KR20030089556A - Evaporation structure of refrigerator - Google Patents

Abstract

PURPOSE: A structure for evaporation of a refrigerator is provided to improve cooling performance of the refrigerator by increasing working time of the refrigerator as an interval between defrosting operations is extended. CONSTITUTION: An evaporation structure(10) comprises an evaporator(20) diagonally inclined, and fixed on a rear side of a freezer compartment(110); a plurality of fans(30,30a) on an upper end of the evaporator; and a driving damper(40) formed as a cylinder to allow the evaporator to be inserted therein, and rotated to change a flowing path of chilled air passing radiating fins of the evaporator depending on driving of the fans. If wind volume of chilled air discharged into the freezer compartment and a refrigerator compartment by one of the fans is rapidly reduced due to the frost formed on the radiating fins of the evaporator, the driving damper having the evaporator inserted therein is rotated by driving of the other of the fans to change the flowing path of chilled air passing the radiating fins of the evaporator to the other part of the evaporator on which no frost is formed.

Description

Evaporation structure of refrigerator

The present invention relates to a refrigerator, and more particularly, a flow path of cold air passing through heat radiation fins (louver fins) of an evaporator fixed to a rear of a conventional freezer compartment to another part of an evaporator which is not frosted. It relates to a refrigerator evaporation structure to improve the cooling performance of the refrigerator according to the setting time of the operation of the defrosting operation for removing the frost formed is longer than in the prior art.

In general, the refrigerator discharges cold air generated by a refrigeration cycle composed of a compressor, a condenser, an expansion valve, an evaporator, and lowers the temperature in the refrigerator to freeze or refrigerate food and the like. As shown in FIG. 1, the main body 100, a freezing chamber 110 and a refrigerating chamber 120 for freezing and refrigerating loads (food) by dividing up and down inside the main body 100, and the main body 100. The refrigerator compartment door 130 and the refrigerator compartment door 140, which are mounted at one side of the refrigerator, to open and close the freezer compartment 110 and the refrigerating compartment 120, and cold air necessary for cooling the freezer compartment 110 and the refrigerating compartment 120 may be generated. It consists of a refrigeration cycle equipment consisting of a compressor 150 and a condenser (not shown), an expansion valve (not shown), and an evaporator 160 forming a refrigeration cycle.

In addition, the cold air generated through the evaporator 160 to take the ambient heat of the elements of the refrigeration cycle equipment to evaporate the refrigerant in the gas phase state to each shelf 170 of the freezer compartment 110 and the refrigerating compartment 120. Cold air discharge ports 190 and 190a are formed in the inner wall 180 of the rear surface of the freezing chamber 110 and the refrigerating chamber 120 to be discharged.

In the refrigerator configured as described above, the refrigerant, which is phase-changed in a low temperature low pressure gas phase by the evaporator 160, flows to the compressor 150 and is compressed from the low temperature low pressure to the high temperature high pressure through the compressor 150, and the compressed high temperature high pressure The gas phase refrigerant is cooled and condensed in the course of passing through the condenser, and is phase-changed to a high-pressure liquid state. The refrigerant, which has been phase-changed into a high-pressure liquid state, is easily evaporated by heat exchange in the evaporator 160 while passing through an expansion valve. After decompression (heat expansion), the refrigerant flows to the evaporator 160 where the evaporation process is performed. As described above, the refrigerant introduced into the evaporator 160 absorbs heat inside the refrigerator and absorbs heat inside the refrigerator. After the phase change to the state to cool the air around it, it forms a refrigeration cycle flowing back into the compressor 150.

At this time, the air (chill) cooled while the heat is lost to the refrigerant through heat exchange with the evaporator 160 is driven by the blower fan 200 installed on the evaporator 160, the freezing chamber 110 and the refrigerating chamber 120. The temperature of the freezing compartment 110 and the refrigerating compartment 120 is lowered as the discharge air is circulated through the cold air discharge ports 190 and 190a formed in the rear inner wall 180.

Thereafter, each of the cold air whose temperature is raised by circulating the freezing compartment 110 and the refrigerating compartment 120 is supplied to the evaporator 160 again through the cold air duct 210 to be recooled, at which time the evaporator 160 Since the cold air provided at the low temperature and humidity (humid cold air mixed with external air during frequent opening and closing of the refrigerator door) is frosted on the surface of the evaporator 160 due to the temperature difference between the evaporator 160 and the low temperature and high temperature cold air. When the low temperature and humid cold air flows through the evaporator 160, as shown in FIG. 2, the flow path of the cold air that is heat-exchanged with the evaporator 160 continues in one direction. When formed, as shown in Figure 3, the thickness of the frost formed on the surface of the evaporator 160 is thick, and at the same time as the frost implantation rate is rapidly progressed standing on the surface of the evaporator 160 While acting as a flow resistance to prevent the flow of cold air passing through the evaporator 160, the amount of cold air discharged to the freezing chamber 110 and the refrigerating chamber 120 by the blowing fan 200 is rapidly reduced, accordingly There was a big problem that the cooling performance of the refrigerator is greatly reduced.

In order to solve this problem, as illustrated in FIGS. 2 and 3, an evaporator 160 provided with a defrosting line (heater) 160a has been provided. When frost is formed on the surface of the evaporator 160, Defrost operation was periodically performed using the defrosting line 160a to remove frost formed on the evaporator 160. However, in the above defrosting operation, the refrigeration cycle of the refrigerator being operated is stopped, and then the evaporator ( Since a separate defrosting operation is performed using the defrosting line 160a installed in the 160, the defrosting line 160a installed in the evaporator 160 is periodically operated to perform the defrosting operation as described above periodically. There was also a big problem that the power consumption used in the refrigerator is greatly increased, such as frost formed on the surface.

In order to solve the above problems, the present invention is variable so that the flow path of cold air passing through the heat radiation fins (louver fins) of the evaporator fixed to the rear of the conventional freezing chamber is flowed to another part of the evaporator which is not frosted. Since the operation setting time of the defrosting operation for removing the frost formed on the evaporator can be set longer than in the prior art, while increasing the refrigerator operating time according to the frequent defrosting operation of the conventional evaporator, that is, the time during which the refrigeration cycle takes place, Accordingly, the purpose is to improve the cooling performance of the refrigerator.

In addition, the defrosting operation is not operated when the defrosting operation timing of the present invention is frosted in one direction of the evaporator as in the prior art, the bidirectional direction of the evaporator applied to the present invention, that is, the initial flow direction of cold air and the flow path of cold air Since the defrosting operation is started when frost is formed on the evaporator of the variable direction part, the defrosting operation time of the present invention can be set longer than the frequent defrosting operation time of the conventional evaporator, and the consumption used in the refrigerator compared to the conventional one. Another purpose is to allow for a significant reduction in power.

An object of the present invention, the evaporator is installed obliquely inclined to the rear of the freezer compartment, a plurality of blower fan installed on the top of the evaporator, and the flow path of the cold air passing through the evaporator in accordance with the driving of the blower fan is variable. It can be solved by the refrigerator evaporation structure of the present invention composed of a drive damper rotated at an angle, will be described in detail with reference to the accompanying drawings.

1 is a side cross-sectional view showing a structure and a cold air circulation state of a typical refrigerator.

Figure 2 is a front sectional view of a freezer compartment of a conventional refrigerator equipped with an evaporator and a blowing fan.

Figure 3 is a state diagram showing a state in which frost frost on the conventional evaporator.

4 is a front sectional view of a freezer compartment in which the present invention is installed;

5 is a perspective view of a tri tube evaporator applied to the present invention.

6 is a front view and a side view of a drive damper which is rotated at an angle by the driving of the blower fan to change the flow path of cold air;

7 is an operational state diagram of the present invention.

Explanation of symbols on the main parts of the drawings

10. Evaporation structure 20. Evaporator (tri tube) 21, 21a. Heat sink fin (louver fin)

22. First refrigerant pipe 23. Second refrigerant pipe 24. Defrost pipe 25. Heater

26. Louver 27. Connector 30, 30a. Blower fan 40. Driving damper

41. Cold Air Inlet 42. Cold Air Outlet

100.Fridge body 110.Freezer 120.Refrigerator 130.Freezer door

140. Refrigerator door 150. Compressor 160. Evaporator 160a. Defrost

170. Shelf 180. Inner wall 190, 190a. Cold air outlet

200. Blowing fan 210. Cold duct

Figure 4 shows a front sectional view of a freezer compartment in which the present invention is installed, and Figure 5 shows a perspective view of a tri-tube evaporator applied to the present invention.

Refrigerator evaporation structure 10 of the present invention, the inclined in an oblique state and the evaporator 20 is fixed to the rear of the freezer compartment 110;

A blowing fan (30) (30a) installed on the evaporator (20) a plurality;

The evaporator 20 is formed into a cylindrical body to be interpolated, and the heat radiation fins (louver fins) 21 and 21a of the evaporator 20 are driven by the plurality of blower fans 30 and 30a installed. It is composed of a drive damper 40 is rotated at a predetermined angle so that the cold air flow path passing through them.

Hereinafter, the refrigerator evaporation structure of the present invention will be described in detail.

6 is a front view and a side view of a driving damper that is rotated at a predetermined angle by a driving fan to change a flow path of cold air.

Refrigerator evaporation structure 10 of the present invention, the evaporator 20 is not frost frost in the flow path of the cold air passing through the heat radiation fins (louver fins) (21, 21a) of the evaporator 20 fixed to the rear of the freezer compartment. In order to allow the operation setting time of the defrosting operation for removing the frost formed on the evaporator 20 by flowing to another part of the evaporator 20 can be set longer than before, the rear side of the freezer compartment in which the conventional evaporators 160 and 160a are installed. Evaporator 20 formed of an e-tube (Tri-Tube) is installed obliquely in an oblique state, a plurality of blowing fans 30, 30a are respectively installed on the top of the evaporator 20, the blowing fan 30 The evaporator 20 has a structure in which a drive damper 40 is rotated at a predetermined angle so that the flow path of cold air is variable according to the driving of the 30a, and thus the detailed structure of the refrigerator evaporation structure 10 is provided. It will be described in detail.

The evaporator 20 is previously filed by the present applicant and published on March 25, 1999, so that the heat exchange of the evaporation action can be better than the conventional evaporator 160, 160a of the conventional fin tube structure (Korean Patent Publication Publication No. 99-023109) Refrigerator heat exchanger, that is, tri-tube (Tri-Tube) using the evaporator 20 is inclined diagonally fixed to the rear of the freezer compartment, the tri-tube evaporator 20, As shown in Fig. 5, a pair of first and second refrigerant pipes 22 and 23 through which the refrigerant flows; A defrost pipe (24) disposed side by side between the two refrigerant pipes (22) and (23), and having a heater (25) therein that generates heat in the defrost mode; The first and second refrigerant pipes 22 and 23 and the defrost pipe 24 are respectively formed, and the first and second flat plates having a plurality of louvers 26 at regular intervals to improve breathability. The heat dissipation fins 21 and 21a are integrally molded, and thus, a tube consisting of three tubes including two refrigerant tubes 22 and 23 and one defrosting tube 24 is formed into a tri-tube (tri-). tube).

In addition, a connecting pipe at one end of the first and second refrigerant pipes 22 and 23 so that the refrigerant flows through the first and second refrigerant pipes 22 and 23 of the tri-tube evaporator 20. (27) is provided so that the refrigerant decompressed from the expansion valve (not shown) flows through the inlet of the first refrigerant pipe 22 to flow the first refrigerant pipe 22 of a predetermined length. After that, the refrigerant flowing through the first refrigerant pipe 22 is connected to the first refrigerant pipe 22 and the second refrigerant pipe 23 through the connection pipe 27 connecting the second refrigerant pipe 23. It flows to and is discharged to the compressor 150 through the outlet of the second refrigerant pipe (23).

As shown in FIG. 4, the blower fan 30 and 30a may rotate the drive damper 40 by a control unit (not shown) according to driving of the blower fan 30 and 30a. It is connected to the control unit together with the drive damper 40 so that the evaporator so as to blow the cold discharged variable flow path through the drive damper 40 to the freezer compartment 110 and the refrigerating chamber 120 of the refrigerator. (20) It is provided in plurality at the upper end.

As shown in FIGS. 4 and 6, the driving damper 40 is formed in a cylindrical body so that the evaporator 20 can be interpolated, and a plurality of blower fans are provided on the evaporator 20. 30) (30a) has a structure that can be rotated at a predetermined angle so that the flow path of the cold air is variable, in particular, the circumferential surface of the drive damper 40 of the blower fan (30) (30a) The cold air inlet 41 and the cold air outlet 42 are symmetrically diagonally formed so that cold air flows into the evaporator 20 and discharged to the blower 30, 30a by driving.

Hereinafter, the operation of the refrigerator evaporation structure of the present invention will be described in detail.

Figure 7 shows the operational state diagram of the refrigerator evaporation structure of the present invention.

First, when the blower fan 30 of one side installed on the upper end of the evaporator 20 in the rear side of the freezer compartment is driven, as shown in FIG. 7A, by the blowing force (suction input) of the blower fan 30. The cold air inlet 41 of the drive damper 40 in which the evaporator 20 is inserted is formed such that the same flow path as that of the cold air passing through the conventional evaporators 160 and 160a shown in FIGS. 1 and 2 is formed. Cold air is introduced through the air, and the cold air introduced through the cold air inlet 41 of the driving damper 40 as described above, that is, the heat dissipation fin (louver fin) 21 inside the driving damper 40, that is, the evaporator 20. While flowing through the passage 21a, the refrigerant is cooled through heat exchange with the refrigerant in the evaporator 20.

In addition, the cold air cooled to a predetermined temperature by heat exchange with the evaporator 20 as described above is discharged through the cold air outlet 42 of the drive damper 40, as shown in Figure 1 by the blowing fan 30 The temperature of the freezer compartment 110 and the refrigerating compartment 120 is determined by the discharged cold air while being discharged and circulated through the respective cold air outlets 190 and 190a formed on the inner walls of the rear side of the freezer compartment 110 and the refrigerating compartment 120. Is lowered to the set temperature.

Afterwards, each cold air circulated through the freezer compartment 110 and the refrigerating compartment 120 to raise the temperature, as shown in (a) of FIG. 7 through the cold air duct 210 shown in FIG. In the case of cold air provided to the evaporator 20, since the refrigerator doors 130 and 140 are frequently mixed with external air during frequent opening and closing of the refrigerator door 130, the cold air is supplied to the evaporator 20. The surface of the evaporator 20 due to the temperature difference between the evaporator 20 and the low temperature and humid cold when cold and humid cold air flows through the heat radiation fins (louver fins) 21 and 21a of the evaporator 20. Frost is formed on the heat radiation fins (louver fins) 21 and 21a.

Furthermore, when the low-temperature and humid cold air flows through the evaporator 20, when the flow path of the cold air that is heat-exchanged with the evaporator 20 is continuously formed in one direction, the surface of the evaporator 20 and the heat radiation fin (louver) As the frost thickness formed on the fins 21 and 21a becomes thick, the frost formed on the evaporator 20 passes the flow of cold air passing through the evaporator 20 as the frost deposition rate is rapidly progressed. While the membrane acts as a flow resistance, the blowing amount of the cold air discharged into the freezing chamber 110 and the refrigerating chamber 120 by the blower fan 30 is rapidly reduced, at this time, the heat radiation fin (louver fin) of the evaporator 20 ( When the cold air flow passing through the evaporator 20 decreases due to the frost formed on the 21) 21a, the evaporator 20, as shown in FIG. To drive the blowing fan 30a on the other side At this time, when operating the blower fan (30a) of the other side installed on the top of the evaporator 20 as described above, at the same time as the drive of the other blower fan (30a), the drive damper (interpolating the evaporator 20) 40 is rotated at a predetermined angle, that is, the direction perpendicular to the flow path of the cold air formed by driving the blower fan 30 on one side, and the cold air inlet 41 of the drive damper 40 rotated at the predetermined angle as described above. At the same time as the cool air is introduced, the cool air is exchanged with the refrigerant in the evaporator 20 while flowing through the evaporator 20 interpolated in the drive damper 40, and the cooled cold air is cooled by the drive damper 40. It is discharged through the cold air outlet 42 of the to be discharged to the freezing chamber 110 and the refrigerating chamber 120 of the refrigerator by the blowing fan (30a).

Since the operation setting time of the defrosting operation for removing the frost formed on the evaporator 20 can be set longer than before, the refrigerator operation time according to the frequent defrosting operation of the conventional evaporators 160 and 160a. That is, it is possible to increase the time that the refrigeration cycle is performed, thereby improving the cooling performance of the refrigerator.

In the refrigerator evaporation structure 10 of the present invention configured as described above, the blower fan is frosted on the heat radiation fins (louver fins) 21 and 21a of the evaporator 20 like the conventional evaporators 160 and 160a. When the airflow amount of the cold air discharged to the freezing chamber 110 and the refrigerating chamber 120 is rapidly reduced by 30, the drive damper 40 interpolating the evaporator 20 due to the operation of the other blower fan (30a). In accordance with the rotation of the evaporator 20 by varying the flow path of the cold air passing through the heat radiation fins (louver fins) (21, 21a) to flow to other parts of the evaporator 20, the frost is not implanted. Since the operation setting time of the defrosting operation for removing the frost formed on the evaporator 20 can be set long, an excellent cooling time of the refrigerator can be increased, that is, a time during which a refrigeration cycle is performed, thereby improving the cooling performance of the refrigerator. Invention, especially the cold of the present invention And evaporation structure is more efficient as in the refrigerator to be used in regions with high humidity, evaporation refrigerator structure 10 as described above is placed out that it can be applied to not only the refrigerator of the above-described column-type form, a side-by-side type of refrigerator.

Refrigerator evaporation structure of the present invention, by varying the flow path of the cold air passing through the heat radiation fins (louver fins) of the fixed evaporator installed in the rear of the conventional freezer to flow to other parts of the evaporator that is not frost frost than the conventional evaporator Since the operation setting time of the defrosting operation to remove the frost formed on the can be set long, the refrigerator operating time according to the frequent defrosting operation of the conventional evaporator, that is, the time that the refrigeration cycle is performed, thereby increasing the cooling performance of the refrigerator accordingly. There is an excellent effect to improve the.

In addition, the defrosting operation is not operated when the defrosting operation timing of the present invention is frosted in one direction of the evaporator as in the prior art, the bidirectional direction of the evaporator applied to the present invention, that is, the initial flow direction of cold air and the flow path of cold air Since the defrosting operation is started when frost is formed on the evaporator of the variable direction part, the defrosting operation time of the present invention can be set longer than the frequent defrosting operation time of the conventional evaporator, and the consumption used in the refrigerator compared to the conventional one. There is also an excellent effect that can significantly reduce power.

Claims (3)

An evaporator fixed to an oblique state and installed at the rear of the freezer compartment; A blowing fan installed on a plurality of upper ends of the evaporator; The evaporator is formed of a cylindrical body to be interpolated, the drive damper is rotated by a predetermined angle so that the cold air flow path passing through the heat radiation fins (louver fins) of the evaporator in accordance with the driving of the plurality of blower fan is installed Refrigerator evaporation structure, characterized in that consisting of. The refrigerator evaporation structure according to claim 1, wherein a cold air inlet and a cold air outlet are respectively formed on the circumferential surface of the damper so that cold air flows into the evaporator and is discharged to the blower unit by driving the blower fan. The refrigerator evaporation structure of claim 2, wherein the cold air inlet and the cold air outlet are penetrated to be diagonally symmetrical to the circumferential surface of the damper.