KR100484661B1 - Refrigerator increased with inner space - Google Patents

Abstract

The present invention relates to a refrigerator having an increased internal volume, which is connected to a compressor to interpolate a condenser mounted inside a refrigerator machine room into a condenser case having a predetermined space and install it on the rear wall of the refrigerator outer case, thereby providing a conventional condenser. While reducing the space of the machine room as much as the space, there is an excellent effect that can be used as the internal space of the refrigerator to reduce the remaining space of the predetermined size.

In addition, since the condenser case installed on the rear wall of the refrigerator outer case is in direct contact with the outside air, there is an excellent effect of the heat sink that the refrigerant heat radiated from the condenser is discharged to the outside of the refrigerator via the condenser case.

Description

Refrigerator increased with inner space

The present invention relates to a refrigerator. More specifically, the condenser mounted in the refrigerator machine room connected to the compressor is inserted into a condenser case having a predetermined space and installed on the rear wall of the refrigerator outer case. As the internal space (volume) of the refrigerator can be utilized, in particular, the internal volume of the condenser in which the condenser is inserted into contact with the outside air can also serve as a heat sink to release the heat of the refrigerant radiated from the condenser to the outside of the refrigerator. It is about an old refrigerator.

In general, the refrigerator lowers the temperature in the refrigerator through the cold air generated by the refrigeration cycle consisting of the compressor 50, the condenser 60, the expansion valve (not shown), and the evaporator (not shown) to freeze food or the like. It is intended for refrigeration, and in particular, in the machine room 70 located at the lower rear side of the refrigerator, as shown in FIG. 1, the refrigerant evaporated from the evaporator to a low temperature low pressure gas phase is pressurized to a high temperature high pressure gas phase A condenser 60 is connected to the compressor 50 and the compressor 50 to condense the refrigerant pressurized from the compressor 50 into a liquid phase at room temperature and high pressure. The compressor 50 and the condenser 60 are provided. Machine room cover 80 is installed outside the machine room 70 to protect the refrigerator machine room 70 is installed. Reference numeral 61 is a blower fan 61 for cooling the compressor 50 and the condenser 60.

However, in the case of the machine room 70, since the compressor 50 and the condenser 60 are installed in the machine room 70, as shown in FIG. 1, the space of the machine room 70 itself is the refrigerator. As the lower part occupies almost all of the spaces, there is a problem in that the internal space (volume) of the refrigerator cannot be utilized as much as the space of the machine room 70.

In addition, in the case of the machine room cover 80 for protecting the compressor 50 and the condenser 60, as shown in FIG. 2, the compressor 50 and the condenser 60 and the outside air of the machine room 70 Since it is fixed to the outside of the machine room 70 so as not to be in direct contact with each other, the compressor motor (not shown) when pressurizing the heat of the inside of the machine room 70, that is, the refrigerant at low temperature and low pressure, to a high temperature and high pressure state. Compressor waste heat and heat of refrigerant radiated around the condenser 60 are generated more quickly through the vent hole 90 of the cover 80 by the load of the compressor 50. (70) There is a big problem that the temperature inside the machine room 70 rises because it cannot be discharged to the outside, and further, the machine room cover 80 itself heat dissipated around the condenser 60 is the machine room 70. In contact with outside air Since the heat sink does not act as a heat sink to be discharged to the outside of the machine room 70 by the tropical current phenomenon, the heat of the refrigerant radiated around the condenser 60 is not released to the outside of the machine room 70 smoothly. There was also a big problem that would be another factor in the synergism of the internal temperature of the machine room 70, which is the aforementioned problem.

The present invention has been made in order to solve the above problems, by inserting the condenser connected to the compressor inside the refrigerator machine room in the condenser case having a predetermined space and install it on the rear wall of the refrigerator outer case, the conventional condenser occupies The purpose of the present invention is to reduce the space of the machine room as much as the previously used space, and at the same time, to make the remaining space of the predetermined size as the internal space (volume) of the refrigerator.

In addition, since the condenser case installed on the rear wall of the refrigerator outer case is in direct contact with the outside air, the refrigerant heat radiated from the condenser may also serve as a heat sink to be discharged to the outside of the refrigerator through the condenser case. There is a purpose. In addition, by forming a blow induction duct connected to the case so that the heat radiated from the condenser can be sucked by the blower fan inside the machine room, the heat radiated from the condenser by the suction force of the blower fan through the blower induction duct Another object is to allow the internal compressor to cool and then be discharged out of the machine room.

The object of the present invention is solved by the refrigerator having an increased internal volume of the present invention, which is connected to a compressor and interpolates a condenser mounted inside a refrigerator machine room into a condenser case having a predetermined space and installs it on the rear wall of the refrigerator outer case. It may be described in detail with reference to the accompanying drawings.

FIG. 3 is a perspective view illustrating a condenser and a condenser case, which are components of the present invention, installed on a rear wall of a refrigerator outer case, and FIG. 4 is a disassembled condenser case and a refrigerator machine room in which a condenser is inserted among refrigerator components of the present invention. A perspective view showing a state.

The refrigerator of the present invention lowers the temperature in the refrigerator by a refrigeration cycle in which the refrigerant pressurized to high temperature and high pressure in the compressor 50 installed in the machine room 70 circulates through a condenser, an expansion valve (not shown), and an evaporator (not shown). In a refrigerator to make;

In order to utilize the space of the machine room 70 occupied by the condenser as an internal space (volume) of the refrigerator, the condenser 20 is inserted into the condenser case 10 in a predetermined space, thereby allowing the condenser case 10 to be used. It is a configuration installed on the rear wall 40 of the refrigerator outer case. Reference numeral 30 denotes an internal volume increasing unit 30, and 80 denotes a machine room cover 80.

Hereinafter, a refrigerator having an increased internal volume of the present invention will be described in detail.

Figure 5 shows a perspective view of a condenser which is a component of the present invention, Figure 6 shows a perspective view of a condenser case which is a component of the present invention.

The refrigerator of the present invention interpolates the condenser 20 to the condenser case 10 in a predetermined space so that the condenser case 10 is installed on the rear wall 40 of the refrigerator outer case separate from the machine room 70. 1 may be utilized as an internal space (volume) 30 of the refrigerator as much as the space occupied by the conventional condenser 60 of FIG. 1, and in particular, the condenser 20 is inserted into the condenser case 10 in contact with external air. As the heat sink for discharging the heat of the refrigerant radiated at 20 to the outside of the refrigerator, the configuration thereof will be described in detail.

As shown in FIGS. 4 and 5, the condenser 20 is formed in an in-line plate shape so as to be interpolated in the condenser case 10 in the predetermined space, and the inlet 21 of the condenser 20 is formed. ) Is connected to the compressor outlet 51 installed inside the machine room 70, the outlet 22 of the condenser is connected to the hotline inlet 25 installed on the front of the refrigerator to prevent dew condensation. .

As shown in FIGS. 4 and 5, the condenser case 10 includes a case member 11 having one side open while having a predetermined space for the condenser 20 to be interpolated;

A plurality of vent holes 12 passing through the case member 11 to radiate heat radiated around the condenser 20 to the outside of the case member 11;

The heat of refrigerant circulated around the condenser 20 may be circulated toward the blower fan 61 while being integrally formed at the bottom of the case member 11 to protect the blower fan 61 installed in the machine room 70 of the refrigerator. It is composed of a blowing induction duct 13, which is installed in a form in which one side is opened in a position corresponding to the blowing fan 61, in particular between the lower end of the case member 11 and the blowing induction duct (13) A connection passage 14 is formed to allow the heat of the refrigerant radiated around the condenser 20 to flow into the blowing air inductor 13.

In addition, the condenser case 10 is installed on the rear wall 40 of the refrigerator outer case in a state where the condenser 20 is interpolated, wherein one side of the condenser case 10 is opened. The member 11 is, as described above, the one side of the open side is faced to the rear wall 40 of the refrigerator outer case is fixed by the screw 15, integrally formed at the bottom of the case member 11 The blower induction duct 13 circulates and flows refrigerant heat radiated around the condenser 20 by the suction force of the blower fan 61 installed in the machine room 70 to the blower fan 61 in the machine room 70. One side of the opening is secured by screws 15 so as to correspond to the opening hole 71 formed at the position of the blower fan 61 inside the machine room 70.

Furthermore, in the case of the condenser case 10, the heat of the refrigerant radiated around the condenser 20 is discharged to the outside of the case member 11 through a plurality of vent holes 12 penetrated through the case member 11. At the same time, the condenser case 10 having the condenser 20 interpolated is installed on the rear wall 40 of the refrigerator outer case so that the condenser case 10 is in direct contact with the outside air. The refrigerant heat radiated around the condenser 20 due to the heat flow between the refrigerant heat and the outside air is also discharged to the outside of the refrigerator through the condenser case 10.

7 is a view showing another configuration of the condenser and the condenser case of the components of the present invention, which is due to the heat of the refrigerant heat radiated around the condenser 20a and the air flow due to the tropical flow phenomenon of the condenser case The condenser 20a is integrally formed on one surface of the condenser case 10a in contact with the external air so as to be rapidly discharged to the outside of the refrigerator via the 10a.

8 is an embodiment showing another configuration of the condenser and the condenser case of the components of the present invention, which is formed integrally with each other, in order to increase the heat exchange amount between the refrigerant heat radiated around the condenser 20b and the outside air The heat transfer area of the condenser case 10b and the condenser 20b is increased to increase the contact heat transfer area of the refrigerant heat radiated around the condenser 20b and external air.

Hereinafter, the operation of the refrigerator having an increased internal volume of the present invention will be described in detail.

9 is a state diagram showing an operating state of the present invention.

First, the coupling process between the condenser interpolated in the condenser case among the components of the present invention and the compressor installed in the machine room, and the process of fixing the condenser case to the refrigerator outer case are as follows.

The condenser 20 having a planar state formed in an in-line shape is inserted into the condenser case 10 and fixed by welding or screws such that the condenser 20 does not flow in the condenser case 10, and then the inlet of the condenser ( 21 is connected to the compressor outlet 51 installed inside the machine room 70, and the outlet 22 of the condenser is connected to the hotline inlet 25 installed on the front of the refrigerator to prevent dew condensation. The one side of the condenser case 10 into which the condenser 20 is inserted is attached to the rear wall 40 of the outer case of the refrigerator and fixed using the screw 15.

In addition, the blower induction duct 13 integrally formed at the lower end of the condenser case 10 is also opened at the blower fan 61 so as to correspond to the opening hole 71 at the blower fan 61 in the machine room 70. One side surface is fixed by using a screw 15, the process of coupling the condenser 20 and the compressor 50 interpolated in the condenser case 10 and the condenser case 10 the back of the refrigerator outer case In the refrigerator according to the present invention, all of the processes fixed to the wall 40 are terminated. As shown in FIG. 3, the space occupied by the conventional condenser 60 illustrated in FIG. It can utilize as (volume) 30.

The refrigerant cycle of the refrigerator in which the condenser case 10 is fixed to the rear wall 40 of the refrigerator outer case as described above is as follows.

The refrigerant introduced into the compressor 50 through an evaporator (not shown) and pressurized from the low-temperature low-pressure gas phase to the high-temperature high-pressure gas phase is installed on the rear wall 40 of the refrigerator outer case as shown in FIG. 9. The condenser case 10, that is, the flow to the condenser 20 interpolated in the condenser case 10, the refrigerant introduced into the condenser 20 as described above is a room temperature and high pressure through the heat radiation action in the condenser 20 Phase change to a liquid state, wherein the heat of the refrigerant radiated around the condenser 20 is a portion of the heat of the refrigerant through the vent hole 12 through the condenser case 10 a plurality of the heat to the outside of the condenser case 10 The remaining heat of the refrigerant passes through the opening hole 71 at the position of the blower fan 61 and the blower duct 13 installed correspondingly by the suction force of the blower fan 61 installed in the machine room 70. 70) Flowing into the blowing fan 61 installed inside Along with the blowing force according to the driving of the blower fan 61, the compressor is cooled and then discharged to the outside of the machine room 70, that is, to the outside of the refrigerator through a plurality of vent holes 90 formed in the machine room cover 80. It is provided with a heat radiation passage.

In addition, in the case of the condenser case 10, since the condenser case 10 in which the condenser 20 is interposed so as to be in direct contact with the external air is installed on the rear wall 40 of the refrigerator outer case, the condenser The refrigerant heat radiated around the condenser 20 due to the heat flow between the refrigerant heat in the case 10 and the outside air also serves as a heat sink to be discharged to the outside of the refrigerator through the condenser case 10.

As such, the refrigerant having completed the condensation through the condenser 20 flows into the hotline inlet 25 connected to the outlet 22 of the condenser 20, and is installed on the front of the refrigerator to prevent dew condensation. After the entire flow (not shown), the flow through the inlet of the expansion valve (not shown) connected to the outlet of the hotline into the expansion valve.

In addition, the refrigerant introduced into the expansion valve is decompressed to be easily evaporated by heat exchange in the evaporator, and then flows to the evaporator in which the evaporation process of the refrigerant is performed. As the endothermic action is endothermic to evaporate and phase change to a low-temperature low-pressure gas phase state to form a refrigerating cycle to be introduced into the compressor 50 again, by repeating the refrigerating cycle process of the refrigerant as described above to discharge the cold air into the refrigerator In this case, the internal temperature of the refrigerator is lowered.

In the refrigerator having an increased internal volume of the present invention, the condenser mounted in the refrigerator machine room connected to the compressor is inserted into a condenser case having a predetermined space and installed on the rear wall of the outer case of the refrigerator. At the same time as reducing the space of the machine room, there is an excellent effect that can be used as the internal space (volume) of the reduced constant size of the space remaining.

In addition, since the condenser case installed on the rear wall of the refrigerator outer case is in direct contact with the outside air, there is an excellent effect of the heat sink that the refrigerant heat radiated from the condenser is discharged to the outside of the refrigerator via the condenser case.

1 is a partial perspective view showing a machine room structure of a conventional refrigerator.

2 is a partial side cross-sectional view of a refrigerator having a conventional machine room cover fixed thereto.

3 is a perspective view showing a condenser and a condenser case which are components of the present invention installed on a rear wall of a refrigerator outer case.

Figure 4 is a perspective view showing an exploded state of the condenser case and the refrigerator machine room in which the condenser interpolated among the refrigerator components of the present invention.

5 is a perspective view of a condenser that is a component of the present invention.

6 is a perspective view of a condenser case that is a component of the present invention.

Figure 7 is an embodiment showing another configuration of the condenser and the condenser case of the components of the present invention.

8 is an embodiment showing another configuration of the condenser and the condenser case of the components of the present invention.

9 is a state diagram showing an operating state of the present invention.

Explanation of symbols on the main parts of the drawings

10, 10a, 10b. Condenser Case 11.Case Member 12.Aeration Vent

13. Blowing air duct 14. Connecting passage 15. Fixing screw

20, 20a, 20b. Inline condenser 21. Condenser inlet 22. Condenser outlet

25. Hotline inlet 30. Inner volume increase 40. Refrigerator outer case back wall

50. Compressor 51. Compressor outlet 61. Blower fan 70. Machine room

71. Opening hole 80. Machine room cover 90. Machine room cover vent

Claims (7)

delete delete In the refrigerator, A case member having a predetermined space such that the condenser is interpolated to the rear side of the refrigerator and installed on the rear wall of the rear side of the refrigerator; The other side is formed in contact with the case member, one side is opened in a position corresponding to the blowing fan of the machine room formed at the bottom of the rear of the machine room, the heat of refrigerant radiated around the condenser is circulated toward the blowing fan of the machine room formed at the bottom of the rear wall of the refrigerator A refrigerator with an increased internal volume, characterized by comprising a blowing induction duct to guide . The method of claim 3, wherein The case member may include a plurality of ventilation holes formed to discharge the heat of the refrigerant radiated around the condenser to the outside of the case member, and the other side of the air blowing duct so that the heat of the refrigerant radiated around the condenser is introduced into the air blowing duct. Refrigerator with increased internal volume, characterized in that the connecting passage is formed at the bottom of the case member corresponding to the . The method of claim 3, wherein Refrigerant heat radiated around the case member and the condenser by the suction force of the blower fan installed in the machine room is sucked along the blowing induction duct, and includes a heat dissipation flow path discharged outside the machine room after cooling the compressor in the machine room . A refrigerator having an increased internal volume. In the refrigerator, A plurality of heat dissipation holes and an open connection path formed at a lower end of the case surface forming a predetermined space, and a case member in which the condenser is integrally formed in the case to increase the heat transfer area and the heat exchange amount of the condenser of a predetermined shape; ; One side is opened at a position corresponding to the blower fan of the machine room formed at the bottom of the rear wall of the refrigerator, and the other side is connected to the open connection passage of the case member, and the heat of refrigerant radiated around the condenser is directed to the blower fan of the machine room. A refrigerator having an increased internal volume , comprising a blower duct for circulating to be circulated . The method of claim 6, Refrigerant heat radiated around the case member and the condenser by the suction force of the blower fan installed in the machine room is sucked along the blowing induction duct, and includes a heat dissipation flow path discharged outside the machine room after cooling the compressor in the machine room . A refrigerator having an increased internal volume.