KR101437809B1 - A cooling tank using a thermoelectric module - Google Patents

Abstract

Disclosed is a cooling tank using a thermoelectric module. The cooling tank using a thermoelectric module includes a main tank body (10) storing inflow water introduced through a water introducing unit (20); a thermoelectric module (60) attached to a rear surface of the main tank body (10) to generate cold air using a thermoelectric element; a cooling plate (40) receiving the cold air and transferring the cold air to the inflow water; a supplementary cooling plate (80) fixed to a surface of the cooling plate (40) to separate a space of the main tank body (10); and a pipe type water discharging unit (30) penetrating the supplementary cooling plate (80) to discharge cooled water, which is the cooled inflow water. The water discharging unit includes an air vent (31) at an upper portion to fill up to an upper portion of the main tank body (10) with the inflow water, prevents the inflow water and the cooled water from being mixed, and discharges the cooled water.

Description

[0001] The present invention relates to a cooling tank using a thermoelectric module,

The present invention relates to a cooling tank, and more particularly, to a cooling tank using a thermoelectric module capable of taking water at a low temperature as much as possible by minimizing mixing of inflow water at room temperature and cooling water in the tank by dividing the space inside the cooling tank into multi- will be.

Generally, a cooling system using a thermoelectric module for generating cooling water is used as a water purifier for taking purified water by using a filter.

The cooling method using the thermoelectric module can be arranged using less space than the cooling method using the compressor.

However, in the technology up to now, the cooling method using the thermoelectric module has a disadvantage that the cooling performance is lower than that of the compressor type cooling method, and the time for cooling the same amount of stored water takes longer than that of the compressor type cooling method.

In order to overcome the disadvantage of the cooling method using the thermoelectric module, the capacity of the cooling water tank of the compressor type cooling method is reduced to reduce the difference in cooling performance.

In this case, the inflow water at room temperature enters the inside of the tank. In this case, there is a problem that the inflow water at the normal temperature and the cooling water are mixed to be outflowed, and the thermoelectric module There has been a problem that mixing is performed more rapidly in a cooling tank having a small capacity of the cooling system used.

In order to overcome such a problem, conventionally, there has been proposed a structure in which the outlet portion is located at the lower portion of the tank using the difference in specific gravity between the cooling water and the inlet water at normal temperature.

However, the cooling tank according to the prior art has a limit in that efficient cooling water extraction can be limited due to continuous inflow of cold water and inflow water at normal temperature.

That is, the inflow water at room temperature is continuously mixed with the cooling water to form a turbulent flow, so that the cooling effect of the cooling water coming out to the cooling water outflow portion at the lower portion of the tank may be lowered.

Also, when the aqueous solution of the electrolyte stagnates in the clearance of the cooling tank, crevice corrosion occurs, and residual water may exist in the lower part of the storage tank when the cooling water is drained.

The object of the present invention is to disperse inflow water at room temperature flowing through the intake part and to divide the inside of the tank with the auxiliary cooling plate to limit the mixing of the inflow water and the cooling water in the tank to the minimum, The present invention provides a cooling tank using a thermoelectric module for allowing a user to go out.

To achieve the above object, a cooling tank (100) using a thermoelectric module according to the present invention comprises a tank body (10) for storing inflow water obtained through a water inlet (20); A thermoelectric module (60) attached to the rear surface of the tank body (10) and generating cool air by using a thermoelectric element; A cooling plate (40) for receiving the cool air from the thermoelectric module (60) and transferring the cold air to the inflow water; An auxiliary cooling plate (80) fixed to one surface of the cooling plate (40) to separate the space of the tank body (10); And a water outlet (30) passing through the auxiliary cooling plate (80) in the form of a pipe to allow the cooling water discharged from the inflow water to flow out, and the water outlet has an air vent (31) 10) so as to prevent the mixing of the inflow water and the cooling water.

In order to achieve the above object, the auxiliary cooling plate (80) of the cooling tank (100) using the thermoelectric module of the present invention includes a central separating plate (84) dividing the inner center of the tank body (10) into two compartments; An upper separation plate 82 for dividing the upper space of the central separation plate 84 into two compartments to form first and second compartments; And a lower separating plate 83 for dividing the lower space of the central separating plate 84 into two compartments to form third to fourth compartments.

A cooling tank 100 using the thermoelectric module according to the present invention for achieving the above object is installed between the thermoelectric module 60 and the cooling plate 40 and serves as a cooling spacer block for transferring the cooling air to the inflow water. (50). ≪ IMAGE >

A cooling tank 100 using a thermoelectric module according to the present invention for achieving the above object is installed between an upper portion of the upper separator plate 82 and a lower portion of the water inlet portion 20 to diffuse the inflow water 70). ≪ / RTI >

In order to achieve the above object, the diffusion member of the cooling tank 100 using the thermoelectric module of the present invention is provided at the center of the lower surface to diffuse the influent water flowing into the first compartment, And a semicircular projection (71) for forming the semicircular projection (71).

In order to achieve the above object, the diffusion member of the cooling tank (100) using the thermoelectric module of the present invention is characterized by a concave shape.

In order to achieve the above object, the diffusion member (70) of the cooling tank (100) using the thermoelectric module according to the present invention is provided with a drain hole at the bottom to prevent the residue in the cooling tank from remaining.

In order to achieve the above object, the central partition plate (84) of the cooling tank (100) using the thermoelectric module of the present invention has a plurality of partition plate passages (91) By connecting the three compartments, the cooling water mixed with the influent water in the second compartment flows into the third compartment and is prevented from being rapidly mixed with the cooling water in the third compartment.

In order to achieve the above object, a cooling tank 100 using a thermoelectric module according to the present invention is formed on an upper surface of the tank body 10, and the air vent 31 is positioned inside the cooling tank 100, And a circular guide (11) for preventing mixing of the circular guide (11).

According to the present invention, in the cooling tank using the thermoelectric module, the inflow water is dispersed by the diffusion member to prevent turbulent formation with the cooling water existing in the tank, and the upper and lower separation plates and the middle separation plate It is possible to prevent turbulent flow formation.

In addition, the cooling water existing inside the tank forms the inflow water and the layer and flows out to the cooling water outflow portion of the lower portion of the tank, so that the temperature of the water to be outflowed can be lowered.

In addition, inflow of inflow water through the air vent existing inside the circular guide of the tank main body can be prevented as much as possible on the upper part of the water outlet.

FIG. 1 is a perspective view of the cooling tank 100 using the thermoelectric module according to the present invention in a front side direction.
2 is a perspective view of the cooling tank 100 using the thermoelectric module shown in FIG.
FIG. 3 is an exploded perspective view of the cooling tank 100 using the thermoelectric module shown in FIG. 1 in a direction toward the front side.
Fig. 4 is an exploded perspective view of the cooling tank 100 using the thermoelectric module shown in Fig. 1 in the left direction.
Fig. 5 is an exploded perspective view of the cooling tank 100 using the thermoelectric module shown in Fig. 1 in the right direction.

Hereinafter, preferred embodiments of a cooling tank using the thermoelectric module according to the present invention will be described with reference to the accompanying drawings.

1 is a perspective view of a cooling tank 100 using a thermoelectric module according to the present invention in a front side direction and includes a tank body 10, a water inlet 20, and a water outlet 30.

Fig. 2 is a perspective view of the cooling tank 100 using the thermoelectric module shown in Fig. 1 in the direction of one side of the rear side. The tank body 10, the water inlet 20, the water outlet 30, the cooling plate 40, A cooling spacer block 50 and a thermoelectric module 60.

Fig. 3 is an exploded perspective view of the cooling tank 100 using the thermoelectric module shown in Fig. 1 in the direction of the front side and includes a tank body 10, a circular guide 11, a water inlet 20, a water outlet 30, The air vent 31, the cooling plate 40, the cooling spacer block 50, the thermoelectric module 60, the diffusion member 70, the cooling assistant plate 80, the upper separating plate 82, the lower separating plate 83 ), A central separation plate (84), and a sealed packing (110).

Fig. 4 is an exploded perspective view of the cooling tank 100 using the thermoelectric module shown in Fig. 1 in the left direction. The tank body 10, the water inlet 20, the cooling plate 40, the diffusion member 70, And includes a semicircle projection 71, a hook 72, a hook fixing portion 81, an upper separation plate 82, and a lower separation plate 83.

5 is an exploded perspective view of the cooling tank 100 using the thermoelectric module shown in Fig. 1 in the right direction. The tank body 10, the circular guide 11, the water outlet 30, the air vent 31, A cooling water outlet portion 32, a cooling plate 40, a hook fixing portion 81, an upper separation plate 82, a lower separation plate 83 and a central separation plate 84.

The function of each component of the cooling tank 100 using the thermoelectric module according to the present invention will be described with reference to FIGS. 1 to 5 as follows.

The tank body 10 stores and cools the inflow water obtained through the intake section 20. [

The thermoelectric module 60 is composed of a thermoelectric element to generate cool air.

The cooling plate 40 transfers the cool air of the thermoelectric module 60 to the inflow water via the cooling spacer block 50.

The auxiliary cooling plate 80 is fixed to one side of the cooling plate 40 to transfer the cool air of the cooling plate 40 to the inflow water and to separate the space inside the tank to delay the mixing of the inflow water and the cooling water.

The auxiliary cooling plate 80 includes a central separating plate 84 for dividing the inner center of the tank body 10 into two compartments, two separated compartments in the upper and lower spaces of the central separating plate 84, And an upper separating plate 82 and a lower separating plate 83 which form the first to fourth compartments.

A concave diffusion member 70 is mounted between the upper part of the upper separation plate 82 and the lower part of the inlet part 20 so that the inflow water at room temperature is spread through the central semi- And turbulent flow to prevent rapid mixing.

The water outlet 30 is provided with an air vent 31 at an upper portion thereof, and restricts the mixing of the inflow water with the cooling water in the tank to the minimum so that the cooling water having the greatest capacity is discharged.

The operation of the cooling tank 100 using the thermoelectric module according to the present invention will be described with reference to FIGS. 1 to 5 as follows.

First, the inflow water at room temperature that has passed through a separate filtration device flows into the cooling tank 100 through the inlet portion 20.

At this time, the gas filling the inside of the tank is discharged through the air vent 31 located above the water outlet 30 assembled to the tank body 10, so that the inflow water is filled in the tank.

If there is no air vent 31, the inflow water will be immediately discharged through the cooling water outlet 32 located at the bottom of the tank, and the inflow water will not be filled at the top of the cooling water outlet 32.

At this time, the water outlet 30 has a pipe shape connected to the lower portion of the tank so that the cooling water at the lower portion of the tank can be taken out first in order to slow the outflow of the obtained hot water.

The tank main body 10 is divided into two compartments by a central separating plate 84 at the center of the interior thereof and the two compartments are divided into an upper separating plate 82 of the auxiliary cooling plate 80 fixed to one side of the cooling plate, And then divided into two sections by the plate 83 so as to be divided into four sections.

The auxiliary cooling plate 80 is fixed to one side of the cooling plate 40 to transfer the cool air of the cooling plate 40 to the inflow water and to separate the space inside the tank to delay the mixing of the inflow water and the cooling water.

That is, the shape of the separation plates 82, 83, and 84 partitioned into the multi-stages fill the inner end surface of the tank except for the predetermined edge space of the separation plate and flow into the uppermost first compartment, Prevent abrupt mixing with influent.

The central partition plate 84 is in a shape identical to the inner end surface of the tank so that the second and third sections are completely separated from each other and only the second section and the third section are connected to the four partition plates 91 at the edges of the partition plate .

The cooling water mixed with the influent in the second compartment flows into the third compartment through the separator passage 91 to prevent rapid mixing with the cooling water in the third compartment.

In this way, the inflow water flows from the first compartment to the fourth compartment and prevents rapid mixing with the cooling water.

However, the inflow water at room temperature flowing through the inlet portion 20 causes turbulence with the cooling water in the first compartment due to the water pressure and the flow velocity, so that the inlet water mixes with the cooling water rapidly and mixes. In order to prevent this, in the present invention, the diffusion member 70 is assembled to the upper separating plate 82 through the hook 72 passing through the hook fixing portion 81.

The diffusion member 70 is located in the lower part of the water inlet 20 in a concave shape so that the inflow water at room temperature is spread by bumping against the semicircular protrusion 71 at the center of the concave shape of the diffusion member 70 upon introduction. The inflow water diffuses through the narrow space of the diffusion member 70 and the upper part of the tank to the first compartment to form a turbulent flow with the cooling water of the first compartment to prevent rapid mixing.

As described above, the inflow water at room temperature by the diffusion member 70 and the respective separation plates 82, 83, 84 forms cooling water and turbulence inside the tank and is prevented from being mixed rapidly, The arrival time to the cooling water outlet portion 32 is delayed and the temperature of the water to be delivered is lowered.

The diffusion member 70 prevents the crevice corrosion caused when the aqueous solution of the electrolyte stagnates in the clearance by securing a space for moving the cooling assisting plate 80 and the fluid, To prevent the residual water inside the storage tank.

The air vent 31 is present in the upper part of the tank and discharges the gas inside the tank. The inflow water flowing in through the inlet part 20 flows into the air vent (not shown) through the cooling water outlet part 32 existing in the lower part of the fourth compartment 31). ≪ / RTI >

A circular guide 11 is provided in the inside of the tank so that the air vent 31 of the water outlet 30 is positioned inside the circular guide 11 so that the mixing of the inflow water with the cooling water flowing out and out is maximized prevent.

The water outlet 30 is provided with an air vent 31 located above the tank main body 10 in order to allow the inflow water to be filled in the cooling tank 100 at the time of initial installation.

As described above, the cooling tank 100 using the thermoelectric module according to the present invention disperses inflow water at room temperature flowing through the inlet portion 20, and at the same time, the partition plate of the auxiliary cooling plate and the partition plate So that the mixing of the inflow water and the cooling water in the tank is limited to the minimum so that the cooling water having the greatest capacity is discharged through the water outlet 30.

Accordingly, the cooling tank 100 using the thermoelectric module prevents the formation of turbulence with the cooling water existing in the tank by dispersing the inflow water by the diffusion member, and the upper and lower separation plates and the center separation plate 84 It is possible to prevent turbulent flow formation.

In addition, since the cooling water existing in the tank forms the inflow water and the layer, it flows out to the cooling water outlet portion 32 in the lower portion of the tank, so that the temperature of the water to be delivered can be lowered.

In addition, inflow of inflow water through the air vent 31 existing in the circular guide 11 of the tank main body can be prevented as much as possible on the upper part of the water outlet 30.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that the present invention can be changed.

10: tank body
11: Circular guide
30:
31: Air vent
32: Cooling water outlet portion
40: cooling plate
81: hook fixing portion
82: upper separation plate
83: Lower partition plate
84:

Claims (9)

A tank main body 10 for storing influent water obtained through the inlet portion 20;
A thermoelectric module (60) attached to the rear surface of the tank body (10) and generating cool air by using a thermoelectric element;
A cooling plate (40) for receiving the cool air from the thermoelectric module (60) and transferring the cold air to the inflow water;
An auxiliary cooling plate (80) fixed to one surface of the cooling plate (40) to separate the space of the tank body (10); And
A water outlet (30) through which the cooling water passes through the auxiliary cooling plate (80) in the form of a pipe to allow the inflow water to flow out;
, ≪ / RTI &
The auxiliary cooling plate (80)
A central separation plate (84) dividing the inner center of the tank body (10) into two compartments;
An upper separation plate 82 for dividing the upper space of the central separation plate 84 into two compartments to form first and second compartments; And
A lower separating plate 83 for dividing the lower space of the central separating plate 84 into two compartments to form third to fourth compartments; / RTI >
Wherein the water outlet is provided with an air vent (31) at an upper portion thereof to fill the inflow water up to an upper portion of the tank main body (10) and prevent the inflow water from being mixed with the cooling water,
Cooling tank using thermoelectric module.
delete The method according to claim 1,
The cooling tank
A cooling spacer block (50) attached between the thermoelectric module (60) and the cooling plate (40) and serving as a medium for transferring the cool air to the inflow water;
Further comprising:
Cooling tank using thermoelectric module.
The method according to claim 1,
The cooling tank
A diffusion member 70 mounted between an upper portion of the upper partition plate 82 and a lower portion of the inlet portion 20 to spread the inflow water flowing thereinto;
Further comprising:
Cooling tank using thermoelectric module.
5. The method of claim 4,
The diffusion member
A semicircular protrusion (71) provided at the center of the lower surface to diffuse the inflow water flowing into the first compartment to form cooling water and turbulence of the first compartment;
And a control unit
Cooling tank using thermoelectric module.
5. The method of claim 4,
The diffusion member
And a concave shape,
Cooling tank using thermoelectric module.
5. The method of claim 4,
The diffusion member (70)
And a drain hole is provided in the lower portion to prevent remaining of the inside of the cooling tank.
Cooling tank using thermoelectric module.
The method according to claim 1,
The central separator plate 84
A plurality of separation plate passages 91 are formed in a predetermined edge area to connect the second and third compartments so that cooling water mixed with the influent water in the second compartment flows into the third compartment, And preventing rapid mixing with the cooling water of the compartment.
Cooling tank using thermoelectric module.
The method according to claim 1,
The cooling tank
A circular guide (11) formed on an upper surface of the tank main body (10) to place the air vent (31) therein to prevent mixing of the inflow water and the outgoing cooling water;
Further comprising:
Cooling tank using thermoelectric module.

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