DE202011002989U1 - Thermoelectric cooling assembly - Google Patents

Abstract

A thermoelectric cooling assembly comprising: a heat dissipating plate device (1) which is hollow and has two opposing surfaces; two opposite sides; two heat dissipating surfaces (111, 131) respectively formed on the opposite surfaces of the heat dissipating plate device (10); an inlet (15) formed on one of the sides of the heat exchanging plate device (10) and having a threaded hole (151) formed through the inlet (15); an outlet (16) formed on one of the sides of the heat exchanging plate device (10) opposite to the inlet 815) and having a threaded hole (161) formed through the outlet (16); a channel (14) formed in a zigzag shape in the heat dissipating plate device (10) connected to the threaded holes (151, 161) and having a zigzag flow direction; and a plurality of cooling fins (17) provided with cooling fins fixed in the channel (14) at intervals, each cooling fins (17) having a top end, a bottom, two opposite ends and several gaps (171), .. .

Description

The present utility model relates to a thermoelectric cooling assembly, and more particularly to a thermoelectric cooling assembly having increased cooling efficiency.

A conventional thermoelectric cooling assembly has a water cooled heat exchanger and a plurality of thermoelectric cooling chips. Each thermoelectric cooling chip has a cold end and a warm end which is fixedly mounted on the water cooled heat exchanger. In use, the thermoelectric cooling chips of the thermoelectric cooling assembly are cooled in a refrigeration system.

However, the water (liquid) in the water-cooled heat exchanger has only contact with the inner walls of the tubes or plate of the water-cooled heat exchanger, and therefore, the effective heat-dissipating area of the thermoelectric cooling assembly is small and can not be further increased. Consequently, the cooling efficiency of the conventional thermoelectric cooling assembly is insufficient and should be further improved.

To overcome the shortcomings, the present utility model provides a thermoelectric cooling assembly which alleviates the aforementioned problems.

The main objective of the utility model is to provide a thermoelectric cooling assembly with increased cooling efficiency.

A thermoelectric cooling assembly has a heat dissipating plate device, a thermoelectric device and a Kreislaufvorrrichtung. The heat-dissipating plate device is a hollow plate and has a channel and a plurality of cooling fins provided with cooling fins. The channel is zigzag-mounted in the heat-dissipating plate device to allow the passage of a liquid. The cooling fins are mounted in the duct. The cooling fins increase the heat-dissipating surfaces with which the liquid makes contact. Thus, the heat can be quickly dissipated from the heat-dissipating disk device. As a result, the cooling efficiency of the thermoelectric cooling assembly according to the present utility model is increased.

Other objects, advantages and novel features of the utility model will become more apparent from the following detailed description when read in conjunction with the appended drawings.

In the drawings

1 Fig. 13 is an exploded perspective view of a first embodiment of the thermoelectric cooling assembly according to the present invention;

2 is a schematic diagram of a thermoelectric cooling assembly according to 1 ;

3 FIG. 12 is a perspective view of a heat-dissipating plate device of the thermoelectric cooling assembly according to FIG 1 ;

4 FIG. 11 is an exploded perspective view of the heat-dissipating plate device of the thermoelectric cooling assembly. FIG 3 ;

5 Figure 11 is a top plan view of a subsection of the heat dissipating plate device of the thermoelectric cooling assembly 3 ;

6 is an enlarged side view of the thermoelectric cooling assembly according to 2 ;

7 Fig. 10 is an enlarged top view of a subsection of the heat dissipating disk device in operation 2 ;

8th Fig. 13 is an exploded perspective view of a second embodiment of the thermoelectric cooling assembly according to the present invention; and

9 is an enlarged side view of the second embodiment of the thermoelectric cooling assembly according to 8th ,

Detailed description of the preferred embodiment

Regarding the 1 to 4 For example, the first embodiment of a thermoelectric cooling assembly according to the present invention consists of a heat-dissipating plate 10 , a thermoelectric device 20 and a circulatory device 30 ,

The heat-dissipating disk device 10 is rectangular and has two opposite surfaces, two opposite sides, one bottom plate 11 , a middle case 12 , an upper sheet 13 , a channel 14 , an inlet 15 , an outlet 16 and a plurality of cooling fins provided with cooling fins 17 ,

The floor panel 11 is rectangular and made of metal and has a top surface, a bottom surface and a heat-dissipating surface 111 formed on the lower surface of the floor panel 11 ,

The middle case 12 is firmly on the upper surface of the floor panel 11 attached by adhesive, is hollow and has a frame 121 , a first partition 122 and a second partition 123 , The frame 121 is firmly attached to the upper surface of the floor panel 11 attached and is rectangular and made of metal. The first partition 122 and the second partition 123 are stuck to the frame 121 attached to an inner cavity of the middle housing 12 to create the zigzag channel 14 form.

The upper sheet 13 is rectangular and made of metal, has a shape that matches the shape of the floor panel 11 fits and is firmly on the housing 121 , the first partition 122 and the second partition 123 attached to the canal 14 close. The upper sheet 13 has a top surface and a heat-dissipating surface 131 resting on the upper surface of the upper sheet 13 is trained. Consequently, the heat-dissipating surfaces 111 . 131 respectively corresponding to the opposite surfaces of the heat-dissipating plate device 10 educated.

In further relation to 5 is the channel 14 in the heat-dissipating disk device 10 formed and has a zigzag flow direction with three extended sections 142 and two curve sections 141 , Every curve section 141 is with two adjacent sections 142 connected.

The inlet 15 and the outlet 16 are respectively on the opposite sides of the heat-dissipating disk device 10 educated. The inlet 15 is firmly on the floor panel 11 , the housing 121 and the top sheet 13 attached with adhesive and has a threaded hole 151 passing through the inlet 15 is formed and with the channel 14 wrong.

The outlet 16 is firmly on the floor panel 11 , the housing 121 and the top sheet 13 attached with adhesive and has a threaded hole 161 passing through the outlet 16 is formed and with the channel 14 wrong. After floor panel 11 , the middle case 12 , the upper sheet 13 , the inlet 15 and the outlet 16 were assembled by adhesive, a polishing process is applied to the heat-dissipating plate device to seal seams on the heat-dissipating plate device 10 have formed, remove.

The cooling fins provided with cooling fins 17 are stuck in the channel 14 at the enlarged sections 142 appropriate. Each heatsink with cooling fins 17 It is made of metal and has an upper end, a bottom, two opposite ends and several gaps 171 , The top, bottom, and ends of each heatsink fins 17 are fixed to the middle case 12 and upper sheet metal 13 connected by adhesive. The gaps 171 each cooling fin provided with cooling fins 17 are formed at intervals by the heat sink provided with cooling fins and extend along the flow direction in the channel 14 ,

In relation to 1 and 6 becomes the thermoelectric device 20 firmly with the heat-dissipating disk device 10 connected and has several thermoelectric cooling chips 21 , Each thermoelectric cooling chip 21 is rectangular and has a cool end and a warm end, which are firmly connected on the heat-dissipating surface 131 of the upper sheet 13 are. The thermoelectric cooling chips 21 are arranged in a matrix pattern.

In relation to 2 . 6 and 7 is the circulatory device 30 firmly with the heat-dissipating disk device 10 connected and has a pipe 31 , a pump 32 , a fan 33 and a liquid 34 , The pipe 31 has a central segment, a heat-dissipating section 311 and two ends. The heat-dissipating section 311 is at the central segment of the pipe 31 trained and is meandering. The ends of the pipe 31 are each firm with the threaded holes 151 . 161 connected. The pump 32 is stuck to the pipe 31 connected in a row. The fan 33 adjoins the heat-dissipating section 311 of the pipe 31 , The fan can move air towards the heat dissipating section 311 bubbles to increase a heat-dissipating effect. The liquid 34 is in the channel 14 and the tube 31 cast.

In operation, the thermoelectric cooling assembly of the present utility model is placed in a refrigerator or refrigerator. Each thermoelectric cooling chip 21 and the pump 32 are electrically connected. When heat is supplied to the thermoelectric cooling assembly according to the present utility model, the liquid flows 34 through the channel 14 to remove heat from the heat-dissipating disk device 10 to transport away and is through the heat-dissipating section 311 cooled. As a result, heat can be continuously discharged.

The cooling fins provided with cooling fins 17 increase the heat-dissipating area with which the liquid 34 Being in contact is high, allowing heat to dissipate quickly from the heat-dissipating disk device 10 can be removed and derived.

As a result, the cooling efficiency of the thermoelectric cooling assembly of the present invention is increased.

In relation to 8th and 9 a second embodiment of the thermoelectric cooling assembly according to the present utility model is basically identical to the first embodiment, except that two thermoelectric devices 20 . 20A be used and respectively firmly on the heat-dissipating surfaces 111 . 131 are attached.

From the above description, it should be noted that the present utility model has the following advantages: the gaps 171 increase the outer heat-dissipating surface of the cooling fins provided with cooling fins 17 with which the liquid 34 Contact has, allowing heat to pass through the liquid faster 34 can be removed. As a result, the cooling efficiency of the thermoelectric cooling assembly according to the present invention is increased.

Claims (3)

A thermoelectric cooling assembly comprising: a heat dissipating disk device ( 1 ), which is hollow and has two opposite surfaces; two opposite sides; two heat-dissipating surfaces ( 111 . 131 ) respectively on the opposite surfaces of the heat-dissipating disk device (FIG. 10 ) educated; an inlet ( 15 ) formed on one of the sides of the heat exchanging disk device ( 10 ) and has a threaded hole ( 151 ) formed through the inlet ( 15 ); an outlet ( 16 ) formed on one of the sides of the heat exchanging disk device ( 10 ), opposite the inlet 815 ) and has a threaded hole ( 161 ), formed through the outlet ( 16 ); a channel ( 14 ) which zigzag in the heat dissipating disk device ( 10 ) is formed, connected to the threaded holes ( 151 . 161 ) and has a zigzag flow direction; and a plurality of cooling fins provided with cooling fins ( 17 ) fixed in the channel ( 14 ) are arranged in an interval-like manner, whereby each cooling body provided with cooling fins ( 17 ) an upper end, a bottom, two opposite ends and several gaps ( 171 ), which by the cooling fins provided with heat sink ( 17 ) and extend along the flow direction of the channel ( 14 ), wherein the upper end, the bottom and the ends of each Kühlköpern provided with cooling fins ( 17 ) fixed to the heat-dissipating disk device ( 10 ) are connected; a thermoelectric device ( 20 . 20A ) firmly fixed to the heat-dissipating disk device ( 10 ) and several thermoelectric cooling chips ( 21 . 21A ), each thermoelectric cooling chip ( 21 . 21A ) has a cool end and a warm end fixed to one of the heat-dissipating surfaces ( 111 . 131 ) connected is; and a circulating device ( 30 ) firmly fixed to the heat-dissipating disk device ( 10 ), consisting of a tube ( 31 ), consisting of a central segment; a heat-dissipating section ( 311 ) formed on the central segment of the tube ( 31 ); and two ends, each correspondingly fixed with the threaded holes ( 151 . 161 ) connected; a pump ( 32 ), which are fixed to the pipe ( 31 ) is connected in a serial fashion; a blower ( 33 ) which is sent to the heat-dissipating section ( 311 ) of the pipe ( 31 ) adjoins; and a liquid ( 34 ), which are in the channel ( 14 ) and the pipe ( 31 ) is filled. The thermoelectric cooling assembly of claim 1, wherein the heat-dissipating disk device ( 1 ) is rectangular; and the channel ( 14 ) three extended sections ( 142 ), in which the heat sinks provided with cooling fins ( 17 ) are attached; and two curve sections ( 141 ), each curve section ( 141 ) with two adjacent sections ( 142 ) has The thermoelectric cooling assembly according to claim 1 or 2, wherein the heat dissipating section (FIG. 311 ) is wound; and two thermoelectric devices ( 20 . 20A ) and in each case firmly fixed to the heat-dissipating surfaces ( 111 . 131 ) are mounted.

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