KR102421892B1 - Thermoelectric cooling module for refrigeration facility and refrigeration truck using the same - Google Patents

Abstract

The present invention relates to a thermoelectric cooling module for refrigeration and refrigeration facilities and a refrigeration tower vehicle to which the same is applied. In particular, there is no need to provide a separate cold storage warehouse, and a phase change material ( PCM) a body in which a cooling space is formed; a thermoelectric element provided in the main body, one surface of which absorbs heat by a power source to form a low-temperature part, and the other surface is heated to form a high-temperature part; a water block provided on the other side of the thermoelectric element and through which cooling water flows; and a cold air transfer plate provided in the cooling space, a part of which comes into contact with one surface of the thermoelectric element, separates the thermoelectric element and the water block from the cooling space, and absorbs the cold air from the low temperature part and transfers it to the phase change material; characterized in that it comprises; It relates to a thermoelectric cooling module for refrigeration and refrigeration facilities and a refrigeration tower vehicle to which the same is applied.

Description

Thermoelectric cooling module for refrigeration facility and refrigeration truck using the same

The present invention relates to a thermoelectric cooling module for refrigeration and refrigeration facilities and a refrigeration tower vehicle to which the same is applied. It's about the top car.

In general, freezing and refrigeration facilities are provided to keep fish, meat, vegetables, fruits, etc. fresh or to keep them in a cold state. Such refrigeration and refrigeration facilities are provided in a fixed state such as a warehouse, and there are those provided in a moving means such as a truck.

Among them, a moving means equipped with a refrigeration/refrigeration facility is usually called a refrigeration tower vehicle, and since the power source of the mounted refrigerator is acquired from the engine, there is a problem that the refrigeration/refrigeration system is stopped when the engine is stopped. In order to solve this problem, recently, PCM (Phase Change Material) refrigeration tower vehicles have been widely used.

The PCM refrigeration tower vehicle is equipped with a PCM module that encapsulates a PCM of an appropriate temperature range in a plate-shaped or specific type container in the vehicle, and stores the PCM module using electricity when the vehicle is not in operation. Keep frozen or refrigerated. PCM refrigeration tower vehicle using such a PCM module does not require an engine and battery, so it is attracting attention from economic and environmental aspects, but a separate cold storage warehouse is needed to store the PCM module, and the PCM module is cooled due to the increase in temperature in summer. There is a problem that the holding time is reduced.

1. Republic of Korea Patent Publication No. 10-2020-0022419 'The refrigerator of the thermoelectric module and heat pipe combination structure'

The present invention is to solve the above problems, there is no need to provide a separate cold storage warehouse, and to provide a thermoelectric cooling module for refrigeration and refrigeration facilities that can effectively maintain the cooling energy of a phase change material and a refrigeration tower vehicle to which the same is applied. There is a purpose.

The present invention for achieving the above object is a thermoelectric cooling module for refrigeration and refrigeration equipment, comprising: a body having a cooling space in which a phase change material (PCM) is accommodated; a thermoelectric element provided in the main body, one surface of which absorbs heat by a power source to form a low-temperature part, and the other surface is heated to form a high-temperature part; a water block provided on the other side of the thermoelectric element and through which cooling water flows; and a cold air transfer plate provided in the cooling space, a part of which is in contact with one surface of the thermoelectric element, separates the thermoelectric element and the water block from the cooling space, and absorbs the cold air from the low temperature part and transfers it to the phase change material.

In addition, in the main body, a cooling space for accommodating a phase change material is formed therein, an open hole having a size corresponding to the other surface of the thermoelectric element is formed through the lower surface of the upper case, and the open hole is sealed by the cold air transmission plate. and a lower case coupled to the lower side of the upper case and having an upper surface corresponding to the open hole recessed downward to form an installation space in which the thermoelectric element and the water block are located.

In addition, the cold air transmission plate has a 'C' shape with a longitudinal cross-section opening upward while forming a size corresponding to the open hole, and a cold air absorption part having a bottom surface in contact with the thermoelectric element, and a plate shape from the side wall of the cold air absorption part It may include a cold air transmission unit extending to face the side wall of the upper case.

In addition, the water block has a predetermined thickness and has a larger plate shape than the thermoelectric element, and one surface is depressed inside and the edge of the thermoelectric element is seated along the recessed edge to form a cooling water receiving space between the one surface and the thermoelectric element. and an inlet and an outlet which are formed through one surface toward the other while communicating with the cooling water receiving space, the inlet and the outlet may be provided to penetrate through the lower case to be exposed to the outside.

In addition, the main body, made of a material having elasticity, while being fixed to the outer wall forming the cooling space may be provided with a deforming member that is formed convexly toward the outside.

On the other hand, the refrigeration tower vehicle to which the thermoelectric cooling module for refrigeration and refrigeration equipment of the present invention is applied to achieve the above object, the thermoelectric cooling module is installed in a refrigeration tower vehicle including a loading box installed at the bottom of the bottom plate, the thermoelectric cooling A plurality of modules are provided in the module installation space formed between the bottom and the bottom plate of the loading box, and the refrigeration tower vehicle includes a water tank for storing cooling water supplied to a water block included in the thermoelectric cooling module, and cooling water stored in the water tank. and a pump for delivering the to at least one water block.

In addition, a plurality of thermoelectric cooling modules are provided on the same plane in the module installation space to form rows and rows, and an empty space is included between the module installation space and the floor plate, and the refrigerating tower vehicle is configured to discharge the air in the loading box to the outside. Or it may further include an air circulation unit including a fan for introducing external air, and a duct provided in the loading box so that the module installation space and the air circulation unit communicate with each other.

In addition, the refrigeration tower vehicle may further include an inverter provided with a plug to receive and convert commercial power to supply power to the thermoelectric element.

According to the present invention, since the phase change material is cooled by using a thermoelectric element, there is no need to separately take out the thermoelectric cooling module containing the phase change material and store it for cooling. When the cooling energy is reduced, the phase change material is cooled through electrical control to effectively maintain the cooling energy.

A refrigeration tower vehicle to which such a thermoelectric cooling module is applied can easily store a thermoelectric cooling module using electricity during times when the vehicle is not in operation, and effectively control the energy storage through electric control when the vehicle is operating and maintain the frozen or refrigerated state. can

1 is a perspective view showing a thermoelectric cooling module for refrigeration and refrigeration equipment according to the present invention;
2 and 3 are exploded perspective views showing the thermoelectric cooling module for refrigeration and refrigeration facilities according to the present invention;
4 and 5 are cross-sectional views showing the thermoelectric cooling module for refrigeration and refrigeration equipment according to the present invention;
6 is a perspective view showing a water block applied to a thermoelectric cooling module for refrigeration and refrigeration facilities according to the present invention;
7 is a plan view showing the structure of a refrigeration tower vehicle to which the thermoelectric cooling module for refrigeration and refrigeration facilities of the present invention is applied;
8 is a side view showing the structure of a refrigeration tower vehicle to which the thermoelectric cooling module for refrigeration and refrigeration facilities of the present invention is applied;
9 is a rear view showing the structure of a refrigeration tower vehicle to which the thermoelectric cooling module for refrigeration and refrigeration facilities according to the present invention is applied.

In the present invention, there is no need to provide a separate cold storage warehouse, so that the cooling energy of the phase change material can be effectively maintained, a body having a cooling space in which the phase change material (PCM) is accommodated; a thermoelectric element provided in the main body, one surface of which absorbs heat by a power source to form a low-temperature part, and the other surface is heated to form a high-temperature part; a water block provided on the other side of the thermoelectric element and through which cooling water flows; and a cold air transfer plate provided in the cooling space, a part of which comes into contact with one surface of the thermoelectric element, separates the thermoelectric element and the water block from the cooling space, and absorbs the cold air from the low temperature part and transfers it to the phase change material; characterized in that it comprises; We propose a thermoelectric cooling module for refrigeration and refrigeration facilities.

In addition, the thermoelectric cooling module is installed in a refrigeration tower vehicle including a loading box having a bottom plate installed at the bottom, and a plurality of thermoelectric cooling modules are provided in a module installation space formed between the bottom of the loading box and the bottom plate, and the refrigerating tower car is a thermoelectric device for refrigeration facilities, comprising: a water tank for storing coolant supplied to a water block included in the thermoelectric cooling module; and a pump for transferring the coolant stored in the water tank to at least one water block. We propose a refrigeration tower vehicle to which a cooling module is applied.

The scope of the present invention is not limited to the embodiments described below, and various modifications may be made by those of ordinary skill in the art without departing from the technical gist of the present invention.

Hereinafter, a thermoelectric cooling module for a refrigeration and refrigeration facility of the present invention and a refrigeration tower vehicle to which the same is applied will be described in detail with reference to the accompanying FIGS. 1 to 9 .

First, the thermoelectric cooling module for refrigeration equipment of the present invention includes a body 100, a thermoelectric element 200, a water block 300 and a cold air transfer plate 400 as shown in FIGS. 1 to 5 . .

The body 100 is formed with a cooling space 110 in which a phase change material (PCM) is accommodated, and is made of a material with high thermal conductivity so that cold air according to the cooling of the phase change material can be easily transmitted. This is preferable.

In addition, the body 100 may be provided with a deformable member 140 that is elastically deformable as shown in FIGS. 1, 2, 4 and 5 . The deformation sphere 140 may be made of a material having elasticity, such as silicone, for example, and may be convexly formed toward the outside while being fixed to the outer wall forming the cooling space 110 . Since the volume of the phase change material increases during freezing, the deformation sphere 140 swells in consideration of the increased volume and can accommodate the increased volume, so that the volume change according to the freezing and thawing of the phase change material is increased. It is possible to prevent the body 100 from being damaged by this.

One side of the thermoelectric element 200 absorbs heat by the power to form a low-temperature part, and the other side heats up to form a high-temperature part, and may be formed in various shapes, but is preferably made in a plate shape in terms of heat transfer.

As shown in FIGS. 4 and 5 , the water block 300 is provided on the other side of the thermoelectric element 200 , that is, on the high temperature side, and is configured to allow cooling water to flow therein. The water block 300 may indirectly cool the other surface of the thermoelectric element 200 forming the high temperature part through cooling water, but as an example for more effective cooling, as shown in FIG. It is made in the form of a plate larger than the element 200, one surface located on the other side of the thermoelectric element 200 is depressed inward, and the edge of the thermoelectric element 200 is seated along the recessed edge, so that one surface and the thermoelectric element 200 are seated. ), a cooling water receiving space 310 may be formed between them.

In addition, the water block 300 has an inlet 320 through which the cooling water is introduced and an outlet 330 through which the cooling water is discharged. While communicating with the 310 may be formed through from one surface toward the other surface. In the water block 300 , the cooling water introduced into the cooling water receiving space 310 through the inlet 320 directly cools the other surface of the thermoelectric element 200 , and then is discharged through the outlet 330 .

And on one surface of the water block 300, as shown in FIG. 6a, on the coolant receiving space 310 between the inlet 320 and the outlet 330, a protrusion toward the outside so as not to contact the other surface of the thermoelectric element 200 ( 340) may be formed to protrude. At this time, the inlet 320 and the outlet 330 may be respectively formed in the longitudinal center of the cooling water receiving space 310 , and the protrusion 340 has an edge forming the longitudinal direction adjacent to the inlet 320 and the outlet 330 . It is formed so that the edge forming the horizontal direction may be formed to be adjacent to the step forming the cooling water receiving space 310 . Accordingly, the cooling water spreads from the cooling water receiving space 310 to the vicinity of the edge of the thermoelectric element 200 , so that efficient heat exchange is achieved over the entire other surface of the thermoelectric element 200 .

The cold air transfer plate 400 is provided in the cooling space 110 as shown in FIGS. 4 and 5 so that a part thereof is in contact with one surface of the thermoelectric element 200, so that cold air from the low temperature part of the thermoelectric element 200 is provided. It absorbs and delivers cold air to the phase change material accommodated in the cooling space 110 . The cold air transfer plate 400 is provided to separate the thermoelectric element 200 and the water block 300 from the cooling space 110 , so that the phase change material stays only in the cooling space 110 . Do not affect the other surface of (200) and the water block (300).

Specifically, as shown in FIG. 1 , the main body 100 may include an upper case 100a and a lower case 100b coupled to the lower side of the upper case 100a. 4 and 5, the upper case 100a has a cooling space 110 in which a phase change material is accommodated therein, and an open hole having a size corresponding to the other surface of the thermoelectric element 200 on the lower surface ( 120) is formed through penetration. The open hole 120 is closed by the cold air transmission plate 400 .

Accordingly, as an example, the cold air transfer plate 400 forms a 'C' shape with a longitudinal cross-section open upward while forming a size corresponding to the opening hole 120 as shown in FIGS. 2 and 3, and a bottom surface of the thermoelectric element. The cold air absorbing part 410 in contact with one surface of the 200 and the cold air transmitting part 420 extending from the upper end of the side wall of the cold air absorbing part 410 toward the side wall of the upper case 100a while forming a plate shape. can be configured to

That is, the cold air absorption unit 410 is in direct contact with the thermoelectric element 200 and serves to seal the open hole 120 while receiving the cold air, and the cold air transmission unit 420 is the cold air absorption unit 410 . It conducts the absorbed cold air along the longitudinal direction and serves to cool the phase change material accommodated in the cooling space (110). In addition, the cold air transmission unit 420 may be formed through a conduction induction hole having a predetermined length along the longitudinal direction, and the conduction induction hole is the cold air transfer unit 420 located farthest from the cold air absorption unit 410 . It plays a role in effectively delivering cold air to the end of the

As shown in FIGS. 4 and 5, the lower case 100b has an upper surface corresponding to the open hole 120 recessed downward to provide an installation space 130 in which the thermoelectric element 200 and the water block 300 are located. is formed In addition, the lower case 100b has an inlet 320 such that the inlet 320 and the outlet 330 of the water block 300 installed on the installation space 130 penetrate through the lower case 100b and are exposed to the outside. and the lower case 100b is penetrated so that the portion where the outlet 330 is positioned corresponds to the size of the inlet 320 and the outlet 330 , so that the installation space 130 may communicate with the outside. As such, as the inlet 320 and the outlet 330 are exposed to the outside, the water block 300 receives cooling water from the outside, cools the thermoelectric element 200, and then discharges the cooling water. .

The thermoelectric cooling module (A) for refrigeration equipment according to the present invention as described above uses a thermoelectric element 200 capable of forming a low temperature part by power to cool the phase change material, so the thermoelectric cooling module in which the phase change material is accommodated. (A) does not need to be taken out and stored separately, so there is no need to provide a storage warehouse. Energy can be effectively maintained.

On the other hand, in the refrigeration tower vehicle (C) to which the thermoelectric cooling module for refrigeration and refrigeration equipment of the present invention is applied, as shown in FIG. . 8 and 9, the loading box of the refrigeration tower car (C) has a bottom plate 11 installed at the bottom, and the thermoelectric cooling module (A) is located between the bottom of the loading box 10 and the bottom plate 11. A plurality of modules may be provided in the formed module installation space 12 .

A plurality of thermoelectric cooling modules (A) may be provided on the same plane to form rows and columns in the module installation space 12. At this time, as shown in FIGS. 7 to 9, a plurality of thermoelectric cooling modules (A) are A predetermined number may be gathered to form one thermoelectric cooling assembly module (B), and a plurality of thermoelectric cooling assembly modules (B) may be provided on the same plane to form a column and a row in the module installation space 12 . At this time, the thermoelectric cooling module (A) is provided in the module installation space (12), it is preferable to be installed to include an empty space between the floor plate (11). This is to form an air flow for discharging heat generated from the thermoelectric cooling module (A) to the outside.

The refrigeration tower vehicle (C) includes a water tank (20) for storing coolant supplied to the water block (300) included in the thermoelectric cooling module (A), and at least one water block ( It includes a pump 30 that delivers to 300 ). The water tank 20 and the pump 30 may be provided in the lower body of the cooling tower car C as shown in FIGS. 8 and 9 , and the water tank 20 is the thermoelectric cooling module A of each. All of the water blocks 300 may be connected, but it is preferable to connect to any one of the water blocks 300 included in the thermoelectric cooling assembly module (B) to increase the cooling efficiency.

In addition, the refrigeration tower car (C) includes an air circulation unit 40 including a fan 41 for discharging the air in the loading box 10 to the outside or introducing the outside air as shown in FIGS. 7 to 9 . , It may further include a duct 50 provided in the loading box 10 so that the module installation space 12 and the air circulation unit 40 communicate. Accordingly, the heat generated from the thermoelectric cooling module (A) provided in the module installation space (12) is moved to the air circulation unit (40) along the duct (50) and can be discharged to the outside by the fan (41). , if necessary, the fan 41 may introduce external air into the air circulation unit 40 and send it to the module installation space 12 through the duct 50 .

And, as shown in FIG. 8 , the refrigeration tower vehicle C may further include an inverter 60 that is provided with a plug to receive and convert commercial power to supply power to the thermoelectric element 200 . Accordingly, the thermoelectric cooling module (A) can be easily stored and cooled using electricity during the time when the refrigeration tower vehicle (C) is not operated through the inverter (60). In addition, although not shown in the drawing, the refrigeration tower vehicle (C) may further include a control unit for controlling the operation of the thermoelectric element 200 , the pump 30 , the fan 41 , and the inverter 60 , through the control unit It is possible to effectively control the cooling energy through electric control while driving the vehicle and maintain the frozen or refrigerated state.

A : Thermoelectric cooling module B : Thermoelectric cooling assembly module
C : Refrigeration tower car
10: loading box 11: floor plate
12: module installation space 20: water tank
30: pump 40: air circulation unit
41: fan 50: duct
60: inverter
100: body 100a: upper case
100b: lower case 110: cooling space
120: open hole 130: installation space
140: deformation sphere 150: injection hole
200: thermoelectric element
400: water block 310: cooling water receiving space
320: inlet 330: outlet
340: protrusion
400: cold air transmission plate 410: cold air absorption unit
420: cold air transfer unit 421: transfer induction groove

Claims (8)

a body 100 having a cooling space 110 in which a phase change material (PCM) is accommodated;
a thermoelectric element 200 provided in the main body 100, one side of which absorbs heat by power to form a low-temperature part, and the other side heats up to form a high-temperature part;
a water block 300 provided on the other side of the thermoelectric element 200 and having a coolant flowing therein;
While being provided in the cooling space 110, a part is in contact with one surface of the thermoelectric element 200, separates the thermoelectric element 200 and the water block 300 from the cooling space 110, and absorbs the cold air of the low temperature part to change the phase A cold air transfer plate 400 for transferring the material; including,
In the main body 100, a cooling space 110 in which a phase change material is accommodated is formed therein, and an open hole 120 having a size corresponding to the other surface of the thermoelectric element 200 is formed therethrough, and the cold air is transmitted. The upper case 100a, in which the open hole 120 is sealed by the plate 400, is coupled to the lower side of the upper case 100a, and the upper surface corresponding to the open hole 120 is depressed downward, so that the thermoelectric element ( 200) and a lower case 100b in which an installation space 130 in which the water block 300 is located is formed,
The cold air transfer plate 400 has a size corresponding to the opening hole 120 and has a 'C' shape with a longitudinal cross-section open upward, and a cold air absorption unit 410 whose bottom surface is in contact with the thermoelectric element 200 and, A thermoelectric cooling module for refrigeration and refrigeration facilities, comprising a cold air transfer unit 420 in the form of a plate and extending from the side wall of the cold air absorption unit 410 toward the side wall of the upper case 100a. According to claim 1,
The water block 300 has a predetermined thickness and has a larger plate shape than the thermoelectric element 200, and one surface is depressed inward, and the edge of the thermoelectric element 200 is seated along the recessed edge, so that one surface and the thermoelectric element are mounted. A cooling water accommodating space 310 is formed between the 200, and an inlet 320 and an outlet 330 that are formed through from one surface to the other while communicating with the cooling water receiving space 310 are formed,
The thermoelectric cooling module for refrigeration and refrigeration equipment, characterized in that the inlet (320) and the outlet (330) are provided to be exposed to the outside through the lower case (100b). According to claim 1,
The main body 100 is made of a material having elasticity and is fixed to the outer wall forming the cooling space 110 and is provided with a deforming hole 140 convexly formed toward the outside. Thermoelectric cooling module. The thermoelectric cooling module (A) according to any one of claims 1 to 3 is installed in a refrigeration tower car (C) including a loading box (10) having a bottom plate (11) installed at the bottom,
A plurality of thermoelectric cooling modules (A) are provided in the module installation space (12) formed between the bottom of the loading box (10) and the bottom plate (11),
The refrigeration tower vehicle (C) includes a water tank (20) for storing coolant supplied to the water block (300) included in the thermoelectric cooling module (A), and at least one water tank (20) for the coolant stored in the water tank (20). A refrigeration tower vehicle to which a thermoelectric cooling module for refrigeration and refrigeration facilities is applied, characterized in that it includes a pump 30 that delivers it to the block 300 . 5. The method of claim 4,
The module installation space 12 includes a plurality of thermoelectric cooling modules A on the same plane to form rows and columns, and an empty space between the module installation space 12 and the floor plate 11,
The refrigerating tower car (C) includes an air circulation unit 40 including a fan 41 for discharging air in the loading box 10 to the outside or introducing outside air, and the module installation space 12 and air circulation. A refrigeration tower vehicle to which a thermoelectric cooling module for refrigeration and refrigeration facilities is applied, characterized in that it further comprises a duct (50) provided in the loading box (10) so that the part (40) is communicated. 5. The method of claim 4,
The refrigeration tower car (C) is provided with a plug and receives and converts commercial power to supply power to the thermoelectric element 200. Thermoelectric cooling module for refrigeration facilities, characterized in that it further comprises an inverter (60) Refrigeration tower vehicle with delete delete

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