KR20020092335A - Freezer system using peltier element - Google Patents

Abstract

PURPOSE: A refrigerator system using peltier element is provided to improve cooling efficiency by the peltier element. CONSTITUTION: A heat radiating line(13) with a heat radiating pump(11) and a heat radiating heat exchanger(12) is connected with a heat radiating part(22) of a peltier element(20) and installed in a heat radiating compartment(3). A receiver tank(4) for collecting refrigerant is installed on a refrigerant line(5) in a refrigerator compartment(2). A refrigerant pump(6) and a circulating pump(7) are installed on the refrigerant line extending into the heat radiating compartment. The receiver tank is connected with the refrigerant line of the heat radiating compartment by a discharge line(8) with a discharge valve(9). The refrigerant line of the heat radiating compartment is connected with the heat radiating heat exchanger of the heat radiating line by a bypass line(14) with a bypass valve(15).

Description

Freezer system using peltier element

The present invention relates to a freezer system using a Peltier element, and more particularly, a refrigerant recovery receiver tank is installed on a refrigerant line connected to an endothermic portion of the Peltier element, and the receiver tank extends toward the heat dissipation chamber. This refrigerant line is connected to the heat radiation heat exchanger of the heat radiation line installed inside the heat dissipation chamber. During normal operation of the system, the internal temperature of the heat dissipation chamber is reduced to an appropriate level to improve the cooling efficiency by the Peltier element, When the Peltier element is stopped by this operation, the internal heat of the heat dissipation chamber can be prevented from entering the refrigerating chamber and the temperature of the heat dissipation chamber can be lowered within a short time, thereby preventing the load generated when the system is restarted. In addition to ensuring safe operation, the endothermic portion of the Peltier element The Peltier element used for the small sized refrigeration unit is used only as a small refrigeration unit by using the cooled refrigerant as a cooling source for the heat generating part of the Peltier element for the freezer compartment, and detachably installing a refrigerating case in which the coolant is stored on each refrigerant line of the refrigerating compartment and the freezer compartment. In addition, the Peltier element can be easily applied to various air conditioners such as spot coolers using ice storage systems, and the Peltier element's cooling capacity can be improved to almost the same level as the general refrigeration and freezing units using compressors and evaporators. It relates to a freezer system using the device.

In general, the Peltier effect is one of the electrical properties of junctions in electronics and materials engineering, and it is the heat generated when current flows through the junction between two different materials. The Peltier effect is reversible in the sense that it consists of emission and absorption, and if heat is generated when the current flows in one direction, it absorbs heat when the current flows in the opposite direction.

The most representative example of applying the Peltier effect as described above is a Peltier device in which an N-type semiconductor device and a P-type semiconductor device are connected by a metal plate, and when the power is supplied to the Peltier device, the N-type through the first contact metal plate. Since current is transmitted to the semiconductor device, current flows to the second contact metal plate through the connection metal plate and the P-type semiconductor device, so that heat generation occurs in the first and second contact metal plates, and endothermic phenomenon occurs in the connection metal plate. .

Therefore, when the Peltier element is installed in the refrigerating device such that the heat absorbing portion is exposed to the refrigerating compartment and the heat generating portion is exposed to the external space of the refrigerating compartment such as the heat dissipation chamber, the internal heat of the refrigerating compartment is generated by the flow of current through the Peltier element. It is absorbed by the heat absorbing part, so that the temperature of the refrigerating compartment can be easily stored, so that various refrigeration items can be easily stored.The Peltier element is not only small in noise, but also does not generate any pollutants when disposed of. Likewise, Peltier devices have been actively applied to industrial fields such as small refrigerators that can be easily installed in a narrow space in a room without the need to lower the temperature of the refrigerator to very low levels, or portable refrigerators that use batteries as a power source.

However, since the cooling performance of the heat absorbing part is dependent on the temperature of the heat generating part, the Peltier device as described above does not reduce the cooling efficiency by the Peltier device when the temperature of the heat generating part cannot be lowered to an appropriate level. In order to lower the negative temperature, an oil-type cooling device or an air-cooled cooling device has been applied in the past, but such a cooling device does not have a large heat dissipation area or heat dissipation effect. Therefore, it is difficult to reduce the temperature of the heat dissipation side of the Peltier element to an appropriate level in a short time. In the case of the oil type cooling device, the device itself is not only expensive, but additional problems occur due to oil leakage and exchange.

As described above, it is difficult to maintain the temperature of the heat generating portion side of the Peltier element at an appropriate level within a short time by the conventional oil-type or air-cooled cooling device. When the operation of the Peltier element is stopped due to various reasons, the heating portion side of the Peltier element is Since heat is easily introduced into the refrigerating compartment, the internal temperature of the refrigerating compartment is increased, causing damage to the refrigerated articles stored in the refrigerating compartment, and the elevated temperature of the refrigerating compartment which is in contact with the endothermic section when the Peltier element is restarted, Due to the considerable load on the Peltier element due to temperature, there was a problem in that Peltier element failure occurs frequently.

As described above, it is difficult to reduce the temperature of the heating part of the Peltier element to an appropriate level as well as to apply the Peltier element due to the failure of the device generated when the Peltier element is stopped. There is a problem that is limited to such fields as small refrigerators or portable refrigerators used for storing cosmetics or medicines, and this makes it impossible to properly apply various advantages of the Peltier element to a refrigerator or an air conditioner that requires rather high cooling performance. There was a problem.

The present invention has been made to solve the above-mentioned conventional problems, the freezer system using the Peltier element according to the present invention is to install a receiver tank for refrigerant recovery on the refrigerant line connected to the heat absorbing portion of the Peltier element, The receiver tank is connected to the refrigerant line extending to the heat dissipation chamber side, and this refrigerant line is connected to the heat dissipation heat exchanger of the heat dissipation line installed inside the heat dissipation chamber. Therefore, during normal operation of the system, the internal temperature of the heat dissipation chamber is lowered to an appropriate level. When the Peltier element is stopped due to various reasons, it can lower the temperature of the heat sink in a short time while preventing the internal heat of the heat sink from entering the refrigerating chamber. To ensure the safe operation of the device by preventing the load from restarting Let it be the technical problem.

In addition, the present invention uses the refrigerant cooled in the heat absorbing portion of the Peltier element for the refrigerating compartment as a cooling source for the heat generating portion of the Peltier element for the freezer compartment, and on each refrigerant line of the refrigerating compartment and the freezer compartment detachably installed storage storage case in which the coolant is stored In addition, the Peltier element, which has been applied to small refrigeration units, can be easily applied to various air conditioners such as spot coolers using ice storage systems, as well as the refrigeration system. Another technical challenge is to be able to improve to almost the same level as the freezer.

1 is an apparatus diagram showing an embodiment of a freezer system using a Peltier device according to the present invention.

2 is a device diagram showing another embodiment of the present invention.

Figure 3 is a device diagram showing another embodiment of the present invention.

Figure 4 (a) and (b) is a cross-sectional view showing the heat transfer promoting means applied to the Peltier element of the freezer system according to the present invention.

<Explanation of symbols for main parts of drawing>

1 Insulation Wall 2 Refrigerating Room 3 Heat Dissipation Room

4: receiver tank 5: refrigerant line 6: refrigerant pump

7: circulation valve 8: discharge line 9: discharge valve

10 refrigeration unit 11 heat dissipation pump 12 heat dissipation heat exchanger

13: heat dissipation line 14: bypass line 15: bypass valve

16: heat dissipation fan 17: refrigeration heat exchanger 18: blowing fan

20: Peltier element 21: heat absorbing portion 22: heat generating portion

23,28: heat transfer plate 24: P pole 25: N pole

26: electrode plate 29: heat transfer promoting means 30: refrigeration apparatus

31 freezing chamber 32 freezing heat exchanger 33 refrigerant line

40: ice storage device 41: heat storage case 42: heat storage case

Hereinafter, described in detail with reference to the accompanying drawings, the present invention for achieving the above object is as follows.

1 is an apparatus diagram showing an embodiment of a freezer system using a Peltier element according to the present invention, 21A is a heat sink fin, 22a is a heat sink fin, which is not described in the description of the reference numerals.

In an embodiment of the present invention, as shown in FIG. 1, the refrigerating chamber 2 and the heat dissipation chamber 3 are partitioned by a heat insulating wall 1, and the heat absorbing portion 21 is disposed inside the heat dissipation chamber 3. ) And a heat absorbing fin 21a and a heat radiating fin 22a protruding from the heat generating unit 22, and the heat absorbing portion 21 of the Peltier element 20 has an inside of the refrigerating chamber 2. Refrigerant line (5) extending to the contact is installed to be in contact with the heat absorbing fin (21a), the heat generating portion 22 of the Peltier element 20 is provided with a heat dissipation pump 11 and a heat dissipation heat exchanger (12) The heat dissipation line 13 installed inside the heat dissipation chamber 3 is connected to the heating fins 22a.

In addition, the refrigerant line 5 extending into the refrigerating chamber 2 is provided with a refrigerant recovery receiver tank 4 capable of recovering and storing a predetermined amount of refrigerant, and circulating the refrigerant through the refrigerant line 5. The refrigerant pump 6 and the circulation valve 7 are installed on the refrigerant line 5 extending into the heat dissipation chamber 3, and the receiver tank 4 discharges the discharge valve 9. Connected to the refrigerant line 5 of the heat dissipation chamber 3 by a line 8, and the refrigerant line 5 of the heat dissipation chamber 3 has a bypass line 14 having a bypass valve 15. It is connected to the heat radiation heat exchanger 12 of the heat radiation line 13 by the.

The circulation valve 7 is opened during normal operation (On) of the Peltier element 20, and is connected to the Peltier element 20 to be closed at the off (Off) of the Peltier element 20 due to various causes, the discharge The valve 9 and the bypass valve 15 are closed during the normal operation (On) of the Peltier element 20, and the Peltier element 20 so as to open when the Peltier element 20 is stopped due to various causes. The refrigerant pump 6 of the refrigerant line 5 and the heat radiation pump 11 of the heat dissipation line 13 are connected to a power source different from the Peltier element 20 so that they are always operated.

1 shows each of the lines 5 and 13 and their devices in a developmental manner in order to more reliably represent the connection state of the various devices installed on the coolant line 5 and the heat dissipation line 13. As a matter of fact, it is preferable that the refrigerant line 5 and the receiver tank 4 are closely installed on the heat insulating wall 1 of the refrigerating compartment 2 to maximize the storage space inside the refrigerating compartment 2, The heat dissipation line 13 and the refrigerant line 5 installed in the heat dissipation chamber 3 are preferably installed in contact with each of the lines 5 and 13 in order to increase heat exchange efficiency.

In addition, the heat dissipation heat exchanger 12 is preferably used that has excellent heat exchange performance, such as a fin-tube type, but the bypass line 14 inside the heat dissipation heat exchanger 12 more easily. In order to install the heat dissipation heat exchanger 12 in the form of a heat dissipation fin protruding from the outside of the tank-shaped body, and a tube-type bypass line 14 is installed therein. In addition to the heat dissipation performance, it is preferable to install in consideration of the heat exchange action between the heat dissipation heat exchanger 12 and the bypass line 14 together.

In addition, the refrigerant flowing through the refrigerant line 5 and the heat dissipating fluid flowing through the heat dissipation line 13 may be any refrigerant used in a general refrigerating and freezing apparatus using a compressor and an evaporator. In consideration of the physical properties and the influence of the refrigerant on the material of the refrigerant line 5 and the heat dissipation line 13, it is preferable to select and use the optimal one.

In the freezer system according to the embodiment of the present invention having the above configuration, the refrigerant line 6 by the refrigerant pump 6 in the state in which only the circulation valve 7 is opened during the normal operation (On) of the Peltier element 20 ( 5) and the heat dissipation line 13 by the heat dissipation pump 11 are performed. In the case of the coolant line 5, the coolant cooled in the heat absorbing part 21 of the Peltier element 20 As the refrigerant flows into the refrigerating chamber 2 through the coolant line 5, the internal temperature of the refrigerating chamber 2 is lowered and stored in the receiver tank 4. Thus, the refrigerant stored in the receiver tank 4 is the refrigerant pump 6. And circulated to the heat absorbing portion 21 side of the Peltier element 20 along the refrigerant line 5 on the heat dissipation chamber 3 side by the circulation valve 7 to recool the refrigerant. In the case of the heat dissipation fluid heated in the heat generating portion 22 of the Peltier element 20 passes through the heat dissipation pump 11 and the heat dissipation heat exchanger 12 As a result, the heat is released into the heat dissipation chamber 3 and is circulated to the heat generating part 22 side of the Peltier element 20 again, thereby reheating the heat dissipation fluid.

In the normal operation of the system as described above, the temperature of the heat generating part 22 of the Peltier element 20 depends on the heat dissipation amount of the heat dissipating fluid circulating through the heat dissipating line 13 and the heat dissipating heat exchanger 12. Since the heat dissipation is simultaneously performed on all the surface areas of the heat dissipation line 13 and the heat dissipation heat exchanger 12, the heat dissipation area and the heat dissipation effect are not only greatly increased, but also the inside of the heat dissipation chamber 3 which is elevated by heat dissipation of the heat dissipation fluid. Since the temperature of the temperature is cooled by the refrigerant flowing along the refrigerant line 5, the heat dissipation line 13 and the heat dissipation heat exchanger 12 can be maintained at a very high level.

In addition, since the Peltier element 20 itself is provided inside the heat dissipation chamber 3, even if most of the endothermic action of the endothermic portion 21 of the Peltier element 20 is used for cooling the refrigerant, a portion thereof is raised. Since it is used to lower the internal temperature of the heat dissipation chamber 3, the cooling action of the refrigerant line 5 can be further contributed to lowering the internal temperature of the heat dissipation chamber 3, and thus the Peltier element ( By lowering the temperature of the heat generating unit 22 of 20), the cooling efficiency of the refrigerant by the Peltier element 20 as well as the refrigerating performance of the refrigerating device 10 in which the Peltier element 20 is installed can be further improved. It will be possible.

In addition, when the operation of the Peltier element 20 is stopped due to various reasons, only the discharge valve 9 and the bypass valve 15 are opened to operate and bypass the bypass line 14 by the refrigerant pump 6. The heat radiation line 13 is operated by the pump 11. In the case of the bypass line 14, the refrigerant remaining on the refrigerant line 5 of the refrigerating chamber 2 by the refrigerant pump 6. The refrigerant stored in the receiver tank 4 is circulated to the heat dissipation heat exchanger 12 of the heat dissipation line 13 through the discharge line 9 and the bypass line 15 while being recovered to the receiver tank 4. In the case of the line 13, the heat radiation fluid is circulated as in the normal operation of the Peltier element 20.

When the bypass line 14 and the heat dissipation line 13 operate as described above, all of the refrigerant remaining on the refrigerant line 5 on the refrigerating chamber 2 side is recovered to the receiver tank 4 and thus the heat dissipation chamber ( The internal temperature of the refrigerating compartment (2) is blocked because the internal heat of 3) is blocked from flowing into the refrigerating compartment (2) through the refrigerant and the refrigerant stored in the receiver tank (4) is used as a cooling source of the refrigerating compartment (2) for a predetermined time. Is prevented from being sharply lowered, thereby allowing the refrigerated article stored in the refrigerating compartment 2 to be safely stored for a predetermined time even when the Peltier element 20 is stopped.

In addition, the cooling action of the heat dissipation chamber 3 through the surface area of the bypass line 14 during the flow of a part of the refrigerant stored in the receiver tank 4 to the heat dissipation heat exchanger 12 through the bypass line 14. At the same time, the cooling of the heat dissipation fluid is performed by the refrigerant introduced into the heat dissipation heat exchanger 12, and the cooled heat dissipation fluid rapidly reduces the temperature of the heat-generating part 22 side of the Peltier element 20. By lowering the load, the load on the Peltier element 20 can be minimized when the Peltier element 20 is restarted, thereby preventing the failure of the device, and the normal operation of the refrigerating device 10 can be performed in a very short time. will be.

Figure 2 is a device diagram showing another embodiment of a freezer system using a Peltier element according to the present invention, the reference numeral 3a, which is not described in the description of the reference numerals for the drawing, and 3b represents the inlet.

In another embodiment of the present invention, as shown in FIG. 2, the heat dissipation chamber 3, the refrigerating chamber 2, and the freezing chamber 31 are partitioned into separate spaces by the heat insulation wall 1. A heat dissipation line 13 having a heat dissipation pump 11 and a heat dissipation heat exchanger 12 is installed in the interior of the refrigerator 3, and a refrigerant pump 6 and a refrigeration heat exchanger 17 are installed in the refrigerating chamber 2. Refrigerant line (5) is provided, and the refrigerant line (33) having a refrigeration heat exchanger (32) is installed inside the freezing compartment (31).

The Peltier element 20 between the heat dissipation chamber 3 and the refrigerating chamber 2 is exposed to the heat dissipation chamber 3 and the heat absorbing portion 21 is exposed to the refrigerating chamber 2. Is installed on the heat insulating wall 1, and the heat generating portion 22 is exposed to the refrigerating chamber 2 between the refrigerating chamber 2 and the freezing chamber 31, and the heat absorbing portion 21 is transferred to the freezing chamber 31. The exposed Peltier element 20 is installed on the heat insulation wall 1, and the portion of the heat insulation wall 1 on which each Peltier element 20 is installed is tightly sealed to block the inflow of air.

The heat dissipation line 13 of the heat dissipation chamber 3 is connected to the heat generation unit 22 of the Peltier element 20 provided between the heat dissipation chamber 3 and the refrigerating chamber 2, and the refrigerating chamber 2 and the freezing chamber ( The coolant line 33 of the freezer compartment 31 is connected to the heat absorbing portion 21 of the Peltier element 20 provided between 31, and the coolant line 5 of the refrigerating compartment 2 is a Peltier side of the heat dissipation chamber 3. The heat absorbing portion 21 of the heat absorbing portion 21 of the element 20 and the heat generating portion 22 of the Peltier element 20 on the freezing chamber 31 side, respectively, is installed. The coolant cooled in the c) can be used as a cooling source of the heat generating section 22 of the Peltier element 20 on the freezing chamber 31 side.

Therefore, the Peltier element 20 of the heat dissipation chamber 3 side is a freezer compartment so that the cooling function of the refrigerating compartment 2 can be performed smoothly while cooling the heat generating unit 22 of the Peltier element 20 of the freezing compartment 31 side. It is preferable to use a slightly larger capacity than the (31) side Peltier element 20, and when the capacity of each Peltier element 20 is the same, the number of the Peltier elements 20 of the heat dissipation chamber 3 is determined in the freezer compartment 31. 1 to 2 more than the number of the Peltier element 20 on the side, and the heat dissipation heat exchanger 12 in order to more effectively lower the temperature of the heat generating section 22 of the Peltier element 20 on the heat dissipation chamber 3 side. A heat dissipation fan 16 is installed at the side of the heat dissipation fan, and a heat dissipation port 3a for discharging internal heat and an inlet 3b for inflow of outside air are respectively formed at the outer heat dissipation wall 1 of the heat dissipation chamber 3.

FIG. 2, which shows another embodiment of the present invention, also like FIG. 1, shows each line 5 in order to more reliably indicate the connection state of various devices installed on the refrigerant lines 5 and 33 and the heat radiation line 13. 33, 13, and the apparatus thereof in a developmental manner, substantially each refrigerant line 5, 33, and the refrigerating and freezing heat exchangers 17, 32 are the refrigerating chamber 2 and the freezing chamber 31. It is preferable to maximize the storage space inside the refrigerating compartment (2) and the freezing compartment (31) by installing in close contact on the heat insulating wall (1) of the), the refrigerating heat exchanger (17) and the freezer heat exchanger (32) It is preferable to use an excellent heat exchanger such as a pin-tube type.

When each Peltier element 20 of the freezer system according to another embodiment of the present invention having the configuration described above is operated together with the heat dissipation pump 11 and the refrigerant pump 6, the heat dissipation line inside the heat dissipation chamber 3 (13) and each of the refrigerant lines 5 and 33 in the refrigerating chamber 2 and the freezing chamber 31 operate at the same time.

First, in the case of the heat dissipation line 13, the heat dissipation fluid heated in the heat generating part 22 of the Peltier element 20 passes through the heat dissipation pump 11 and the heat dissipation heat exchanger 12, and then inside the heat dissipation chamber 3; The heat is discharged to the heat generating part 22 of the Peltier element 20 and is reheated. In this process, the heat released into the heat dissipation chamber 3 is discharged by the heat dissipation fan 16 and the heat dissipation port 3a. At the same time as being discharged to the outside of the heat dissipation chamber 3, outside air of low temperature flows into the heat dissipation chamber 3 through the inlet port 3b.

In addition, the refrigerant line 5 of the refrigerating chamber 2 has the refrigerant cooled in the heat absorbing portion 21 of the Peltier element 20 on the heat dissipation chamber 3 side along the refrigerant line 5 and on the freezing chamber 31 side. The heat generating unit 22 of the Peltier element 20 is first cooled, and then circulated to the refrigerating heat exchanger 17 to lower the internal temperature of the refrigerating chamber 2, and the refrigerant used for cooling is the refrigerant pump 6. The coolant is circulated again to the heat absorbing part 21 side of the Peltier element 20 on the heat dissipation chamber 3.

In addition, the refrigerant line 33 of the freezing compartment 31 is transferred from the refrigerant line 33 in contact with the heat absorbing portion 21 of the Peltier element 20 of the freezing compartment 31 to the refrigerant stored in the freezing heat exchanger 32. The refrigerant is stored in the inside of the freezer heat exchanger (32) is primarily cooled, and the refrigerant inside the cooled freezer heat exchanger (32) performs heat exchange with the air inside the freezer compartment (31), thereby It will lower the internal temperature.

In the operation of the system as described above, the temperature of the heat generating portion 22 of each Peltier element 20 depends on the heat dissipation amount of the fluid circulating through the heat dissipation line 13 and the heat dissipation heat exchanger 12. Since the heat dissipation area 13 and the heat dissipation heat exchanger 12 are simultaneously made at all surface areas, the heat dissipation area and the heat dissipation effect are greatly increased, and the internal temperature of the heat dissipation chamber 3 increased by the heat dissipation of the fluid is dissipated. Most of the air is discharged to the outside of the heat dissipation chamber 3 by the fan 16 and the heat dissipation hole 3a, and at the same time, external air of low temperature flows into the heat dissipation chamber 3 through the inlet port 3b. The heat dissipation amount from the heat dissipation line 13 and the heat dissipation heat exchanger 12 can be maintained at a very high level.

Since the heat dissipation amount from the heat dissipation line 13 and the heat dissipation heat exchanger 12 can be maintained at a very high level as described above, the temperature of the heat generating part 22 of the Peltier element 20 on the heat dissipation chamber 3 side is maintained at an appropriate level. It is possible to improve the cooling performance of the heat absorbing portion 21 of the Peltier element 20 on the heat dissipation chamber 3 side by lowering the temperature of the heat dissipation chamber 3. Even if the refrigerant is used as the cooling source of the heat generating unit 22 of the Peltier element 20 on the inner copper chamber 31 side, not only the cool air required for the refrigerating compartment 2 can be supplied sufficiently but also the Peltier element on the freezer compartment 31 side ( Since the temperature of the heat generating unit 22 of 20) is lowered to a level suitable for freezing, the Peltier element 20, which has been applied to a small refrigeration device, can be easily applied to the freezing device 30.

In addition, when the operation of the Peltier element 20 is stopped due to various reasons, the Peltier element 20 is formed by the heat dissipation pump 11, the heat dissipation heat exchanger 12, and the heat dissipation fan 16 inside the heat dissipation chamber 3. The heat dissipation effect on the heat generating unit 22 temperature of the c) is continuously made, and the inside of the refrigerating chamber 2 is a Peltier element 20 by the refrigerant pump 6 and the refrigerating heat exchanger 17. Cooling operation of the heating unit 22 and the refrigerating chamber 2 itself is made continuously.

Therefore, even when the Peltier element 20 is prevented from suddenly lowering the internal temperature of the refrigerating compartment 2 or the freezing compartment 31, the article stored in the refrigerating compartment 2 or the freezing compartment 31 can be safely stored for a predetermined time. In addition, by lowering the temperature of the heat-generating portion 22 side of each Peltier element 20 in a short time, minimizing the load on the Peltier element 20 when the Peltier element 20 is restarted, it is possible to prevent the failure of the device and Normal operation of the refrigerating device 30 is enabled in time.

3 is an apparatus diagram showing another embodiment of a freezer system using a Peltier element according to the present invention, wherein 2a, which is not described in the description of the reference numerals, represents a cold air inlet 31a.

Another embodiment of the present invention, as shown in Figure 3, in each of the refrigerant line (5) 33 of the refrigerating chamber (2) and the freezing chamber (31) according to another embodiment of the present invention as brine ( Brine) stored therein detachably installed, the heat storage line 13 of the heat dissipation chamber (3) is detachably installed in the heat dissipation case (13) in which the brine is stored as a heat storage material. Peltier element is formed in the heat insulation wall 1 of 2) through a cooling air inlet 2a for discharging cold air to the outside by the blower fan 18 and a cold air inlet 31a communicating with the freezing chamber 31, respectively. An embodiment in which the 20 is applied to the ice storage device 40 is shown, and the technical configuration other than that is the same as the other embodiment of the present invention.

The freezer system according to another embodiment of the present invention operates the Peltier element 20 by using the cheap electric power at night with the function of the refrigerating device 30 according to another embodiment of the present invention. 41, the stored coolant stored in the interior of the night at night, the cold storage case 41 is stored from the cold compartment (2) and the freezing compartment 31 to store the frozen coolant in this way to a device such as a spot-cooler (Spot-cooler) It is used for cooling during the day while being inserted, or while operating the blower fan 18 installed in the refrigerating compartment 2 while the storage case 41 is stored in the refrigerating compartment 2 and the freezing compartment 31. ) And the function to directly supply the cold air in the freezer compartment 31 to various cooling places during the day.

In addition, the main purpose of the heat storage case 42 installed in the heat dissipation line 13 of the heat dissipation chamber 3 is a heat dissipation action by the heat dissipation heat exchanger 12 and the heat dissipation fan 16, and the heat dissipation line 13 flows. By reducing the heat of the heat dissipation fluid more effectively to lower the temperature of the heat generating portion 22 of the Peltier element 20 on the heat dissipation chamber 3 side to suit the ice storage device 40, the heat of the heat dissipation fluid for a predetermined time The absorbed heat storage case 42 is removed from the heat dissipation chamber 3 to naturally discharge heat accumulated in the heat storage case 42, and then reinserted into the heat dissipation chamber 3 to be reused. The case 42 can also be used for applications such as heating.

Figure 4 (a) and (b) is a cross-sectional view showing the heat transfer promoting means applied to the Peltier element of the freezer system according to the present invention, unexplained reference numeral 20a in the description of the reference numerals for the drawings, 23a is interference It represents a pin.

The heat transfer promoting means 29 is installed on the heat absorbing portion 21 and the heat generating portion 22 side of the Peltier element 20 to increase the heat exchange efficiency by the Peltier element 20, so that the Peltier element 20 is installed. To improve the performance of each freezer system according to the present invention to the maximum, as an example thereof, as shown in Fig. 4 (a), the P pole 24 and the N pole 25 each pole plate 26 Peltier element 20 is installed so that one pole plate 26 forms a heat absorbing portion 21 and the other pole plate 26 forms a heat generating portion 22, and the heat absorbing portion 21 of the Peltier element 20 is connected. ) And the heat generating part 22, the interference pin 23a for forming the vortex is provided with the heat absorbing part 21 and the heat transfer plate 23 extending to the heat generating part 22.

As another example of the heat transfer facilitating means 29, the heat absorbing portion 21 (or the heat generating portion) of the Peltier element 20 itself has a trapezoidal or triangular cross section, as shown in FIG. And a flow of refrigerant and heat-dissipating fluid through each of the refrigerant lines 5 and 33 or the heat-dissipating line 13 to the heat-absorbing portion 21 (or the heat-generating portion) formed in this manner. The heat transfer plate 28 is configured to be spaced apart at regular intervals so as to secure a space.

In the heat transfer facilitating means 29, (a), the refrigerant or heat-dissipating fluid flowing between the Peltier element 20 and the heat transfer plate 23 causes flow interference by the interference pins 23a, thereby causing interference. By forming a vortex flow between the fins 23a, the heat exchange efficiency by the Peltier element 20 can be further improved. The heat absorbing part 21 of the Peltier element 20 is illustrated in (b). And the heat generating part 22 to increase the heat exchange area by increasing the heat exchange area, thereby improving the heat exchange efficiency by the Peltier element 20, and thus the overall cooling performance of the freezer system according to the present invention is increased by the compressor and the evaporator. It is intended to be improved to almost the same level as the general refrigeration and freezer using.

As described above, the freezer system using the Peltier element according to the present invention installs a receiver tank for refrigerant recovery on the refrigerant line connected to the heat absorbing portion of the Peltier element, and connects the receiver tank to the refrigerant line extending toward the heat dissipation chamber side. This refrigerant line is connected to the heat radiation heat exchanger of the heat radiation line installed inside the heat dissipation chamber. During normal operation of the system, the internal temperature of the heat dissipation chamber is reduced to an appropriate level to improve the cooling efficiency by the Peltier element, and the Peltier element for various reasons. If the operation is stopped, the internal heat of the heat dissipation chamber can be prevented from flowing into the refrigerating compartment and the temperature of the heat dissipation chamber can be lowered within a short time. Driving can be guaranteed.

In addition, the present invention uses a refrigerant cooled in the heat absorbing portion of the Peltier element for the refrigerating compartment as the heat source cooling source of the Peltier element for the freezer compartment, and on each refrigerant line of the refrigerating compartment and the freezer compartment detachably installed storage storage case in which the coolant is stored In addition, the Peltier element, which was applied only to the small refrigeration unit, can be easily applied to various air conditioners such as a spot cooler using an ice storage system as well as a refrigerating unit. There is an effect that can be improved to almost the same level as the refrigeration and freezer.

Claims (5)

The refrigerating chamber 2 and the heat dissipation chamber 3 are partitioned by the heat insulating wall 1, and the Peltier element 20 having the heat absorbing portion 21 and the heat generating portion 22 is installed inside the heat dissipation chamber 3. In the heat absorbing portion 21 of the Peltier element 20, the refrigerant line 5 extending into the refrigerating chamber 2 is installed, Inside the heat dissipation chamber 3, a heat dissipation line 13 having a heat dissipation pump 11 and a heat dissipation heat exchanger 12 is connected to the heat generator 22 of the Peltier element 20, In the refrigerating chamber (2), a receiver tank (4) for refrigerant recovery is installed on the refrigerant line (5), and the refrigerant pump (6) and the circulation valve (7) for circulation of the refrigerant are the heat dissipation chamber (3). Installed on the refrigerant line (5) extending into the interior of the The receiver tank (4) is connected to the refrigerant line (5) of the heat dissipation chamber (3) by a discharge line (8) having a discharge valve (9), The refrigerant line 5 of the heat dissipation chamber 3 is connected to the heat dissipation heat exchanger 12 of the heat dissipation line 13 by a bypass line 14 having a bypass valve 15. Freezer system using Peltier element. The heat transfer plate according to claim 1, wherein an interference pin 23a for vortex formation extends toward the heat absorbing portion 21 and the heat generating portion 22 on the heat absorbing portion 21 and the heat generating portion 22 of the Peltier element 20. (23) or the heat transfer facilitation means 29 which is alternatively selected from the heat absorbing portion 21 extending in the form of a fin and the heat transfer plate 28 spaced apart to form a flow space of the refrigerant from the heat generating portion 22 side. A freezer system using a Peltier element characterized by the above. The refrigerating chamber 2 and the heat dissipation chamber 3 are partitioned by a heat insulating wall 1, and the heat absorbing portion 21 is exposed to the refrigerating chamber 2 between the refrigerating chamber 2 and the heat dissipation chamber 3, and the heat generation thereof. In the case where the Peltier element 20 in which the part 22 is exposed to the heat dissipation chamber 3 is provided on the heat insulation wall 1, One side of the refrigerating compartment 2 is divided into a freezing compartment 31 by a heat insulating wall (1), the heat absorbing portion (21) is exposed to the freezing compartment (31) on the heat insulating wall (1) and the heat generating unit (22) ( 2) the Peltier device 20 is exposed, In the refrigerating compartment 2, a refrigerant line 5 including a refrigerant pump 6 and a refrigerating heat exchanger 17 is provided with a heat absorbing portion 21 and a freezing compartment 31 of the Peltier element 20 of the heat dissipation chamber 3. Are respectively connected to the heat generating portion 22 of the Peltier element 20, In the freezer compartment 31, a refrigerant line 33 having a freezer heat exchanger 32 is connected to the heat absorbing part 21 of the Peltier element 20 on the freezer compartment 31 side. Inside the heat dissipation chamber 3, a heat dissipation line 13 having a heat dissipation pump 11 and a heat dissipation heat exchanger 12 is connected to the heat generator 22 of the Peltier element 20, Peltier element, characterized in that the heat dissipation opening (3a) and the inlet opening (3b) is formed through the outer heat insulating wall (1) of the heat dissipation chamber (3) for the heat dissipation by the heat dissipation fan 16 and the inflow of outside air, respectively Freezer system using. According to claim 3, wherein the refrigerating chamber (2) and the refrigerant line (5) 33 of the freezing chamber (31), the refrigerating case 41 stored therein is stored detachably installed therein, In the heat radiation line 13 of the heat dissipation chamber 3, a heat storage case 42 having a heat storage material stored therein is detachably installed. The heat insulating wall 1 of the refrigerating compartment 2 is formed with a cooling air inlet 2a for discharging cold air to the outside by the blower fan 18 and a cold air inlet 31a communicating with the freezing compartment 31, respectively. Freezer system using a Peltier device, characterized in that The heat absorbing portion 21 and the heat generating portion 22 side of the Peltier element 20 is provided with an interference pin 23a for forming a vortex on the heat absorbing portion 21 and the heat generating portion 22. Heat transfer facilitation means 29 which is alternatively selected from heat transfer plate 23 extending in the side or heat absorbing portion 21 extending in the form of fin and heat transfer plate 28 spaced apart to form a flow space of the refrigerant from the heat generating portion 22 side. A freezer system using a Peltier element, characterized in that the formation.