out. An inlet pipe 58 is with the heat exchanger 10 coupled and in fluid communication with the second working fluid inlet manifold 54 to allow the second working fluid into the heat exchanger 10 to flow into it. An outlet pipe 60 is with the heat exchanger 10 coupled and in fluid communication with the second working fluid outlet manifold 56 to allow the second working fluid from the heat exchanger 10 to flow out. It is understood that the wires 50 . 52 . 58 . 60 as needed with the heat exchanger 10 can be coupled by any suitable means such as brazing, soldering, welding, use of a gasket, and the like. It is further understood that the lines 50 . 52 . 58 . 60 may be formed from any suitable material, such as a metal material or a plastic material. As shown, the lines extend 50 . 52 . 58 . 60 from one side of the heat exchanger 10 from the side to the outside. It is understood, however, that each of the wires 50 . 52 . 58 . 60 may be formed to meet as needed from any side of the heat exchanger 10 extending in any direction and in any configuration.

In the embodiment shown, a temperature adjusting element 70 in each of the inlet duct 58 and the outlet pipe 60 arranged for the second working fluid. As needed, more or less temperature adjustment elements 70 as shown, such as a temperature adjusting element 70 that in each of the lines 50 . 52 . 58 . 60 is arranged, two or more temperature setting elements 70 in at least one of the lines 50 . 52 . 58 . 60 are arranged, or a temperature setting 70 that only in one of the lines 50 . 52 . 58 . 60 is arranged. As shown, the temperature adjustment element 70 in the pipes 58 . 60 arranged in a position that is to a flow direction of the second working fluid through the lines 58 . 60 is substantially rectangular. It is understood, however, that the temperature setting element 70 as needed in the pipes 50 . 52 . 58 . 60 may be arranged in any position, such as in a position, to a flow direction of the first working fluid through the lines 50 . 52 is substantially at right angles, in a position corresponding to the flow direction of the working fluids through the lines 50 . 52 . 58 . 60 is substantially parallel, or in an intermediate position, extending between the flow direction of the working fluids through the lines 50 . 52 . 58 . 60 is substantially orthogonal position and the substantially parallel position.

The temperature setting element shown 70 is a heating element, such as a positive temperature coefficient (PTC) or a glow plug. It is understood that the temperature setting element 70 as required, any temperature setting element 70 may be, such as other heating elements or a cooling element. In the embodiment shown, the temperature adjustment elements 70 with the wires 58 . 60 through a threaded engagement 72 coupled forming a substantially fluid-tight connection therebetween. It is understood, however, that the temperature setting elements 70 with the wires 50 . 52 . 58 . 60 can be coupled as required by any means, such as brazing, soldering, welding, use of fasteners and the like, to form a fluid-tight connection. If desired, seals (not shown) may also be used to facilitate the manufacture of the fluid-tight connection.

In operation, the first working fluid flows to the heat exchanger 10 through the inlet pipe 50 and in the intake manifold 40 for the first working fluid. The first working fluid then flows into the flow channels 22a between the alternating plates 18a . 18b are formed. When the first working fluid is on the flow paths of the flow channels 22a moves, the first working fluid flows around the surface irregularities 24 around, in the plates 18a . 18b are formed, whereby the first working fluid is fluidized. Subsequently, the first working fluid flows from the flow channels 22a through the outlet manifold 42 and in the outlet line 52 from the heat exchanger 10 out.

At the same time, the second working fluid flows to the heat exchanger 10 through the inlet pipe 58 and in the intake manifold 54 for the second working fluid. The second working fluid then flows into the flow channels 22b between the alternating plates 18a . 18b are formed. When the second working fluid is on the flow paths of the flow channels 22b moves, the second working fluid flows around the surface irregularities 24 around, in the plates 18a . 18b are formed, whereby the second working fluid is fluidized. Typically, heat is transferred from the second working fluid to the first working fluid. It is understood, however, that in certain applications of the heat exchanger 10 for example, when used in colder areas, heat may be transferred from the first working fluid to the second working fluid as needed. Subsequently, the second working fluid flows from the flow channels 22b through the outlet manifold 56 and in the outlet line 60 from the heat exchanger 10 out.

When a temperature of the second working fluid passing through the inlet conduit 58 in the heat exchanger 10 flows, is above, or below a desired temperature, in the inlet line 58 arranged temperature adjustment 70 either activated or deactivated. In the embodiment shown, the temperature adjusting element 70 a heating element and is activated when the temperature of the second working fluid flowing through the inlet duct 58 flows below the desired temperature. The temperature setting element works accordingly 70 in the inlet pipe 58 to heat the second working fluid passing through the inlet conduit 58 flows until the desired temperature is reached. Once the desired temperature is reached, the temperature setting element 70 then deactivated. It is understood, however, that the temperature setting element 70 can be used to measure the temperature of the second working fluid flowing through the inlet pipe 58 flows, as needed to keep at the desired temperature. Additional temperature adjustment elements 70 in the inlet pipe 58 minimize the time needed to reach the desired temperature. When the temperature setting element 70 is a heating element that has been activated and the temperature of the second working fluid flowing through the inlet conduit 58 flows above the desired temperature is the temperature setting 70 disabled.

When a temperature of the second working fluid passing through the outlet conduit 60 from the heat exchanger 10 from flowing, above, or below a desired temperature, becomes the temperature adjusting element 70 that in the outlet pipe 60 is arranged, either activated or deactivated. In the embodiment shown, the temperature adjusting element 70 a heating element and is activated when the temperature of the second working fluid passing through the outlet 60 flows below the desired temperature. The temperature setting element works accordingly 70 in the outlet pipe 60 to heat the second working fluid passing through the outlet conduit 60 flows until the desired temperature is reached. Once the desired temperature is reached, the temperature setting element 70 then deactivated. It is understood, however, that the temperature setting element 70 can be used to measure the temperature of the second working fluid flowing through the outlet pipe 60 flows, if necessary to keep at the desired temperature. Additional temperature adjustment elements 70 in the outlet pipe 60 minimize the time needed to reach the desired temperature. When the temperature setting element 70 is a heating element that has been activated and the temperature of the second working fluid flowing through the outlet conduit 60 flows above the desired temperature is the temperature setting 70 disabled.

In another embodiment of the invention, the temperature adjusting element 70 that in the inlet pipe 58 is arranged, a cooling element and is activated when the temperature of the second working fluid flowing through the inlet pipe 58 flows above the desired temperature. The temperature setting element works accordingly 70 in the inlet pipe 58 to the second working fluid passing through the inlet pipe 58 flows, cool down until the desired temperature is reached. Once the desired temperature is reached, the temperature setting element 70 then deactivated. It is understood, however, that the temperature setting element 70 can be used to measure the temperature of the second working fluid flowing through the inlet pipe 58 flows, if necessary to keep at the desired temperature. Additional temperature adjustment elements 70 in the inlet pipe 58 minimize the time needed to reach the desired temperature. When the temperature setting element 70 is a cooling element that has been activated and the temperature of the second working fluid flowing through the inlet conduit 58 flows below the desired temperature, the temperature setting is 70 disabled.

In another embodiment of the invention, the temperature adjusting element 70 that in the outlet pipe 60 is arranged, a cooling element and is activated when the temperature of the second working fluid passing through the outlet 60 flows above the desired temperature. The temperature setting element works accordingly 70 in the outlet pipe 60 to the second working fluid passing through the outlet 60 flows, cool down until the desired temperature is reached. Once the desired temperature is reached, the temperature setting element 70 then deactivated. It is understood, however, that the temperature setting element 70 can be used to measure the temperature of the second working fluid flowing through the outlet pipe 60 flows, if necessary to keep at the desired temperature. Additional temperature adjustment elements 70 in the outlet pipe 60 minimize the time needed to reach the desired temperature. When the temperature setting element 70 is a cooling element that has been activated and the temperature of the second working fluid flowing through the outlet conduit 60 flows below the desired temperature, the temperature setting is 70 disabled.

It is understood that the inlet pipe 58 and the outlet pipe 60 any combination of temperature adjusting elements disposed therein 70 such as when the temperature adjusting element 70 that in the inlet pipe 58 is arranged, is a heating element and the temperature setting 70 that in the outlet pipe 60 is arranged, a cooling element is when the temperature setting 70 that in the inlet pipe 58 is arranged, is a cooling element and the temperature setting element 70 that in the outlet pipe 60 is arranged, is a heating element, or if one of the temperature setting elements 70 in the inlet pipe 58 are arranged, a heating element and another of the temperature setting elements 70 in the inlet pipe 58 are arranged, a cooling element and one of the temperature setting elements 70 in the outlet pipe 60 are arranged, a heating element and another of the temperature setting elements 70 in the outlet pipe 60 are arranged, a cooling element is.

It is further understood that at least one of the lines 50 . 52 at least one temperature adjusting element arranged therein 70 for heating or cooling the first working fluid until its desired temperature is reached.

From the foregoing description, one skilled in the art can readily ascertain the essential characteristics of the invention and, without departing from its spirit and scope, make various changes and modifications to the invention to adapt it to various uses and conditions.

Claims (20)

Heat exchanger comprising: a plurality of plates in stacked relationship forming a plurality of first fluid flow channels and a plurality of second fluid flow channels therebetween, the plates having at least a first through hole formed therein in fluid communication with the first fluid flow channels and at least one second through hole formed therein; which is in fluid communication with the second fluid flow channels, wherein the at least one first port of one of the plates is substantially aligned with the at least one first port of another of the plates to form a first manifold to receive a first working fluid therein; the at least one second through opening of one of the plates is substantially aligned with the at least one second through opening of another of the plates to form a second manifold to receive a second working fluid therein; a first conduit in fluid communication with the first manifold to receive the first working fluid therein; a second conduit in fluid communication with the second manifold to receive the second working fluid therein; and a temperature adjusting element disposed in at least one of the first line and the second line to adjust a temperature of the respective working fluid flowing through the at least one of the first line and the second line. The heat exchanger of claim 1, wherein the at least one of the first conduit and the second conduit is one of an inlet conduit and an outlet conduit. The heat exchanger of claim 1, wherein the temperature adjusting element is disposed in the at least one of the first conduit and the second conduit in a position substantially orthogonal to the flow of the respective working fluid through the at least one of the first conduit and the second conduit. The heat exchanger of claim 1, wherein the temperature adjusting element is disposed in the at least one of the first conduit and the second conduit in a position substantially parallel to the flow of the respective working fluid through the at least one of the first conduit and the second conduit. The heat exchanger of claim 1, wherein the temperature adjusting element in the at least one of the first conduit and the second conduit is in an intermediate position between the position substantially perpendicular to the flow of the respective working fluid through the at least one of the first conduit and the second conduit and the substantially parallel position is arranged. The heat exchanger of claim 1, wherein the temperature adjusting element is coupled to at least one of the first conduit and the second conduit via a threaded engagement forming a substantially fluid tight connection between the at least one of the first conduit and the second conduit and the temperature adjusting element. The heat exchanger of claim 1, wherein the temperature adjusting element is one of a heating element to heat the respective working fluid flowing through the at least one of the first conduit and the second conduit to a desired temperature, and a cooling element to receive the respective working fluid. flowing through the at least one of the first conduit and the second conduit until it is allowed to cool to a desired temperature. Heat exchanger according to claim 1, wherein the respective working fluid is at least one of a refrigerant, a motor fluid, a battery coolant and a transmission oil. A heat exchanger comprising: a plurality of end plates, wherein at least one of the end plates comprises a plurality of first through holes formed therein and a plurality of second through holes formed therein; a plurality of inner plates disposed in a stacked relationship between the end plates and defining a plurality of first fluid flow channels and a plurality of second fluid flow channels therebetween, the inner plates having a plurality of first through holes formed therein in fluid communication with the first fluid flow channels; a plurality of second through holes formed therein in fluid communication with the second fluid flow channels, the first through holes of each of the plates being substantially aligned to form an inlet manifold and an outlet manifold to receive the first working fluid therein; second through holes of each of the plates are substantially aligned to form an inlet manifold and an outlet manifold to receive the second working fluid therein; a first inlet line in fluid communication with the inlet manifold to receive the first working fluid therein; a first outlet conduit in fluid communication with the outlet manifold to receive the first working fluid therein; a second inlet line in fluid communication with the inlet manifold to receive the second working fluid therein; a second outlet conduit in fluid communication with the outlet manifold to receive the second working fluid therein; and a temperature adjusting element disposed in at least one of the first inlet line, the first outlet line, the second inlet line and the second outlet line to adjust a temperature of the respective working fluid passing through the at least one of the first inlet line, the first outlet line, the second inlet line and the second outlet line flows. The heat exchanger of claim 9, wherein the temperature adjusting element in the at least one of the first inlet line, the first outlet line, the second inlet line, and the second outlet line is in a position corresponding to the flow of the respective working fluid through the at least one of the first inlet line, the first outlet line second inlet pipe and the second outlet pipe is substantially rectangular, is arranged. The heat exchanger of claim 9, wherein the temperature adjusting element in the at least one of the first inlet line, the first outlet line, the second inlet line, and the second outlet line is in a position corresponding to the flow of the respective working fluid through the at least one of the first inlet line, the first outlet line second inlet line and the second outlet line is substantially parallel. The heat exchanger of claim 9, wherein the temperature adjusting element in the at least one of the first inlet line, the first outlet line, the second inlet line and the second outlet line is in an intermediate position between the flow of the respective working fluid through the at least one of the first inlet line, the first outlet line, the first outlet line second inlet line and the second outlet line is arranged in a substantially rectangular position and the substantially parallel position. The heat exchanger of claim 9, wherein the temperature adjustment element is threadedly coupled to the at least one of the first inlet line, the first outlet line, the second inlet line, and the second outlet line having a substantially fluid tight connection between the at least one of the first inlet line, the first outlet line forming the second inlet conduit and the second outlet conduit and the temperature adjusting element. The heat exchanger according to claim 9, wherein the temperature adjusting element controls one of a heating element to heat the respective working fluid flowing through the at least one of the first inlet line, the first outlet line, the second inlet line and the second outlet line to a desired temperature, and a cooling element for cooling the respective working fluid flowing through the at least one of the first inlet line, the first outlet line, the second inlet line and the second outlet line to a desired temperature. The heat exchanger according to claim 9, wherein the respective working fluid flowing through the at least one of the first intake pipe, the first exhaust pipe, the second intake pipe, and the second exhaust pipe is at least one of a refrigerant, a motor fluid, a battery coolant, and a transmission oil. A heat exchanger comprising: a plurality of first plates including a pair of first through holes and a pair of second through holes formed therein; a plurality of second plates disposed adjacent to the first plates in an alternating pattern to form a plurality of first fluid flow channels and a plurality of second fluid flow channels therebetween, each of the first fluid flow channels receiving a first working fluid therein and each of the second fluid flow channels second working fluid therein, and wherein each of the second plates has a pair of first through holes and a pair of second through holes formed therein; and wherein the first passage openings of each of the plates are substantially aligned to form an inlet manifold and an outlet manifold to receive the first working fluid therein, and wherein the second passage openings of each of the plates are substantially aligned to an inlet manifold and an outlet manifold to form to receive the second working fluid therein; a first inlet line in fluid communication with the inlet manifold to receive the first working fluid therein; a first outlet conduit in fluid communication with the outlet manifold to receive the first working fluid therein; a second inlet line in fluid communication with the inlet manifold to receive the second working fluid therein; a second outlet conduit in fluid communication with the outlet manifold to receive the second working fluid therein; and at least one temperature adjusting element disposed in the second inlet line and the second outlet line to adjust a temperature of the second working fluid flowing through the lines. 17. The heat exchanger of claim 16, wherein the at least one temperature adjusting element in the second inlet conduit is at a position substantially perpendicular to the flow of the second working fluid through the conduit, a position substantially parallel to the flow of the second working fluid through the conduit , and an intermediate position between the flow of the second working fluid through the conduit substantially perpendicular position and the substantially parallel position is arranged. 17. The heat exchanger of claim 16, wherein the at least one temperature adjusting element in the second outlet conduit is at a position substantially orthogonal to the flow of the second working fluid through the conduit, a position substantially parallel to the flow of the second working fluid through the conduit , and an intermediate position between the flow of the second working fluid through the conduit substantially perpendicular position and the substantially parallel position is arranged. The heat exchanger of claim 16, wherein the at least one temperature adjusting element is at least one of a heating element to heat the second working fluid to a desired temperature and a cooling element to cool the second working fluid to a desired temperature. The heat exchanger of claim 16, wherein the first working fluid is a refrigerant and the second working fluid is one of a motor fluid and a battery coolant.

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