KR102188733B1 - Cooling tank apparatus - Google Patents

Abstract

The present invention relates to a cooling tank device, and more particularly, to a cooling tank device capable of cooling a fluid using a thermoelectric element.
To this end, the present invention forms an inner space, the tank body in which the cooling medium is accommodated in the inner space; A coil flow path unit disposed in an internal space of the tank body to heat exchange with the cooling medium and having an inlet port through which fluid is introduced and an outlet port through which fluid is discharged; A cooling unit disposed below the tank body and including a thermoelectric element for cooling the tank body by being disposed to be connected to a lower surface of the tank body; A stirring unit disposed in the inner space and including an impeller for stirring the cooling medium and a driving motor for driving the impeller; And an upper cover unit coupled to an upper portion of the tank body, and in which the driving motor is disposed while supporting the coil passage unit in the inner space.

Description

Cooling tank device {COOLING TANK APPARATUS}

The present invention relates to a cooling tank device, and more particularly, to a cooling tank device capable of cooling a fluid using a thermoelectric element.

In general, a cooling tank device is used to drink drinking water, such as beer or purified water, while the drinker enjoys a cooler condition.

A cooling tank device using a general refrigeration cycle consists of a compressor, a condenser, a dryer, and an evaporator, and requires welding and refrigerant injection processes. However, such a cooler not only causes environmental pollution as a refrigerant is used, but also increases the volume of the product, and the noise caused by the use of a compressor is significant.

Accordingly, there is a need to develop a cooling tank device capable of obtaining a sufficient cooling effect without using a general refrigeration cycle using a compressor and minimizing the volume of the cooling tank device.

Republic of Korea Patent Publication No. 10-0934360 (Name of invention: drinking water cooling device, registered on December 30, 2009)

An object of the present invention is to solve the problems of the prior art, the present invention is to cool a fluid using a thermoelectric element, support the coil flow path unit through the upper cover unit, so that the drive motor can be mounted, the upper cover cover It is to provide a cooling tank device capable of obtaining a sufficient cooling effect and making the structure of the entire device compact by allowing the device to be disposed.

In order to achieve the object of the present invention described above, a cooling tank apparatus according to the present invention comprises: a tank body forming an inner space and receiving a cooling medium in the inner space; A coil flow path unit disposed in an internal space of the tank body to heat exchange with the cooling medium and having an inlet port through which fluid is introduced and an outlet port through which fluid is discharged; A cooling unit disposed below the tank body and including a thermoelectric element for cooling the tank body by being disposed to be connected to a lower surface of the tank body; A stirring unit disposed in the inner space and including an impeller for stirring the cooling medium and a driving motor for driving the impeller; And an upper cover unit coupled to an upper portion of the tank body, wherein the driving motor is disposed while supporting the coil passage unit in the inner space, wherein the upper cover unit includes: an upper cover body; In order to support the coil passage unit on the inner space, a coil passage unit fixing portion including a plurality of support blades protruding from a lower surface of the upper cover body in the direction of the inner space to be coupled to a part of the coil passage unit; It may include a; drive motor mounting portion provided in the upper central region of the upper cover body to mount the drive motor.

In the cooling tank apparatus according to the present invention, the upper cover body is formed to protrude upwardly from the outer circumference of the upper cover body, and may include an edge portion for forming an accommodation space inside the upper cover body.

In the cooling tank apparatus according to the present invention, the upper cover unit is installed to surround the outer circumferential surfaces of the plurality of support blades from the lower surface of the upper cover body, and is formed to protrude in the direction of the tank body, so that the upper cover unit and the upper part of the tank body Upper cover coupling portion to be coupled; A location identification groove formed in one side of the rim portion to easily check the locations of the inlet and outlets installed through the upper cover body; And an upper cover cover installed on the receiving space part while passing through the drive motor mounting part.

In the cooling tank apparatus according to the present invention, the cooling unit is disposed between the lower surface of the tank body and the upper surface of the thermoelectric element, cooled by heat exchange with the thermoelectric element, and the cooled temperature is controlled by the tank body. It further includes a heat transfer member for transferring to a lower surface, wherein the heat transfer member includes: a heat transfer member body fixed to a lower surface of the tank body; And a heat transfer member body fixing portion protruding from both side ends of the heat transfer member body toward an outer radial direction and having a bushing hole through which the coupling bushing protruding from the bottom surface of the tank body is provided; wherein the heat transfer member body comprises: It is fixed to the lower surface of the tank body, characterized in that the first coupling bolt is fixed while being screwed to the coupling bushing.

In the cooling tank apparatus according to the present invention, the heat sink unit is disposed to be connected to the thermoelectric element to radiate the thermoelectric element; And a support unit that is simultaneously coupled with the cooling unit and the heat sink unit to support the tank body.

In the cooling tank apparatus according to the present invention, the heat sink unit comprises: a cooling plate disposed to be in contact with a lower surface of the thermoelectric element, and having a plurality of cooling channels through which a refrigerant moves therein; A heat sink connected to the cooling plate to radiate the cooling plate; And a heat dissipation fan disposed on one side of the heat sink to help heat dissipation of the heat sink.

In the cooling tank apparatus according to the present invention, the support unit includes: a support unit body in which the thermoelectric element is disposed on an upper surface; A sliding coupling portion disposed to be spaced apart from the upper surface of the support unit body at a predetermined interval, and protruding along the longitudinal direction of the support unit body to slide the cooling plate; And a support unit main body fixing part protruding upwardly from the upper surface of the support unit body and coupled to the heat transfer member body fixing part, wherein the support unit body is fixed to the heat transfer member body fixing part, a second A fastening bolt is fixed while being screwed to the heat transfer member body fixing part through the support unit body fixing part.

In the cooling tank apparatus according to the present invention, an upper surface of the support unit body includes an inclined support part for obliquely supporting the cooling plate, and a lower surface of the heat transfer member facing the cooling plate with the thermoelectric element therebetween is It characterized in that it is formed inclined to correspond to the inclination angle of the cooling plate.

In the cooling tank device according to the present invention, further comprising a heat insulating cover formed to surround the outer circumferential surface of the tank body to prevent the temperature of the tank body from being taken to the outside, wherein the heat insulating cover is a portion corresponding to the heat radiating fan It is formed in, the square portion for limiting the movement path of the air so that the air moved by the heat dissipation fan is not moved to the rear side of the tank body; may include.

In the cooling tank apparatus according to the present invention, the support unit may further include a coupling guide member extending from one end of the support unit body to couple the support unit to an external device.

The cooling tank device according to the present invention cools the fluid using a thermoelectric element, supports the coil flow path unit through the upper cover unit, and allows the drive motor to be mounted, and allows the upper cover cover to be disposed, thereby providing sufficient cooling. At the same time, there is an effect that the structure of the entire device can be manufactured compactly.

In addition, in the cooling tank device according to the present invention, as a plurality of support wings provided in the upper cover unit are configured to support the coil flow path unit, the coil flow path unit can be firmly supported in the internal space of the tank body. It works.

In addition, the cooling tank device according to the present invention has the effect of being able to easily separate the cooling plate from the receiving unit as needed, since the cooling plates are coupled to the receiving unit by a sliding coupling method. have.

In addition, the cooling tank device according to the present invention can check the location of the inlet and outlet exposed to the outside of the upper cover unit through the positioning groove, so that the inlet and the outlet are easily connected to the corresponding connection configuration of the external device. There is an effect that can be connected.

1 is a perspective view showing the exterior of a cooling tank device according to an embodiment of the present invention.
2 is an exploded perspective view of FIG. 1.
3 is a view for explaining an arrangement and a coupling relationship between a tank body, a cooling unit, and a support unit according to an embodiment of the present invention.
4 is a perspective view schematically showing the structure of an upper cover unit according to an embodiment of the present invention.
5 is a view showing a state in which the coil flow path unit is coupled to and supported by an upper cover unit according to an embodiment of the present invention.
6 is a view for explaining a structure in which a heat sink unit is installed in a support unit according to an embodiment of the present invention.
7 is a view schematically showing the internal structure of a cooling plate according to an embodiment of the present invention.
8 is an exploded perspective view illustrating a structure in which a cooling unit, a support unit, and a heat sink unit are installed according to another embodiment of the present invention.
9 is a partial cross-sectional view showing an installation state of the cooling unit, the support unit, and the heat sink unit shown in FIG. 8.

Hereinafter, preferred embodiments of the present invention in which the above-described problem to be solved may be specifically realized will be described with reference to the accompanying drawings. In describing the present embodiments, the same names and the same reference numerals are used for the same components, and additional descriptions thereof will be omitted below.

First, FIG. 1 is a perspective view showing the exterior of a cooling tank device according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of FIG. 1, and FIG. 3 is a tank body and a cooling unit according to an embodiment of the present invention. It is a diagram for explaining the arrangement and coupling relationship between the support units.

Next, FIG. 4 is a perspective view schematically showing the structure of an upper cover unit according to an embodiment of the present invention, and FIG. 5 is a state in which the coil flow path unit is coupled to and supported by the upper cover unit according to an embodiment of the present invention. 6 is a view for explaining a structure in which a heat sink unit is installed in a support unit according to an embodiment of the present invention, and FIG. 7 is a diagram illustrating an internal structure of a cooling plate according to an embodiment of the present invention. It is a schematic diagram.

1 to 7, the cooling tank device according to an embodiment of the present invention includes a tank body 100, a coil flow path unit 200, a cooling unit 300, a stirring unit 400, and an upper portion. It includes a cover unit 500, a heat sink unit 600, a support unit 700, and an insulation cover 800.

As shown in FIG. 2, the tank body 100 has an inner space 110 formed with a closed lower end, and the upper end may be formed in a cylindrical shape of an open structure. At this time, the shape of the tank body 100 may be manufactured in various shapes such as a square column shape instead of a cylindrical shape according to the structure and characteristics of the product.

The inner space 110 accommodates a cooling medium heat-exchanging with the coil passage unit 200 to be described later.

The tank body 100 may have a completely sealed structure by a combination with an upper cover unit 500 to be described later.

The tank body 100 may be made of various materials, but is preferably made of a stainless steel material or aluminum material having excellent durability, corrosion resistance, and rigidity in order to prevent corrosion and contamination.

The coil flow path unit 200 may be provided with an inlet 210 through which fluid is introduced at one end, and an outlet 220 through which fluid is discharged at the other end, and increase the contact area with the cooling medium to be described later. It may be formed in a coil shape so that it may be installed in the inner space 110.

Meanwhile, the outlet 220 may be connected to a water intake cock (not shown) for discharging the cold fluid by heat exchange of the fluid flowing into the inlet 210 with the cooling medium, and the user operates the water intake cock. A cold fluid discharged through the outlet 220 may be supplied.

2 and 3, the cooling unit 300 is disposed below the tank body 100, and is disposed to be connected to the lower surface of the tank body 100 to provide the tank body 100. Can be cooled.

The cooling unit 300 may include a thermoelectric element 310 and a heat transfer member 320.

The thermoelectric element 310 may be connected to the tank body 100, absorb heat of the tank body 100 to cool the cooling medium accommodated in the inner space 110, and the absorbed heat will be described later. It may be discharged to the outside through the heat sink unit 600.

More specifically, the thermoelectric element 310 electronically cools an object using the Peltier effect, and the Peltier effect connects two types of metal ends, and when a current is passed therethrough, one terminal according to the current direction is It absorbs heat, and the other terminal generates heat.

Therefore, when a current is applied to the thermoelectric element 310, the upper surface of the thermoelectric element 310 absorbs heat to cool the lower surface of the tank body 100, and the thermoelectric element 310 generates heat. .

At this time, if the lower surface of the thermoelectric element 310 is not cooled, the cooling efficiency of the upper surface of the thermoelectric element 310 decreases. Therefore, the lower surface can be cooled by the heat sink unit 600.

The heat transfer member 320 is disposed between the lower surface of the tank body 100 and the upper surface of the thermoelectric element 310, is cooled by heat exchange with the thermoelectric element 310, and cools the cooled temperature to the tank body ( 100) can be delivered.

The heat transfer member 320 may include a heat transfer member body 321 and a heat transfer member body fixing portion 322.

The heat transfer member body 321 is disposed between the lower surface of the tank body 100 and the upper surface of the thermoelectric element 310, and may be fixed to the lower surface of the tank body 100.

The heat transfer member body fixing portion 322 is formed to protrude from both side ends of the heat transfer member body 321 toward the outer radial direction in order to fix the heat transfer member body 321 to the lower surface of the tank body 100. I can.

At this time, the heat transfer member body fixing part 322 may be provided with a bushing hole 322a through which the coupling bushing 120 protruding from the bottom surface of the tank body 100 passes.

In other words. The heat transfer member body 321 is fixed to the lower surface of the tank body 100, the first coupling bolt (B1) as a separate fastening member in a state where the coupling bushing 120 is coupled to the bushing hole (322a) May be fixed while being screwed to the coupling bushing 120.

The stirring unit 400 may include an impeller 410 disposed in the inner space 110 to stir the cooling medium and a driving motor 420 for driving the impeller 410.

In this case, the driving motor 420 may be mounted and fixed to the driving motor mounting portion 530 of the upper cover body 510 to be described later.

In addition, the driving motor 420 may be connected to the impeller 410 disposed in the inner space 110 with the driving motor shaft 421 passing through the bottom surface of the driving motor mounting part 530.

2 and 4, the upper cover unit 500 is coupled to the upper portion of the tank body 100, while supporting the coil passage unit 200 in the inner space 110 and driving A motor 420 may be disposed.

The upper cover unit 500 includes an upper cover body 510, a coil passage unit fixing part 520, a driving motor mounting part 530, an upper cover coupling part 550, a positioning groove 560, and It may include an upper cover cover 570.

The upper cover body 510 is coupled to the upper portion of the tank body 100, and the inlet 210 and the outlet 220 are provided through and exposed to the outside.

The upper cover body 510 is formed to protrude upward from the outer circumference of the upper cover body 510 and may include an edge portion 511 for forming an accommodation space 512 inside.

The coil flow path unit fixing part 520 is configured to support the coil flow path unit 200 on the inner space 110, and the coil flow path unit 200 reinforces a plurality of support blades 521 and support blades. It may include a part 522.

5, the plurality of support blades 521 are formed to protrude from the lower surface of the upper cover body 510 in the direction of the inner space 110 and are coupled to a part of the coil passage unit 200 The coil flow path unit 200 is supported on the inner space 110.

The support wing reinforcement part 522 is installed so that a plurality of support wings 521 are connected to each other, and by reinforcing the strength of the plurality of support wings 521 installed on the lower surface of the upper cover body 510, the plurality of The coil flow path unit 200 can be more firmly supported by the support blades 521.

The driving motor mounting part 530 may be provided in an upper central region of the upper cover body 510 to mount the driving motor 420.

More specifically, the drive motor mounting part 530 is provided on the receiving space part 512, and is formed in a cylindrical shape in the central region of the receiving space part 512, and the drive motor 420 therein Is equipped.

Meanwhile, a plurality of driving motor fixing portions 540 may be provided on the outer circumferential surface of the driving motor mounting part 530 to be coupled to the driving motor plate 430 coupled to the rear side of the driving motor 420.

That is, by mounting the driving motor 420 to the driving motor mounting portion 530, and then coupling the driving motor plate 430 to the driving motor fixing unit 540 through a separate fastening member (not shown), The driving motor 420 mounted on the driving motor mounting part 530 is fixed on the driving motor mounting part 530.

The upper cover coupling portion 550 is installed so as to surround the outer peripheral surfaces of the plurality of support wings 521 from the lower surface of the upper cover body 510, and is formed to protrude in the direction of the tank body 100 so that the tank body ( 100) is combined with the top.

That is, the upper cover unit 500 is coupled to the upper portion of the tank body 100 by coupling the upper cover coupling portion 550 to the upper portion of the tank body 100.

The positioning groove 560 is formed in a depression at one side of the rim portion 511, and the locations of the inlet 210 and the outlet 220 installed through the upper cover body 510 can be easily checked. .

In this case, the inlet 210 may be disposed close to the positioning groove 560, and the outlet 220 may be disposed farther from the positioning groove 560.

For example, when the cooling tank device is connected to an external device (not shown) such as a water purifier, the location of the inlet port 210 and the location of the outlet 220 can be checked through the positioning groove 560. , There is an advantage that the inlet 210 and the outlet 220 can be easily connected to the corresponding connection configuration of the external device.

The upper cover cover 570 may be installed on the receiving space part 512 while passing through the driving motor mounting part 530.

At this time, the upper cover cover 570 may be formed of an insulating material, and is installed on the receiving space part 512 so that the temperature of the tank body 100 is not taken to the outside together with an insulating cover 800 to be described later. Insulate the tank body 100.

Meanwhile, the inlet 210 and the outlet 220 passing through the upper cover body 510 are provided through the upper cover cover 570 to be exposed to the outside.

As a result, as the upper cover unit 500 supports the coil passage unit 200, the drive motor 420 is mounted, and an upper cover cover 570 for insulation is disposed, the cooling tank device is It can be manufactured compactly.

Meanwhile, as shown in FIG. 4, the upper cover unit 500 may include a sensor mounting part 580.

The sensor mounting unit 580 may be equipped with a sensor unit for detecting a change in temperature, water level, etc. according to the use of the cooling medium filled in the inner space 110 of the tank body 100, for example, a sensor mounting unit ( A temperature sensor and a water level sensor may be mounted as a sensor unit that can be mounted on the 580.

That is, through the temperature sensor and the water level sensor mounted on the upper cover unit 500, it is possible to detect the temperature and water level information of the cooling medium in real time.

As shown in FIG. 6, the heat sink unit 600 is disposed to be connected to the thermoelectric element 310 to radiate heat from the thermoelectric element 310.

The heat sink unit 600 may include a cooling plate 610, a heat sink 620, and a heat dissipation fan 630.

As shown in FIG. 7, the cooling plate 610 is disposed to contact a lower surface of the thermoelectric element 310, and a plurality of cooling channels 611 through which a refrigerant moves may be provided therein.

In this case, a flow path groove 611a for guiding the movement of the refrigerant may be provided on one side of the plurality of cooling channels 611.

The cooling plate 610 may include a horizontal portion 612 coupled to the support unit 700 and a vertical portion 613 bent upward from one side of the horizontal portion 612.

That is, the cooling plate 610 cools the lower surface of the thermoelectric element 310 by exchanging heat with heat generated from the lower surface of the thermoelectric element 310 and the refrigerant accommodated in the horizontal part 612.

At this time, when heat exchange between the lower surface of the thermoelectric element 310 and the horizontal portion 612, the refrigerant accommodated in the cooling channel 611 is evaporated to move to the vertical portion 613, and the vertical portion 613 The refrigerant moved to is condensed by the heat dissipation action of the heat sink 620 and the heat dissipation fan 630 to be described later, and moves back to the horizontal portion 612 along the flow path groove 611a.

The heat sink 620 is disposed on the vertical part 613 to radiate the cooling plate 610, and the heat dissipation fan 630 is disposed on one side of the heat sink 620 to the heat sink 620 Can help heat dissipation.

The support unit 700 may support the tank body 100 while being coupled with the cooling unit 300 and the heat sink unit 600 at the same time.

The support unit 700 may include a support unit body 710, a sliding coupling part 720, and a support unit body fixing part 730.

The thermoelectric element 310 may be disposed on the upper surface of the support unit body 710.

The sliding coupling part 720 is disposed to be spaced apart from the upper surface of the support unit body 710 at a predetermined interval, and may be formed to protrude along the longitudinal direction of the support unit body 710.

In this case, the sliding coupling part 720 may include a first sliding guide 721 and a second sliding guide 722 disposed to be spaced apart from the first sliding guide 721 by a predetermined interval.

In this case, a width of the first sliding guide 721 and the second sliding guide 722 spaced apart from each other may be the same as a widthwise width of the horizontal portion 612.

Therefore, when the horizontal part 612 is slidably coupled between the first sliding guide 721 and the second sliding guide 722, the cooling plate 610 is fixed to the support unit body 710. I can.

That is, as the horizontal portion 612 is slidably coupled to the sliding coupling portion 720, a separate fastening means is not required, and the cooling plate 610 is easily removed from the support unit body 710 if necessary. It has the advantage of being able to separate it.

The support unit body fixing part 730 may be formed to protrude upward from the upper surface of the support unit body 710 to be coupled to the heat transfer member body fixing part 322.

At this time, the support unit body 710 may be fixed to the heat transfer member body fixing part 322.

That is, the second fastening bolt (B2) penetrates the support unit body fixing portion 730 and is screwed to the heat transfer member body fixing portion 322, so that the support unit body 710 is the heat transfer member body fixing portion. It will be able to be fixed at 322.

The heat insulating cover 800 is formed to surround the outer circumferential surface of the tank body 100, and insulates the tank body 100 so that the temperature of the tank body 100 is not taken to the outside.

That is, the above-described upper cover cover 570 and the heat insulating cover 800 insulate the outer circumferential surface and upper portion of the tank body 100, thereby maintaining the temperature of the tank body 100 without being taken to the outside. The efficiency can be improved.

On the other hand, the heat insulating bucket is formed in a portion corresponding to the heat dissipation fan 630, restricts the movement path of air so that the air moved by the heat dissipation fan 630 does not move to the rear side of the tank body 100 It may include a rectangular portion 810.

That is, when the heated air moves to the rear side of the tank body 100 while radiating the vertical part 613 by the heat dissipation fan 630, damage to the surrounding components of the tank body 100 You will be able to.

At this time, the square part 810 blocks the movement path of the heated air so that it does not move to the rear side of the tank body 100, thereby preventing damage to the surrounding components disposed at the rear side of the tank body 100. Avoid.

According to an embodiment of the present invention, the support unit 700 may further include a coupling guide member 740.

The coupling guide member 740 is formed to extend from one end of the support unit body 710 and extends to one end of the support unit body 710 corresponding to the horizontal part 612, so that the support unit ( 700) can be combined with an external device.

That is, when the cooling tank device is coupled to an external device, a separate guide member 740 and the horizontal part 612 are inserted between the coupling guide member 740 and the horizontal part 612 in a cooling tank device coupling part (not shown) provided in the external device. It is possible to easily couple the cooling tank device to the external device without a coupling means.

Meanwhile, FIG. 8 is an exploded perspective view illustrating a structure in which a cooling unit, a support unit, and a heat sink unit according to another embodiment of the present invention are installed, and FIG. 9 is a cooling unit, a support unit, and a heat sink shown in FIG. It is a partial cross-sectional view showing the installation state of the unit.

The refrigerant filled in the cooling channel 611 of the cooling plate 610 is evaporated while exchanging heat with the heat source of the thermoelectric element 310 to cool the thermoelectric element 310, and the evaporated refrigerant is the heat sink 620 and It is circulated in the cooling channel 611 while passing through a phase change process that is condensed by the heat dissipation action of the heat dissipation fan 630.

In order to facilitate the circulation of the refrigerant, the cooling plate 610 may be disposed to be inclined downward at a certain angle (a) while going to an end contacting the thermoelectric element 310.

In order to obliquely arrange the cooling plate 610 in this way, the upper surface of the support unit body 710 according to the present invention may include an inclined support portion 750 for obliquely supporting the cooling plate 610.

As described above, by placing the cooling plate 610 in contact with the thermoelectric element 310 in an inclined downward direction toward the end thereof, it is evaporated while heat exchange with the heat source of the thermoelectric element 310 or the heat sink 620 and the heat dissipation fan 630 By facilitating circulation of the refrigerant condensed by the heat dissipation of the heat sink unit 600, the cooling efficiency of the heat sink unit 600 may be increased, and the cooling efficiency of the cooling tank may be increased.

In addition, when the cooling plate 610 is arranged in an inclined manner as described above, the lower surface 321a of the heat transfer member 320 facing the cooling plate 610 with the thermoelectric element 310 interposed therebetween is the lower surface 321a of the cooling plate 610. It may be formed to be inclined to correspond to the inclination angle (a).

In other words, the thermoelectric element 301 seated on the upper surface of the inclined cooling plate 610 is disposed at an angle, and the heat transfer member 320 can uniformly maintain a wide contact area with the inclined thermoelectric element 301 The lower surface 321a is also formed to be inclined to correspond to the inclination angle (a) of the inclined support part 750.

In the end, since a wide contact area with respect to the heat transfer member 320 and the cooling plate 610 contacting the upper and lower surfaces of the thermoelectric element 310 can be uniformly and stably maintained, the cooling tank can be stably supported, In particular, by increasing the heat transfer efficiency toward the heat transfer member 320 and the cooling plate 610, it is possible to further increase the cooling efficiency of the cooling tank.

As described above, preferred embodiments of the present invention have been described with reference to the drawings, but those skilled in the art will variously modify the present invention within the scope not departing from the spirit and scope of the present invention described in the following claims. Can be modified or changed.

100: tank body 110: internal space
120: coupling bushing 200: coil flow unit
210: inlet 220: outlet
300: cooling unit 310: thermoelectric element
320: heat transfer member 321: heat transfer member body
322: heat transfer member body fixing portion 322a: bushing hole
400: stirring unit 410: impeller
420: drive motor 421: drive motor shaft
430: drive motor plate 500: upper cover unit
510: upper cover body 511: rim portion
512: receiving space part 520: coil flow path unit fixing part
521: a plurality of support wings 522: support wing reinforcement
530: drive motor mounting portion 540: drive motor fixing portion
550: upper cover coupling portion 560: positioning groove
570: upper cover cover 600: heat sink unit
610: cooling plate 611: cooling channel
611a: euro groove 612: horizontal part
613: vertical part 620: heat sink
630: heat dissipation fan 700: support unit
710: support unit body 720: sliding coupling
721: first sliding guide 722: second sliding guide
730: support unit body fixing portion 740: coupling guide member
750: inclined support part 800: insulation cover
810: square part

Claims (10)

A tank body forming an inner space and receiving a cooling medium in the inner space;
A coil flow path unit disposed in an internal space of the tank body to heat exchange with the cooling medium and having an inlet port through which fluid is introduced and an outlet port through which fluid is discharged;
A cooling unit disposed below the tank body and including a thermoelectric element for cooling the tank body by being disposed to be connected to a lower surface of the tank body;
A stirring unit disposed in the inner space and including an impeller for stirring the cooling medium and a driving motor for driving the impeller; And
And an upper cover unit coupled to an upper portion of the tank body, wherein the driving motor is disposed while supporting the coil passage unit in the inner space,
The upper cover unit, the upper cover body; In order to support the coil passage unit on the inner space, a coil passage unit fixing portion including a plurality of support blades protruding from a lower surface of the upper cover body in the direction of the inner space to be coupled to a part of the coil passage unit; And a driving motor mounting part provided in an upper central region of the upper cover body to mount the driving motor,
The cooling unit further includes a heat transfer member disposed between a lower surface of the tank body and an upper surface of the thermoelectric element, cooled by heat exchange with the thermoelectric element, and transferring the cooled temperature to the lower surface of the tank body; and,
The heat transfer member may include a heat transfer member body fixed to a lower surface of the tank body; And a heat transfer member body fixing part which is formed protruding from both side ends of the heat transfer member body toward an outer radial direction and provided with a bushing hole through which the coupling bushing protruding from the bottom surface of the tank body is provided, and including,
The heat transfer member body is fixed to a lower surface of the tank body, wherein the first coupling bolt is screwed to the coupling bushing to be fixed. The method of claim 1,
The upper cover body,
And a rim portion protruding upwardly from an outer circumference of the upper cover body to form an accommodation space portion therein. The method of claim 2,
The upper cover unit,
An upper cover coupling part provided to surround the outer circumferential surfaces of the plurality of support blades from a lower surface of the upper cover body, and protruding toward the tank body to be coupled to an upper portion of the tank body;
A location identification groove formed in one side of the rim portion to easily check the locations of the inlet and outlets installed through the upper cover body; And
And an upper cover cover installed on the receiving space while passing through the drive motor mounting portion. delete The method of claim 1,
A heat sink unit arranged to be connected to the thermoelectric element to radiate heat to the thermoelectric element; And
And a support unit for supporting the tank body while being simultaneously coupled with the cooling unit and the heat sink unit. The method of claim 5,
The heat sink unit,
A cooling plate disposed to be in contact with a lower surface of the thermoelectric element, and having a plurality of cooling channels through which a refrigerant moves therein;
A heat sink connected to the cooling plate to radiate the cooling plate; And
And a heat dissipation fan disposed on one side of the heat sink to help heat dissipation of the heat sink. The method of claim 6,
The support unit,
A support unit body on which the thermoelectric element is disposed on an upper surface;
A sliding coupling part which is disposed to be spaced apart from the upper surface of the support unit body at regular intervals, and is formed to protrude along the longitudinal direction of the support unit body to slide the cooling plate; And
Including; a support unit body fixing portion formed protruding upward from the upper surface of the support unit body and coupled to the heat transfer member body fixing portion,
The support unit body is fixed to the heat transfer member body fixing portion, wherein a second fastening bolt penetrates the support unit body fixing portion and is fixed while being screwed to the heat transfer member body fixing portion. The method of claim 7,
An upper surface of the support unit body includes an inclined support portion for obliquely supporting the cooling plate,
A cooling tank apparatus, wherein a lower surface of the heat transfer member facing the cooling plate with the thermoelectric element therebetween is formed to be inclined to correspond to an inclination angle of the cooling plate. The method of claim 6,
It is formed to surround the outer circumferential surface of the tank body, further comprising an insulating cover for preventing the temperature of the tank body from being taken to the outside,
The heat insulating cover is formed at a portion corresponding to the heat dissipation fan, and a rectangular portion for limiting a movement path of the air so that the air moved by the heat dissipation fan does not move to the rear side of the tank body; Cooling tank device. The method of claim 7,
The support unit,
And a coupling guide member extending at one end of the support unit body to couple the support unit to an external device.

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