DE102014114185A1 - Heat exchanger with thermoelectric elements - Google Patents

Abstract

A heat exchange device having thermoelectric elements (100, 100 ') may include a heat absorption line (300) that transfers heat from one side (301) thereof to another side (302) thereof, a pair of thermoelectric elements (100, 100'). ) which may be provided on the other side of the heat-absorbing duct (300) with respect to the heat-absorbing duct facing each other, each of the thermoelectric elements having a heat-absorbing surface in contact with the heat-absorbing duct (300), a pair of heat-exhaust ducts (200 200 '), wherein each of the heat-removing ducts on a side thereof has a surface in contact with a heat-removing surface of the respective thermoelectric element, and heat-exchanging elements on the one side of the heat-absorbing duct and the heat-exchanging ducts (220, 240, 320, 340) other side (202) of the heat removal lines are provided.

Description

Background of the invention

Field of the invention

The present invention relates to a heat exchanger / heat exchanger having thermoelectric elements, which is compact even with (installed) thermoelectric elements, is simple in design and manufacture and has good efficiency, and a manufacturing method of the same.

Description of the related art

Heretofore, a heat exchanger / heat exchanger using thermoelectric elements has a plate structure. In a plate structure, a passage for coolant is provided on one side of the plate, and air-side heat radiating fins / heat radiating fins are installed on the other side where the heat is radiated.

However, such a plate structure has disadvantages in that it is too heavy and a thickness of a water-side contact portion can not be reduced, so that overheating can be caused when thermoelectric elements are in operation.

As another structure of heat exchangers with thermoelectric elements, there is a core structure. In a core structure, there are pipes on both sides thereof, a plurality of pipes are connected / arranged between the pipes, thermoelectric elements are on / on the pipes, and air side heat radiation fins are on / on the thermoelectric elements. However, such a core structure is difficult to manufacture because, according to an assembly scheme, the thermoelectric elements should be mounted after the core has been assembled, and therefore too many quality variations are caused.

The present invention is directed to a structure of a heat exchanger having thermoelectric elements in which a coolant flows on / on one side thereof while air flows on another side thereof, and more particularly, on a structure in which one Thermal resistance on the coolant side is minimized, thermoelectric elements can be easily mounted / mounted when the heat exchanger is assembled, and a quality control can be performed individually. Further, the present invention is directed to a structure in which costs of molds by means of shared elements are minimized.

The information disclosed in this Background of the Invention section is only for the better understanding of the general background of the invention and should not be construed as an affirmative or any suggestion that this information constitutes prior art that is already known to those skilled in the art ,

Explanation of the invention

Numerous aspects of the present invention are directed to providing a thermoelectric element heat exchanger / heat exchanger which is compact even with (installed) thermoelectric elements, is simple in design and manufacturable and has good efficiency, and a manufacturing method thereof.

In one aspect of the present invention, a heat exchanger device / heat transfer device with thermoelectric elements (eg Peltier elements) may have a heat absorption line (eg with a plate-like structure) which transfers heat from one (eg longitudinal) side thereof to another (eg longitudinal direction) ) Side thereof (eg, absorbs heat and transfers, for example, by heat conduction) a pair of thermoelectric elements provided on the other side of the heat-absorbing duct with respect to the heat-absorbing duct facing each other (eg, opposite sides of the heat-absorbing duct in the thickness direction); wherein each of the thermoelectric elements has a heat-absorbing surface in contact with the heat-absorbing duct, a pair of heat-removing ducts / heat-output ducts (eg, heat-dissipating ducts) (eg, having a plate-like structure, eg, W RME receive and e.g. transferring by means of heat conduction), each of the heat-removing ducts on a (longitudinal) side thereof having a surface in contact with a heat-dissipating surface / heat-output surface (eg, a heat-transmitting surface) of each associated thermoelectric element, and heat exchange elements / elements (eg, for heat exchange / heat transfer) to fluids, for example) provided on one (longitudinal) side of the heat-absorbing duct and on another (longitudinal) side of the heat-dissipating ducts.

The heat-absorbing duct and the heat-removing ducts may have a plate shape.

The other (longitudinal) side of the heat absorption duct is at least equal (eg with respect to a direction of gravity), for example (ie at the same height) with or higher than the one (longitudinal) side thereof.

The pair of heat removal conduits is e.g. with respect to the heat-absorbing duct, symmetrically (for example, the heat-dissipating ducts are arranged symmetrically with respect to the heat-absorbing duct) so that the heat-exhaust ducts on the other (longitudinal) side of the heat-absorbing duct face each other.

The other (longitudinal) side of the heat removal duct is (e.g., with respect to a direction of gravity) e.g. at least equal to or higher than the one (longitudinal) side thereof.

The heat exchange elements are e.g. Heat exchange fins / heat exchange fins.

The heat exchange fins are in contact with two surfaces of the heat absorbing duct as the heat exchange elements on the one (longitudinal) side of the heat absorbing duct.

The heat exchange fins are, as the heat exchange elements, in contact with two surfaces of the heat exhaust ducts on the other (longitudinal) side thereof, with adjacent heat exhaust ducts sharing the intermediate heat exchange fins.

A heat dissipation channel / heat output channel is connected to a front side of the heat exhaust ducts, and a heat absorption duct is connected to a front side of the heat absorption duct.

The heat removal ducts and the heat absorption duct form a right angle between each other.

In another aspect of the present invention, a heat exchange device / heat transfer device having thermoelectric elements (eg Peltier elements) is formed with heat exchange modules / heat transfer modules arranged parallel to each other, each of the heat exchange modules may include a heat absorption line (eg, having a plate-like structure). which transfers heat from one (eg, lengthwise) side thereof to another (eg, lengthwise) side thereof (eg, absorbs heat and transfers, for example, by heat conduction), a pair of thermoelectric elements located on the other (longitudinal) side of the Heat absorption line with respect to the heat absorption line are provided opposite each other, wherein each of the thermoelectric elements has a heat absorbing surface in contact with the heat absorption line, a pair of heat removal lines / heat output lines (eg Wärmeablei each of the heat dissipation pipes on a (longitudinal) side thereof has a surface in contact with a heat dissipation surface / heat output surface (e.g. a heat transfer surface) of the respective thermoelectric element, and heat exchange elements / heat transfer members (eg, for heat exchange / heat transfer with / to eg fluids) provided on one (longitudinal) side of the heat absorption duct and on the other (longitudinal) side of the heat exhaust duct ,

Adjacent heat exchange modules can be a heat transfer part (eg a heat transfer connection part or a heat transfer weight part, eg a part which has a high heat conductivity and / or eg has a high weight and / or eg a large heat capacity) between facing surfaces at the one (longitudinal) Have side of adjacent heat removal lines.

Adjacent heat exchange modules share the heat exchange elements between facing surfaces on the one (longitudinal) side of adjacent heat absorption conduits.

Adjacent heat exchange modules share the heat exchange elements between facing surfaces on the other (longitudinal) side of the adjacent heat removal conduits.

The one (longitudinal) side of the heat-absorbing duct is lower (eg, with respect to a direction of gravity) than the other (longitudinal) side thereof, and the thermoelectric elements are connected to the other side and the one (longitudinal) side That is, the heat dissipation piping is lower (eg, with respect to a gravity direction) than the other (longitudinal) side thereof, and thermoelectric elements are connected to the one (longitudinal) side.

A heat dissipation channel / heat output channel is connected to a front side of the heat exhaust ducts, and a heat absorption duct is connected to a front side of the heat absorption duct.

The heat removal ducts and the heat absorption duct form a right angle between each other.

The methods and apparatus of the present invention have other features and Advantages which will become apparent or more fully explained in the accompanying drawings, which are incorporated herein, and the following detailed description, which together serve to explain certain principles of the present invention.

Brief description of the drawings

1 FIG. 15 is a perspective view of a thermoelectric element heat exchanger according to an exemplary embodiment of the present invention. FIG.

2 FIG. 10 is an exploded (schematic) view of the heat exchanger according to the exemplary embodiment of the present invention. FIG.

3 and 4 show examples of a heat exchanger installation with thermoelectric elements according to an exemplary embodiment of the present invention.

It should be understood that the appended drawings are not necessarily to scale, presenting a somewhat simplified representation of various features illustrative of the basic principles of the invention. The specific design features of the present invention, including, but not limited to, e.g. Concrete dimensions, directions, locations and shapes as disclosed herein are in part dictated by the particular intended application and usage environment.

Throughout the numerous figures of the drawing, reference numbers in the figures indicate the same or similar parts of the present invention.

Detailed description

Reference will now be made in detail to various embodiments of the present invention, examples of which are illustrated in the accompanying drawings and described below. While the invention has been described in conjunction with the exemplary embodiments, it is to be understood that the present description is not intended to limit the invention to those exemplary embodiments. On the contrary, the invention is intended to cover not only the exemplary embodiments but also various alternatives, changes, modifications and other embodiments which may be included within the spirit and scope of the invention as defined by the appended claims.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The 1 FIG. 15 is a perspective view of a thermoelectric element heat exchanger according to an exemplary embodiment of the present invention. FIG 2 FIG. 10 is an exploded (schematic) view of the heat exchanger according to the exemplary embodiment of the present invention and FIGS 3 and 4 13 are views showing examples of a thermoelectric element heat exchanger installation according to an exemplary embodiment of the present invention.

A thermoelectric element heat exchanger according to an exemplary embodiment of the present invention comprises: a heat absorption pipe 300 which heat from one side 301 to another page 302 transferred, a pair of thermoelectric elements 100 and 100 ' , which on the other side 302 the heat absorption line 300 are provided, wherein heat absorbing surfaces in contact with the heat absorption line 300 have a pair of heat pipes 200 and 200 ' each of which has an area on one side 201 in contact with the heat dissipation surface of the respective thermoelectric element 100 and 100 ' has, and heat exchange elements 220 . 240 . 320 and 340 , which on one side 301 the heat absorption line 300 or on another page 202 the heat removal line 200 and 200 ' are provided.

The thermoelectric elements 100 and 100 ' When receiving electricity, they serve to absorb heat to spend from one side to the other side. Therefore, one side thereof serves as a heat absorbing surface and serves another side thereof as a heat dissipation surface.

In such a heat exchanger, which the thermoelectric elements 100 and 100 ' In particular, the efficiency / performance (eg, heat transfer performance) of the heat exchanger depends on how efficiently heat is dissipated / discharged from the heat removal surfaces during cooling operation. Therefore, in such a heat exchanger using the thermoelectric elements, it is necessary that the area or the weight of the heat dissipation side be larger than that of the heat absorption side (eg, due to the greater weight of the heat dissipation side, the heat capacity of the heat dissipation side with respect to the heat absorption side may be larger ). For this purpose, a heat exchanger with thermoelectric elements according to an exemplary embodiment of the present invention: a heat absorption line 300 which heat from one side 301 to another page 302 transferred, a pair of thermoelectric elements 100 and 100 ' , which on both sides of the heat absorption line 300 on the other side 302 thereof, wherein heat-absorbing surfaces (the thermoelectric elements) are in contact with the heat-absorbing duct 300 , a pair of heat pipes 200 and 200 ' , each one on one side 201 a surface in contact with the heat dissipation surface of the respective thermoelectric element 100 and 100 ' has, and heat exchange elements 220 . 240 . 320 and 340 , which on one side 301 the heat absorption line 300 or on another page 202 the heat removal lines 200 and 200 ' are provided.

The heat absorption pipe 300 transfers heat from one side 301 to the other side 302 , Next are the thermoelectric elements 100 and 100 ' on the other side 302 the heat absorption line 300 with respect to the heat absorption pipe 300 provided opposite to each other (eg, on opposite sides of the heat absorption line in the thickness direction). With this configuration, the thermoelectric elements receive 100 and 100 ' Heat from a heat absorption line 300 to dissipate the heat through the heat dissipation surfaces on the (respective) outer sides.

The heat dissipation surfaces of the thermoelectric elements 100 and 100 ' are on one side 201 in contact with a pair of heat dissipation pipes 200 and 200 ' , Accordingly, heat is transmitted through a (eg, only) heat-absorbing duct 300 whereas heat is absorbed by the pair of thermoelectric elements 100 and 100 ' and the pair of heat dissipation pipes 200 and 200 ' is dissipated / drained thereby improving efficiency.

The heat exchange elements 220 . 240 . 320 and 340 are on one side 301 the heat absorption line 300 and on the other side 202 the heat removal lines 200 and 200 ' provided so that the heat (eg with fluids) is replaced.

The heat absorption pipe 300 and the heat removal lines 200 and 200 ' may have a plate shape, and the heat exchange elements 220 . 240 . 320 and 340 may be heat exchange fins / heat exchange fins.

Like in the 2 Especially shown is one side 301 the heat absorption line 300 be the same height (arranged) or higher (arranged) than the other side 302 , With this configuration, heat is transferred more efficiently because it is transferred from a lower position (up) to a higher position. Likewise, the pair is heat removal pipes 200 and 200 ' with respect to the heat absorption pipe 300 symmetrical (eg, the heat dissipation pipes are arranged symmetrically with each other on opposite sides of the heat absorption pipe) so as to face each other, and the other side 202 the heat removal lines 200 and 200 ' may also be at least the same height (arranged) or higher (arranged) as the one side 201 ,

In addition, on / on both side surfaces of the heat absorption line 300 on one side 301 Heat exchange ribs as heat exchange elements 320 and 340 to be in contact with it. Next can on / on both sides of the heat dissipation pipes 200 and 200 ' on the other side 202 Heat exchange ribs as heat exchange elements 220 and 240 to be in contact with it. Neighboring heat pipes 200 and 200 ' can share heat exchange ribs.

The 1 shows a general structure of the heat exchanger. The thermoelectric element heat exchanger according to an exemplary embodiment of the present invention may be formed with heat exchange modules A (and B) arranged in parallel with each other, each module comprising: a heat absorption duct 300 which heat from one side 301 to another page 302 transferred, a pair of thermoelectric elements 100 and 100 ' , which on both sides of the heat absorption line 300 on the other side 302 thereof, wherein heat absorbing surfaces (of the thermoelectric elements 100 and 100 ' ) with the heat absorption pipe 300 in contact, a pair of heat dissipation pipes 200 and 200 ' each of which has an area on one side 201 in contact with the heat dissipation surface of the respective thermoelectric element 100 and 100 ' has, and heat exchange elements 220 . 240 . 320 and 340 , which on one side 301 the heat absorption line 300 or on another page 202 the heat removal lines 200 and 200 ' are provided.

Further, adjacent heat exchange modules A and B may be a heat transfer part 400 (For example, a part which has a large thermal conductivity and / or eg has a high weight and / or eg has a large heat capacity) on one side 201 have between the mutually facing surfaces of the adjacent heat removal lines 200 and 200 ' , With this configuration, adjacent thermoelectric elements and adjacent heat dissipation pipes at the heat dissipation / heat dissipation side are thermally bonded to each other so that they (eg, the thermoelectric elements and the adjacent heat dissipation pipes) have a high weight (eg, a large heat transmission coefficient and / or a large heat capacity) and therefore Efficiency is increased.

Next adjacent heat exchange modules A and B, the heat exchange element 340 to use together, which is arranged between the mutually facing surfaces of the adjacent heat absorption lines on one side. Next adjacent heat exchange modules A and B, the heat exchange element 220 ' to use together, which between the mutually facing surfaces of the adjacent heat removal lines on the other side 202 is arranged. With this configuration, the heat exchange efficiency / heat transfer efficiency is increased.

The 3 and 4 show examples of a heat exchanger installation with thermoelectric elements according to an exemplary embodiment of the present invention depending on a duct arrangement through which air flows. In particular, the shows 3 a linear channel arrangement in which a heat output channel / heat removal channel 20 in line with a heat absorption channel 30 is located (ie, the heat removal channel and the heat absorption channel are parallel to each other, for example, arranged one above the other), and shows the 4 a curved duct arrangement in which the heat output duct / heat removal duct 20 and the heat absorption channel 30 form a 90 ° angle between each other. Likewise, in both figures, one side of the heat-absorbing duct is lower than the other side thereof, and thermoelectric elements are connected to the other side. One side of the heat dissipation pipe is lower than the other side thereof, and thermoelectric elements are connected to one side. Accordingly, heat is naturally transferred from a lower position (upward) to a higher position, so that the heat transfer efficiency is increased.

As described above, according to the thermoelectric element heat exchanger configured as described above, the performance and the efficiency of the thermoelectric element can be maximized, the position of e.g. a radiator (e.g., a radiator for an automobile such as an engine radiator) and / or a radiator are freely set, and heat exchange fins may be shared, thereby enabling a cost reduction. For ease of explanation and detailed definition of the appended claims, the terms "upper (e)", "lower (e)", "inner" and "outer / outer" are used to refer to features of the exemplary embodiments with reference to FIG To describe positions of these features shown in the drawings.

The foregoing descriptions of certain exemplary embodiments of the present invention have been presented for purposes of illustration and description. They are not intended to be exhaustive or to limit the invention to the precise forms disclosed, and obviously many changes and modifications are possible in light of the above teachings. The exemplary embodiments have been chosen and described to describe certain principles of the invention and its practical applicability, thereby enabling one skilled in the art to make and use various exemplary embodiments of the present invention, as well as various alternatives and modifications thereof. It is intended that the scope of the invention be defined by the appended claims and their equivalents.

Claims (17)

A heat exchanger device with thermoelectric elements ( 100 . 100 ' ), comprising: a heat-absorbing duct ( 300 ), which heat from one side ( 301 ) to another page ( 302 ), a pair of thermoelectric elements ( 100 . 100 ' ), which on the other side ( 302 ) of the heat absorption line ( 300 ) with respect to the heat absorption line ( 300 ) are provided opposite each other, wherein each of the thermoelectric elements ( 100 . 100 ' ) a heat-absorbing surface in contact with the heat-absorbing duct (16) 300 ) has a pair of heat dissipation pipes ( 200 . 200 ' ), each of the heat removal lines ( 200 . 200 ' ) on one side ( 201 ) thereof has a surface in contact with a heat dissipation surface of the respective thermoelectric element ( 100 . 100 ' ), and heat exchange elements ( 220 . 240 ; 320 . 340 ), which on one side ( 301 ) of the heat absorption line ( 300 ) and on the other side ( 202 ) of the heat removal lines ( 200 . 200 ' ) are provided. The heat exchange device according to claim 1, wherein the heat absorption duct (16) 300 ) and the heat removal lines ( 200 . 200 ' ) have a plate shape. The heat exchanger device according to claim 1 or 2, wherein the other side ( 302 ) of the heat absorption line ( 300 ) at least equal to or higher than the one side ( 301 ) of which is arranged. The heat exchanger device according to any one of the preceding claims, wherein in the pair of heat dissipation pipes ( 200 . 200 ' ) the heat removal lines with respect to the heat absorption line ( 300 ) are symmetrical to each other, so that the heat removal lines on the other side ( 302 ) of the heat absorption line face each other. The heat exchanger device according to any one of the preceding claims, wherein the other side ( 202 ) of the heat removal line ( 200 . 200 ' ) at least equal to or higher than the one side ( 201 ) of which is arranged. The heat exchanger device according to any one of the preceding claims, wherein the heat exchange elements ( 220 . 240 ; 320 . 340 ) Are heat exchange ribs. The heat exchange device according to any one of the preceding claims, wherein heat exchange fins are used as the heat exchange elements (16). 320 . 340 ) in contact with two surfaces of the heat absorption line ( 300 ) on one side ( 301 ) of the heat absorption duct. The heat exchange device according to any one of the preceding claims, wherein heat exchange fins are used as the heat exchange elements (16). 220 . 240 ) in contact with two surfaces of the heat removal lines ( 200 . 200 ' ) on the other side ( 202 ) of the heat removal conduits and wherein adjacent heat removal conduits share the intermediate heat exchange ribs. The heat exchanger device according to any one of the preceding claims, wherein a heat removal channel ( 20 ) with a front side of the heat removal lines ( 200 . 200 ' ) and a heat absorption channel ( 30 ) with a front side of the heat absorption line ( 300 ) connected is. The heat exchanger device according to any one of the preceding claims, wherein the heat removal conduits ( 200 . 200 ' ) and the heat absorption line ( 300 ) form a right angle between each other. A heat exchanger device with thermoelectric elements ( 100 . 100 ' ), which is formed by means of parallel arranged heat exchange modules (A, B), wherein each of the heat exchange modules (A, B) comprises: a heat absorption line ( 300 ), which heat from one side ( 301 ) to another page ( 302 ), a pair of thermoelectric elements ( 100 . 100 ' ), which on the other side ( 302 ) of the heat absorption line ( 300 ) with respect to the heat absorption line ( 300 ) are provided opposite each other, wherein each of the thermoelectric elements ( 100 . 100 ' ) a heat-absorbing surface in contact with the heat-absorbing duct (16) 300 ) has a pair of heat dissipation pipes ( 200 . 200 ' ), each of the heat removal lines ( 200 . 200 ' ) on one side ( 201 ) thereof has a surface in contact with a heat dissipation surface of the respective thermoelectric element ( 100 . 100 ' ), and heat exchange elements ( 220 . 240 ; 320 . 340 ), which on one side ( 301 ) of the heat absorption line ( 300 ) and on the other side ( 202 ) of the heat removal line ( 200 . 200 ' ) are provided. The heat exchange device according to claim 11, wherein adjacent heat exchange modules (A, B) comprise a heat transfer part (16). 400 ) between mutually facing surfaces on one side ( 201 ) of adjacent heat removal lines ( 200 . 200 ' ) to have. The heat exchange device according to claim 11 or 12, wherein adjacent heat exchange modules (A, B) the heat exchange elements ( 320 . 340 ) between mutually facing surfaces on one side ( 301 ) of the adjacent heat absorption lines ( 300 ) together. The heat exchange device according to any one of claims 11 to 13, wherein adjacent heat exchange modules (A, B) the heat exchange elements ( 220 . 240 ) between facing surfaces on the other side ( 202 ) of the adjacent heat removal lines ( 200 . 200 ' ) together. The heat exchanger device according to any one of claims 11 to 14, wherein said one side ( 301 ) of the heat absorption line ( 300 ) lower than the other side ( 302 ) thereof and the thermoelectric elements ( 100 . 100 ' ) with the other side ( 302 ), and the one side ( 201 ) of the heat removal lines ( 200 . 200 ' ) lower than the other side ( 202 ) thereof and the thermoelectric elements with one side ( 201 ) are connected. The heat exchange device according to any one of claims 11 to 15, wherein a heat removal passage ( 20 ) with a front side of the heat removal lines ( 200 . 200 ' ) and a heat absorption channel ( 30 ) with a front side of the heat absorption line ( 300 ) connected is. The heat exchange device according to any one of claims 11 to 16, wherein the heat removal conduits ( 200 . 200 ' ) and the heat absorption line ( 300 ) form a right angle between each other.

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