KR950002332Y1 - Defrosting unit of stiring cycle refregerator - Google Patents

Abstract

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Description

Defroster of Stirling Cycle Refrigerator

1 is a longitudinal sectional view showing the configuration of a conventional sterling cycle refrigerator.

2 is a block diagram of a conventional defrosting apparatus.

Figure 3 is a schematic diagram showing the configuration of the defrosting device according to the present invention.

FIG. 4 is a detailed view of portion A of FIG. 3 showing a coolant passage structure formed in the motor housing.

5 is a detailed cross-sectional view of the first and second cooling water storage tanks, which are main components of the present invention.

* Explanation of symbols for main parts of the drawings

20: Stirring cooler 20a: cooling unit

20b: heat dissipation part 21, 22: first and second cooling water storage tank

21a: slope 23: automatic 2-way valve

24: heat pipe 24a, 24b: evaporation unit and condensation unit

25, 26, 28: 1st, 2nd, 3rd automatic 3 way valve 27: circulation pump

29: motor housing 29a: spiral cooling water passage

30 control means

The present invention relates to a defroster of a refrigerator using a stirling cycle, and in particular, the frost generated in the cold air generating part (cooling part) of the stirling cooler is easily removed by using heat generated from the heat radiating part, and the performance of the driving motor is reduced. A defrosting device of a stirling cycle refrigerator for improving.

A typical refrigerator uses a Rankine cycle to circulate a refrigerant in a sealed pipe to cool air. The refrigerant is condensed in the condenser in a condenser, and the evaporator is cooled by evaporating while passing through an expansion valve and an evaporator. On the other hand, the cooling is performed by circulating the cold air heat-exchanged around the evaporator to the freezer compartment and the refrigerating compartment by an air circulation fan, wherein the air around the evaporator passes through the evaporator to provide the heat of evaporation to the refrigerant and Is cooled.

The general refrigerator as described above has a serious adverse effect on air pollution, such as the refrigerant (R-12 of the CFC series) destroys the air ozone layer. Recently, the use of such a refrigerant is regulated, and thus a new type of refrigerator is required. Was done.

Therefore, the present inventors use a stirling cycle module as a cooler to cool the air, and circulate the cooled air in an item storage room with a cold circulation fan to cool an item such as food, thereby eliminating the need for a cooler cycle. He developed the anti-corrosive refrigerator and filed a patent application in Korean Patent Application Nos. 90-22023, 22305, and 22308.

However, the conventional stirling cycle refrigerator has a defect that causes frost in the cooling unit, which is a cold air generating unit, when the sterling module for generating cold air, that is, the sterling cooler is operated for a long time, causes deterioration of the heat transfer effect.

Therefore, there is a need for a defrosting device for melting the frost of the cooling unit as a cold air generating unit.

1 is a longitudinal cross-sectional view of a stirling cycle refrigerator having a conventional defrosting device, and FIG. 2 is a block diagram of a defrosting heater. As shown in the drawing, a general stirring cycle refrigerator includes a freezer compartment 2 and a refrigerating compartment (2) in a refrigerator main body (1). 3), a sterling cooler 4 for generating cold air and a cold air circulation fan 5 for circulating cold air are provided.

The Stirling Cooler (4) has a cooling unit (6) and a heat dissipation unit (7), which is a cold air generating unit, a heat dissipation tube (8) is connected to the heat dissipation unit (7), and a defrost heater to the cooling unit (6). (9) is wound, the defrost heater (9) is configured such that the operation is controlled by the defrost timer (10).

In addition, the lower portion of the sterling cooler (4) is provided with a water support (11) for collecting the water of frost melted by the defrosting action.

In the drawings, reference numerals 8a and 8b show cooling imports and exits, 12 shows a heat insulating plate, 13 shows a driving motor, and 14 shows a motor housing.

In the general Stirring cycle refrigerator configured as described above, as the driving motor 13 is driven, cold air is generated in the cooling unit 6 of the Stirling Cooler 4, and the cold air is cooled by the cold air circulation fan 5. ) And the refrigerating chamber (4), the heat released from the heat dissipation unit (7) is cooled by the cooling water.

On the other hand, as the sterling cooler 4 is operated, frost is generated in the cooling unit 6, and when the frost is formed to a certain thickness for a predetermined time, the sterling cooler 4 is stopped and the defrost timer 10 The defrost heater 9 mounted on the surface of the cooling unit 6 is operated to melt frost, and the melted water is collected in the water support 11 located at the lower portion thereof.

However, the defrosting apparatus of the conventional sterling cycle refrigerator attempted as described above is very uneconomical by using an electric heat heater, which is expensive and expensive, as the defrost heater 9 for defrosting the cooling unit 6. There was a downside.

In view of this, the object of the present invention is to provide a defrosting device of a sterling cycle refrigerator, which allows simple and effective removal of frost caught in a cooling unit by using heat generated from a heat radiating portion of a sterling cooler.

Another object of the present invention is to provide a defrosting device of a stir cycle refrigerator for forming a spiral cooling water flow path in a motor housing to prevent overheating of the motor to further improve the performance of the driving motor.

In order to achieve the object of the present invention as described above, a separate first and second coolant storage tanks for storing the coolant adjacent to the Stirling cooler are connected to each other via an automatic two-way valve to install the first coolant storage tank. And connecting the cooling unit of the sterling cooler with at least one heat pipe and starting from the first cooling water storage tank, the first automatic three-way valve, the second automatic three-way valve, the circulation pump, the heat dissipation part of the sterling cooler, and the third automatic. A closed circuit line passing through the three-way valve and the motor housing to the first coolant storage tank, and starting from the second coolant storage tank, the first automatic three-way valve, the second automatic three-way valve, the circulation pump, the sprinkler An open circuit line connected to the first coolant storage tank through the heat dissipation unit, the third automatic three-way valve and the motor housing, and the automatic two-way valve and the first, second and third automatic three-way valves. To control the behavior of Defrost of the spring cycle refrigerator having a control means, the heat of the radiating portion of the sterling cooler is collected in the first cooling water storage tank using the coolant, and the heat is transferred to the cooling unit of the sterling cooler through the heat pipe. An apparatus is provided.

The bottom surface of the first coolant storage tank is inclined at a predetermined angle, and several heat pipe evaporators are disposed stepwise with different lengths along the inclined surface to incline the cooling unit of the Stirling Cooler to condense the heat pipe. And are individually connected to each other, and a lower portion of the first coolant storage tank is connected to a second coolant storage tank filled with a predetermined amount of coolant.

In addition, the outer surface of the motor housing is formed in the cooling water passage of the spiral structure is configured to cool the motor.

The defrosting apparatus of the Stirling cycle refrigerator according to the present invention as described above collects the heat dissipation heat of the sterling cooler to the first cooling water storage tank by using the cooling water and connects the heat between the first cooling water storage tank and the cooling part of the sterling cooler. By removing heat generated in the cooling unit of the Stirling Cooler by transferring the heat pipe to the cooling unit, it is economically more advantageous than defrosting using a conventional electric heater, and also forms a spiral cooling water passage in the motor housing. It is also a side effect that the performance of the motor can be maintained because the overheating of the motor can be prevented by flowing the coolant into the passage.

Hereinafter, the defrosting apparatus of the Stirling cycle refrigerator according to the present invention as described above will be described in more detail according to an embodiment shown in the accompanying drawings.

FIG. 3 is a schematic diagram of the present invention Stirring Cycle Refrigerator Defroster, FIG. 4 is a detail A of FIG. 3, and FIG. 5 is a detailed cross-sectional view of the first and second cooling water storage tanks of the present invention. Similarly, the defrosting apparatus of the Stirling cycle refrigerator according to the present invention automatically separates the first and second coolant storage tanks 21 and 22 for storing the coolant C adjacent to the Stirling cooler 20. At least one (three in the example) heat pipe 24 of the cooling unit 20a of the first cooling water storage tank 21 and the Stirling Cooler 20 by being connected to and installed through the valve 23. And the heat dissipation unit 20b of the first and second automatic three-way valves 25 and 26, the circulation pump 27, and the Stirling cooler 20, starting from the first cooling water storage tank 21. A closed circuit line connected to the first coolant storage tank 21 through the third automatic three-way valve 28 and the motor housing 29 and the second coolant storage tank ( 22, the first process, that is, the first, second automatic three-way valve (25), 26, the circulation pump 27, the heat dissipation portion 20b of the sprinkler 20, the third automatic 3 An open circuit line connected to the first cooling water storage tank 21 through the room valve 28 and the motor housing 29, and the automatic two-way valve 23 and the first, second and third automatic Control means 30, such as a timer device for controlling the three-way valve (25), (26), (28), and the like to cool the water (C) to the heat radiating portion (20b) of the stirling cooler (20) In one place, for example, the first cooling water storage tank 21, and the heat is configured to be transferred to the cooling unit 20a of the Stirling cooler 20 through the heat pipe 24, reference numeral 31 in the drawing The drip tray 32 is a heat dissipation tube.

In other words, the heat dissipation part 20b of the stirling cooler 20 is connected to the coolant storage tank 21 by the heat dissipation tube 32, and the front and the outlet of the cooling water inlet side circulation pump 27 of the heat dissipation part 20b. The second and third automatic three-way valves 26 and 28 are positioned on the side, respectively, and the first automatic three-way valve 25 includes a second coolant storage tank 22 and the second automatic three-way valve ( 26) is located in the middle of the connecting line.

In addition, the first coolant storage tank 21 is positioned higher than the second coolant storage tank 22, and the two coolant storage tanks 21 and 22 are automatically opened by the two-way valve 23. Are connected in communication.

In addition, one of the outlets of the third automatic three-way valve 28 is the heat dissipation tube 32 side, the other is connected to the motor housing 29, which is again at the top of the first cooling water storage tank 21 Connected.

In addition, one of the inlet of the second automatic three-way valve 26 in front of the circulation pump 27, the heat dissipation tube 32, and the other two inlets are the first, second cooling water storage tank 21, ( 22) is connected to the outlet side of the first automatic three-way valve 25 is connected to the line from the lower end of the 22.

That is, in the connection structure as described above, the cooling water closed circuit line centering on the first cooling water storage tank 21 and the cooling water opening starting at the second cooling water storage tank 22 and ending at the first cooling water storage tank 21 are opened. Circuit lines, two cooling water lines will be configured.

In addition, the bottom surface of the first cooling water storage tank 21 is inclined at a predetermined angle. In this example, several heat pipes 24 and the evaporator 24a have different lengths along the inclined surface 21a. It is located in a stepwise manner and is individually connected to the condensation part 24b of the heat pipe 24 which obliquely surrounds the cooling part 20a of the sterling cooler 20.

That is, the heat pipe condensation part 24b located at the cooling part 20a of the sterling cooler 20 is connected to the evaporation part 24a located at the deepest part of the first cooling water storage tank 21 at the top (which is Some of the evaporation is submerged even if there is a little coolant in the storage tank.) The other is connected according to different heights and depths.

In the motor housing 29, a cooling water passage 29a having a helical structure is formed, and the cooling water C passes through the passage 29a to prevent rupture of the motor.

Here, the drive motor and each of the automatic directional valves (23), (25), (26), (28) are connected to the control means 30 to operate in accordance with the control of the control means, the second coolant The storage tank 22 is formed to a size that can accommodate all the cooling water C of the first cooling water storage tank 21.

Hereinafter, the operation and effects of the present invention defrosting device as described above.

When the sterling cooler 20 is operated in a normal state, the coolant moves in a closed circuit line between the heat dissipation unit 20b and the heat dissipation tube 32. At this time, since the temperature of the cooling unit 20a is lower than that of the freezer compartment and the refrigerating chamber (see FIG. 1) of the refrigerator, frost is generated on the surface of the cooling unit 20a by the hot and humid air in the refrigerator. Is operated for a predetermined time, and the direction of the second and third automatic three-way valves 26, 28 by the control means 30 is the motor housing 29 and the coolant storage tank 21, ( 22, the automatic two-way valve 23 is closed so that the coolant through the heat dissipation unit 20b is collected in the second coolant storage tank 21 through the coolant passage 29a installed in the motor housing 29. .

Again, a certain time [time for the level of the second coolant storage tank 22 to be lowered and the heat pipe 24 evaporator 24a in the first coolant storage tank 21 to be locked, for example, a predetermined time After passing through, the position of the first automatic three-way valve 25 is changed from line A to line B by the control means 30 to form one closed circuit.

Accordingly, the temperature of the cooling water of the first cooling water storage tank 21 rises while passing through the heat dissipation portion 20b of the Stirling Cooler 20 and the cooling water passage 29a of the motor housing 29, and the temperature of the cooling water of the first cooling water storage tank 21 is increased. The temperature of the evaporator 24a of the heat pipe 24 which is immersed in the cold water is also increased to exchange heat with the condenser 24b of the cooling unit 20a of the Stirling Cooler 20.

That is, the heat dissipation portion 20b of the stirling cooler 20 is collected in one place (first cooling water storage tank: 21) using cooling water, and the heat is removed to defrost the cooling portion 20a through the heat pipe 24. Will be.

At this time, the driving motor is in the operation stop state.

When the defrost is completed by this action, the driving motor is driven, and the second and third automatic three-way valves 26 and 28 form a cooling water circuit toward the heat dissipation tube. The valve 25 is also returned to its original position and connected to the line A. The automatic two-way valve 23 is opened so that the coolant in the first coolant storage tank 21 flows to the second coolant storage tank 22 and is stored.

At this time, since the bottom surface of the first coolant storage tank 21 is inclined, no coolant remains in the tank 21.

As described in detail above, the defrosting apparatus of the Stirling cycle refrigerator according to the present invention collects the heat of the heat radiating portion of the sterling cooler to the first cooling water storage tank by using the cooling water, and the heat is stored between the heat dissipating portion of the storage tank and the sterling cooler. Defrost generated in the cooling section of the Stirling Cooler by transferring the heat pipe connected to the cooling section, which is economically more advantageous than defrosting using a conventional electric heater, and also has a spiral cooling water in the motor housing. It also has the side effect of maintaining the performance of the motor because it is possible to form a passage to flow the coolant to the passage to prevent overheating of the motor.

Claims (3)

In the defrosting apparatus of the Stirling cycle refrigerator, separate first and second coolant storage tanks 21 and 22 for storing the coolant adjacent to the Stirling cooler 20 via the automatic two-way valve 23. By connecting and connecting the first cooling water storage tank 21 and the cooling unit 20a of the Stirling cooler 20 with at least one heat pipe 24, the first cooling water storage tank 21 and the Stirling cooler ( The cooling unit 20a of the 20 is connected to at least one heat pipe 24, starting from the first coolant storage tank 21, and the first and second automatic three-way valves 25, 26, The cooling water closed circuit connected to the first cooling water storage tank 21 through the circulation pump 27, the heat dissipation portion 20b of the sterling cooler 20, the third automatic three-way valve 28 and the motor housing 29 again. Starting from the line and the second coolant storage tank 22, the first and second automatic three-way valve 25, 26, the circulation pump 27, the stir cooler heat dissipation unit 20b, the third automatic three-way valve 28 and motor housing ( 29 is provided with a cooling water open circuit line connected to the first cooling water storage tank 21 through the automatic two-way valve 23 and the first, second and third automatic three-way valves 25, ( 26) and (28), the control means 30 to control the defrosting of the sterling cooler cooling unit 20a by using the heat radiating section 20b heat of the sterling cooler 20, characterized in that Defroster for Stirling Cycle Refrigerator. The bottom surface of the first cooling water storage tank 21 is inclined at a predetermined angle, so that several heat pipe evaporators 24a are cascaded with different lengths along the inclined surface 21a. Respectively connected to the condensation part 24b of the heat pipe 24 which inclines the cooling part 20a of the sterling cooler 20, and a lower part of the first cooling water storage tank 21, the second cooling water storage tank. Defrosting apparatus of the Stirling cycle refrigerator, characterized in that the 22 is connected to be installed in communication. The defrosting apparatus according to claim 1, wherein a spiral cooling water passage (29a) is formed in the motor housing (29) for cooling the drive motor.