JP2016017737A - TED heat exchanger - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a TED heat exchanger.SOLUTION: A TED heat exchanger comprises a cooling tube and a heat radiation tube each having a tubular-shape with a fluid passage formed therein. When a plurality of cooling tubes and heat radiation tubes are continuously arranged, the TED heat exchanger comprises: a plate part where the cooling tubes and the heat radiation tubes are alternatively arranged; a cooling flow-in tank and a cooling discharge tank which are connected to an inlet and an outlet of the cooling tube, respectively; a radiation heat flow-in tank and a radiation heat discharging tank connected to the inlet and the outlet of the heat radiation tube, respectively; and a thermoelectric element having a cooling surface and a heat radiation surface, and placed between the cooling tube and the heat radiation tube, the cooling surface being in surface contact with the cooling tube, the heat radiation surface being in surface contact with the heat radiation tube.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a new concept thermoelectric device (TED: Thermo-Electric Device) heat exchanger that can improve cooling performance and heat dissipation performance.

  The present invention relates to a new concept TED heat exchanger that can improve cooling performance and remarkably improve heat dissipation performance.

  The thermoelectric element includes a cooling surface and a heat dissipation surface, and can artificially generate a temperature difference between the cooling surface and the heat dissipation surface by an electrical signal. In addition, when the polarity of electricity is changed, the roles of the cooling surface and the heat dissipation surface change.

  In recent years, various concepts have been proposed for heat exchangers using such thermoelectric elements, but the performance of the heat exchanger itself is not supported by the convenience of the thermoelectric elements and the simplification of the system.

  That is, in the case of a thermoelectric element, cooling performance can be ensured when heat radiation is sufficiently performed, but there is a limit to the performance of heat radiation, and thus the cooling performance is not sufficient for the use of electric power.

  The matters described as the background art described above are for the purpose of deepening the understanding of the background of the present invention, and those who have ordinary knowledge in the technical field recognize that it falls under the known prior art. Do not be done.

Korean Unexamined Patent Publication No. 2014-0000865

  An object of this invention is to provide the TED heat exchanger of the new concept which can improve cooling performance and can also improve heat dissipation performance remarkably.

  In order to achieve the above object, a TED heat exchanger according to the present invention comprises a cooling tube having a tube shape in which a fluid passage is formed and a heat radiating tube, and a plurality of cooling tubes and heat radiating tubes are provided continuously. The cooling plate and the heat radiating tube are alternately arranged, the cooling inflow tank and the cooling discharge tank connected to the cooling tube inlet and outlet, respectively, and the heat radiating tube inlet and outlet. It is composed of a cooling inflow tank and a radiation discharging tank, a cooling surface and a heat dissipation surface, and is arranged between the cooling tube and the heat dissipation tube. The cooling surface is attached to the cooling tube and the heat dissipation surface is the heat dissipation tube. And a thermoelectric element facing the surface.

  The inlet and outlet of the cooling tube may be formed to be opposite to each other with respect to the longitudinal center of the cooling tube.

  The inlet and outlet of the heat radiating tube may be formed so as to be located on opposite sides with respect to the center in the length direction of the heat radiating tube.

  The cooling tube and the heat radiating tube may be formed such that the inlet or the outlet is located on the opposite sides with respect to the center in the length direction of the tube.

  The cooling inflow tank or the cooling discharge tank is arranged adjacent to each other on the opposite side with respect to the center in the length direction of the heat radiation inflow tank or the heat radiation discharge tank, and the inlet or outlet of each cooling tube or the heat radiation tube. Can be linked.

  The plurality of inlets of the heat radiating tube may be connected together to the heat radiating inflow tank.

  The plurality of outlets of the heat radiating tube can be connected together to the heat radiating discharge tank.

  The plurality of cooling tubes can form a series of flow paths in which the plurality of cooling tubes are continuous by communicating with each other through the cooling inflow tank or the cooling discharge tank.

  The plurality of cooling tubes are divided into a first cooling set in which a fluid flows on one side and a second cooling set in which a fluid flows on the other side, and the first cooling set and the second cooling set have an inlet and an outlet arranged to each other. Can be configured in the opposite direction.

  The inlet of the first cooling set communicates with the outlet of the second cooling set in the cooling inflow tank or the cooling discharge tank, and the outlet of the first cooling set communicates with the inlet of the second cooling set in the cooling inflow tank or the cooling discharge tank. Can be.

  The first cooling set or the second cooling set may not communicate with the cooling set on the opposite side in the case of an inlet from which fluid is first introduced or an outlet from which the fluid is finally discharged.

  The cooling inflow tank and the cooling discharge tank are respectively connected to the ends of the cooling tubes, and a partition is provided inside the cooling inflow tank and the cooling discharge tank, so that the fluid continues through the first cooling set and the second cooling set. Zigzag flow paths can be formed.

  According to the TED heat exchanger of the present invention as described above, the temperature of the cooling fluid can be sufficiently lowered in the heat exchanger using the thermoelectric element, and the radiating fluid is quickly discharged. Thus, the performance of the thermoelectric device can be remarkably increased. This greatly increases the overall heat exchanger performance (COP) performance.

1 is a perspective view of a TED heat exchanger according to an embodiment of the present invention. It is a figure which shows the cooling side of the TED heat exchanger by the Example of this invention. It is a figure which shows the thermal radiation side of the TED heat exchanger by the Example of this invention. It is a figure which shows the tube and thermoelectric element of the TED heat exchanger by the Example of this invention.

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

  FIG. 1 is a perspective view of a TED heat exchanger according to an embodiment of the present invention, FIG. 2 is a view showing a cooling side of a TED heat exchanger according to an embodiment of the present invention, and FIG. 3 is according to an embodiment of the present invention. FIG. 4 is a view showing a heat dissipation side of a TED heat exchanger, and FIG. 4 is a view showing a tube and a thermoelectric element of a TED heat exchanger according to an embodiment of the present invention.

  The TED heat exchanger according to the present invention includes a cooling tube 100 having a tube shape with a fluid passage formed therein and a heat radiating tube 200, and a plurality of the cooling tubes 100 and the heat radiating tubes 200 are provided and arranged continuously. At this time, the plate portion in which the cooling tubes 100 and the heat radiating tubes 200 are alternately arranged, the cooling inflow tank 310 and the cooling discharge tank 320 respectively connected to the inlet and the outlet of the cooling tube 100, and the inlet of the heat radiating tube 200, The heat radiation inflow tank 410 and the heat radiation discharge tank 420 respectively connected to the outlet, the cooling surface and the heat radiation surface are arranged between the cooling tube 100 and the heat radiation tube 200, and the cooling surface is attached to the cooling tube 100. And a thermoelectric element 500 whose heat radiating surface is attached to the heat radiating tube 200; Including the.

  FIG. 4 shows a tube and a thermoelectric element, and the plate portion of the present invention comprises a plurality of tubes, and the tubes are divided into a cooling tube 100 and a heat radiating tube 200. Each tube has a tube shape in which a fluid passage is formed, and as shown in FIG. 4, a pair of upper and lower plates 10 are combined to form an internal space, and heat exchange with fluid is performed in the internal space. Pins 20 are provided, which can be joined by a method such as brazing.

  On the other hand, a plurality of the cooling tubes 100 and the heat radiating tubes 200 are provided continuously as shown in FIGS. Moreover, in the whole state couple | bonded like FIG. 1, the cooling tube 100 and the heat radiating tube 200 are arrange | positioned alternately.

  The thermoelectric elements 500 are arranged as shown in FIG. 4 between the cooling tubes 100 and the heat radiating tubes 200 arranged alternately in this way. In the case of FIG. 1, the thermoelectric element is hidden and cannot be seen, but it can be easily understood that the thermoelectric element 500 is provided between the cooling tube 100 and the heat radiating tube 200 with reference to FIG. 4. Further, the cooling surface of the thermoelectric element 500 is attached to the cooling tube 100, and the heat dissipation surface is attached to the heat dissipation tube 200, so that the fluid flowing through the cooling tube 100 can pass through the cooling surface of the thermoelectric element 500 disposed above and below. On the contrary, the fluid flowing through the heat radiating tube 200 radiates heat through the heat radiating surfaces of the upper and lower thermoelectric elements 500.

  1 to 3, the inlet 101 and the outlet 102 of the cooling tube 100 may be formed to be opposite to each other with respect to the center a in the length direction of the cooling tube 100. In addition, the inlet 201 and the outlet 202 of the heat radiating tube 200 can be formed to be located on opposite sides with respect to the center b in the length direction of the heat radiating tube 200. As a result, the fluid flowing through the cooling tube 100 and the heat radiating tube 200 can be conducted by sufficiently flowing through the entire area by forming the flow paths in diagonal lines. Further, by positioning the inlet 201 of the heat radiating tube 200 on the outlet 102 side of the cooling tube 100, it is possible to maintain the state in which the cooling fluid finally discharged is cooled to the maximum.

  As shown in FIG. 1, the cooling tube 100 and the heat radiating tube 200 may be formed such that the inlets or outlets are located on opposite sides of the tube with respect to the longitudinal centers a and b. Further, the cooling inflow tank 310 or the cooling discharge tank 320 is disposed adjacent to the heat radiation inflow tank 410 or the heat radiation discharge tank 420 on the opposite sides with respect to the centers a and b in the length direction of the tubes, It can be connected to the inlet or outlet of the tube 100 or the heat radiating tube 200. With this configuration, a compact size can be realized in the thickness direction of the heat exchanger, and the fluid can circulate uniformly over the entire area.

  On the other hand, as shown in FIG. 3, the plurality of inlets 201 of the heat radiating tube 200 may be connected together to the heat radiating inflow tank 410. Further, the plurality of outlets 202 of the heat radiating tube 200 can be connected to the heat radiating discharge tank 420 together. As a result, the heat dissipation fluid for heat dissipation flows in simultaneously from the inlet 201 on one side and is simultaneously discharged through the outlet 202 on the other side to form a plurality of straight flow paths, thereby increasing the flow velocity. Rapid heat dissipation can be performed, and the amount of heat radiated can be maximized.

  On the other hand, in the case of cooling as shown in FIG. 2, the plurality of cooling tubes 100 are connected to each other through the cooling inflow tank 310 or the cooling discharge tank 320 so that the plurality of cooling tubes 100 are continuous. A series of flow paths can be formed. That is, in the case of heat dissipation, a plurality of parallel flow paths are used to achieve a high flow rate and a large flow rate and heat dissipation, while in the case of cooling, cooling is applied to continuous cooling so that the flow paths are connected in a zigzag manner. Although the flow rate and flow rate are small, the cooling is increased accordingly.

  Specifically, the plurality of cooling tubes 100 are divided into a first cooling set A in which fluid flows on one side and a second cooling set B in which fluid flows on the other side, and the first cooling set A and the second cooling set. In B, the arrangement of the inlet and the outlet can be configured in opposite directions.

  The inlet of the first cooling set A communicates with the outlet of the second cooling set B in the cooling inflow tank 310 or the cooling discharge tank 320, and the outlet of the first cooling set A is the cooling inflow tank 310 or the cooling discharge tank 320. And can communicate with the inlet of the second cooling set B. However, the first cooling set A or the second cooling set B is configured not to communicate with the cooling set on the relative side in the case of the inlet through which the fluid is first introduced or the outlet from which the fluid is finally discharged.

  For this purpose, the cooling inflow tank 310 and the cooling discharge tank 320 are connected to the ends of the cooling tube 100, respectively, and partition walls 314 and 324 are provided inside the cooling inflow tank 310 and the cooling discharge tank 320, respectively. A zigzag flow path that continuously flows through the first cooling set A and the second cooling set B is formed.

  That is, in the embodiment shown in FIGS. 1 and 2, one partition wall 314, 324 is provided in each of the cooling inflow tank 310 and the cooling discharge tank 320 at different positions, so that the first cooling set A-second cooling. Set B-allows the flow path of the first cooling set A to be formed. Through this process, the cooling fluid is continuously cooled, and the temperature of the final discharge cooling fluid becomes very low, while the heat dissipation fluid realizes faster heat dissipation through multiple parallel flow paths and finally heat exchange The performance of the vessel should be very excellent.

  On the other hand, there is a method in which the cooling inflow tank 310 and the cooling discharge tank 320 are provided and the partition walls 314 and 324 are provided in the cooling inflow tank 310, but there is also a method in which a plurality of cooling inflow tanks or cooling discharge tanks are provided to form one flow path. That is, by designing the cooling inflow tank or the cooling discharge tank to be divided into a plurality of tanks, the same effects as the effects divided by the partition walls can be obtained. However, in this case, there may be a disadvantage that the number of parts increases and the number of assembly steps increases.

  According to the TED heat exchanger of the present invention as described above, the temperature of the cooling fluid can be sufficiently lowered in the heat exchanger using the thermoelectric element, and the radiating fluid is quickly discharged. Thus, the performance of the thermoelectric device can be remarkably increased. This greatly increases the COP performance of the overall heat exchanger.

  While the invention has been illustrated and described with reference to specific embodiments, it will be appreciated that the invention can be modified and varied in various ways without departing from the spirit of the invention provided by the following claims. Will be obvious to those of ordinary skill in the art.

100 Cooling tube 200 Radiating tube 500 Thermoelectric element

Claims (12)

It consists of a cooling tube and a heat radiating tube having a tube shape with a fluid passage inside, and when a plurality of cooling tubes and heat radiating tubes are provided and arranged continuously, the cooling tubes and the heat radiating tubes are alternately arranged. The plate part,
A cooling inflow tank and a cooling discharge tank respectively connected to the inlet and outlet of the cooling tube;
A heat radiation inflow tank and a heat radiation discharge tank respectively connected to the inlet and outlet of the heat radiation tube;
A TED comprising a cooling surface and a heat radiating surface, and disposed between the cooling tube and the heat radiating tube, the cooling surface being attached to the cooling tube, and the heat radiating surface being attached to the heat radiating tube; Heat exchanger.   2. The TED heat exchanger according to claim 1, wherein an inlet and an outlet of the cooling tube are formed to be opposite to each other with respect to a center in a length direction of the cooling tube.   2. The TED heat exchanger according to claim 1, wherein an inlet and an outlet of the heat radiating tube are formed so as to be positioned on opposite sides with respect to a center in a length direction of the heat radiating tube.   2. The TED heat exchanger according to claim 1, wherein the cooling tube and the heat radiating tube are formed such that an inlet or an outlet is positioned on opposite sides with respect to a center in a length direction of the tube.   The cooling inflow tank or the cooling discharge tank is arranged adjacent to each other on the opposite side with respect to the center in the length direction of the heat radiation inflow tank or the heat radiation discharge tank, and the inlet or outlet of each cooling tube or the heat radiation tube. The TED heat exchanger according to claim 4, wherein the TED heat exchanger is connected.   The TED heat exchanger according to claim 1, wherein a plurality of inlets of the heat radiating tube are connected to a heat radiating inflow tank together.   The TED heat exchanger according to claim 1, wherein a plurality of outlets of the heat radiating tube are connected together to a heat radiating discharge tank.   The plurality of cooling tubes form a series of flow paths in which a plurality of cooling tubes are continuous by communicating with each other through a cooling inflow tank or a cooling discharge tank. The TED heat exchanger as described.   The plurality of cooling tubes are divided into a first cooling set in which a fluid flows on one side and a second cooling set in which a fluid flows on the other side, and the first cooling set and the second cooling set have an inlet and an outlet arranged to each other. The TED heat exchanger according to claim 1, wherein the TED heat exchanger is configured in an opposite direction.   The inlet of the first cooling set communicates with the outlet of the second cooling set in the cooling inflow tank or the cooling discharge tank, and the outlet of the first cooling set communicates with the inlet of the second cooling set in the cooling inflow tank or the cooling discharge tank. The TED heat exchanger according to claim 9, wherein   The first cooling set or the second cooling set is not in communication with the cooling set on the opposite side in the case of an inlet through which fluid is first introduced or an outlet from which the fluid is finally discharged. TED heat exchanger.   The cooling inflow tank and the cooling discharge tank are respectively connected to the ends of the cooling tubes, and a partition is provided inside the cooling inflow tank and the cooling discharge tank, so that the fluid continues through the first cooling set and the second cooling set. The TED heat exchanger according to claim 11, wherein the TED heat exchanger forms a zigzag flow path.

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