KR20230010385A - refrigerator - Google Patents

Abstract

In the refrigerator of the present invention, even if the temperature of the hot gas flow path through which the hot gas flows gradually decreases due to heat exchange while passing through the evaporator, heat from a heating source is provided to the hot gas flow path through a heat transfer member to reheat the hot gas. This is so that sufficient heat can be provided until it completely passes through the evaporator.

Description

refrigerator {refrigerator}

The present invention relates to a refrigerator having a heating heat source and a hot gas flow path.

In general, a refrigerator is a home appliance provided to store various foods for a long time with cool air generated by using circulation of a refrigerant according to a refrigerating cycle.

In such a refrigerator, one or a plurality of storage compartments for storing storage objects (eg, food or beverages, etc.) are partitioned from each other and provided. The storage chamber receives cold air generated by a refrigeration system including a compressor, a condenser, an expander, and an evaporator, and is maintained within a set temperature range.

Meanwhile, while the refrigerator is operating, cold air circulating inside each storage compartment passes through an evaporator, and in the process, moisture contained in the cold air is deposited on the surface of the evaporator to form frost.

Accordingly, the defrosting operation to remove the frost is performed periodically or when an operating condition is satisfied, and such a defrosting operation is usually performed using a heating heat source made of an electric heater.

At this time, as the heating heat source, a sheath heater using radiant heat may be provided, or a cord heater in contact with the outer surface of the heat exchange pin may be provided.

In particular, the sheath heater and the cord heater are provided together to improve defrost efficiency and shorten defrost operation time, and in this regard, Patent Publication No. 10-2001-0047410 (Prior Document 1), Patent Publication No. 10- It is as described in No. 2018-0011691 (Prior Document 2).

However, the defrosting method using only a heating source using electricity, such as the prior art 1 and the prior art 2 described above, takes a considerable amount of time to lower each storage compartment to a set temperature after the defrosting operation is finished, and power consumption is severe. There are downsides.

In addition, conventionally, hot gas defrosting using a hot refrigerant (hot gas) passing through a compressor is additionally provided, and through this, a defrosting time is shortened and an increase in the internal temperature of the refrigerator is minimized during the defrosting operation. In this regard, disclosed in Patent Publication No. 10-2010-0034442 (Prior Document 3), Patent Publication No. 10-2017-0013766 (Prior Document 4), and Patent Publication No. 10-2017-0013767 (Prior Document 5). same as bar

However, in the technology of Prior Document 3 described above, since the hot gas defrosting and the heater defrosting are selectively performed according to the room temperature, there is still a problem in the defrosting operation using only the heating heat source.

In addition, since the technologies of Prior Documents 4 and 5 described above are defrosting the evaporator using only hot gas, the power consumption is reduced, but the defrosting time is not significantly shortened compared to the method using a heating source.

In particular, in the hot gas defrosting method described above, since the temperature is lowered due to heat exchange with the evaporator while passing through the evaporator, it is impossible to heat the entire area of the evaporator evenly.

Accordingly, a defrost defect in which frost remains after the defrost operation may be caused, and the defrost time cannot be greatly shortened.

Patent Publication No. 10-2001-0047410 Patent Publication No. 10-2018-0011691 Patent Publication No. 10-2010-0034442 Patent Publication No. 10-2017-0013766 Patent Publication No. 10-2017-0013767

The present invention has been made to solve various problems according to the prior art, and an object of the present invention is to defrost operation by simultaneously applying a heat conduction method using a hot gas and a radiant heat method using a heating heat source for defrosting an evaporator. that shortened the time.

In addition, another object of the present invention is to improve power efficiency by enabling a flow path through which hot gas flows to receive heat generated from a heating heat source.

In addition, an object of the present invention is to ensure that all parts of the evaporator can be evenly defrosted by allowing the hot gas to be reheated by the heating heat source even if the temperature of the hot gas decreases during defrosting of the evaporator by the hot gas.

According to the refrigerator of the present invention for achieving the above object, a hot gas flow path and a heating heat source may be provided together to selectively supply heat to a region requiring heat.

In addition, according to the refrigerator of the present invention, the hot gas flow path may receive heat from the heating source by the heat transfer member. Accordingly, even if the temperature of the hot gas flow path is lowered while passing through the evaporator during the defrosting operation, the defrosting effect may be further improved by reheating.

In addition, according to the refrigerator of the present invention, the hot gas flow path may be provided separately from the refrigerant flow path passing through the expander and evaporator from the condenser.

Further, according to the refrigerator of the present invention, the hot gas flow path may be formed to guide the flow of the refrigerant recovered from the condenser to the compressor through the evaporator without passing through the expander.

Also, according to the refrigerator of the present invention, the heat transfer member may be in contact with the heating heat source.

Also, according to the refrigerator of the present invention, the heat transfer member may be in contact with the hot gas flow path.

In addition, according to the refrigerator of the present invention, the heating heat source may be configured as a sheath heater.

Also, according to the refrigerator of the present invention, the heat transfer member may be formed of a metal plate.

In addition, according to the refrigerator of the present invention, one end of the heat transfer member may be formed to be in surface contact while surrounding at least a portion of the heating heat source.

Also, according to the refrigerator of the present invention, the other end of the heat transfer member may be formed to be in surface contact while surrounding at least a portion of the hot gas flow path.

Further, according to the refrigerator of the present invention, the heat transfer member may be formed to be rounded or bent as it goes from a contact portion with the heating heat source to a contact portion with the hot gas flow path.

Also, according to the refrigerator of the present invention, a plurality of heat transfer members may be provided.

Further, according to the refrigerator of the present invention, the hot gas flow path may be connected to the hot gas inlet side of the evaporator furthest from the heating heat source.

In addition, according to the refrigerator of the present invention, the hot gas flow path may be connected to the hot gas outlet side of the evaporator furthest from the heating heat source.

In addition, according to the refrigerator of the present invention, the hot gas inlet side and the hot gas outlet side of the hot gas flow path may be located on opposite sides of the evaporator where the heating heat source is located.

In addition, according to the refrigerator of the present invention, at least a portion of the hot gas flow path may be connected to pass through a region adjacent to the heating heat source.

In addition, according to the refrigerator of the present invention, the hot gas flow path may be formed to sequentially penetrate from the uppermost heat exchange fins constituting the evaporator to the lowermost heat exchange fins.

In addition, according to the refrigerator of the present invention, the hot gas flow path may include an inlet flow-side flow path for guiding hot gas to flow through a part of the evaporator.

Further, according to the refrigerator of the present invention, the hot gas flow path may include an outflow flow-side flow path for guiding an outflow flow of the hot gas flowing through another part of the evaporator.

In addition, according to the refrigerator of the present invention, the hot gas flow path may include a flow-side flow path connected to the inflow-side flow path and the outflow-side flow path.

In addition, according to the refrigerator of the present invention, the flow-side flow path connected to the hot gas flow path may be formed to sequentially pass through the heat exchange fins of the lowermost row.

In addition, according to the refrigerator of the present invention, the heating heat source may be located at the bottom of the flow-side passage constituting the hot gas passage.

In addition, according to the refrigerator of the present invention, the heat transfer member may be formed to connect the flow-side flow path constituting the hot gas flow path and the heating heat source.

The refrigerator of the present invention configured as above provides each of the following effects.

The refrigerator of the present invention can provide heat from a heating heat source and heat from a hot gas flow path through which a high-temperature refrigerant (hot gas) flows. In this way, sufficient heat can be supplied to the place where heat is needed.

In addition, since the refrigerator of the present invention performs the defrosting operation while using both the heating heat source and the hot gas, the time required for the defrosting operation is shortened.

In addition, since the refrigerator of the present invention performs the defrosting operation while using both the heating heat source and the hot gas, power consumption for the defrosting operation is reduced.

In addition, since the refrigerator of the present invention reheats the hot gas flow path with heat generated by the heat generated by the heating heat source using the heat transfer member, heat for defrosting can be sufficiently provided until the hot gas completely passes through the evaporator.

In addition, in the refrigerator of the present invention, since the heat transfer member is formed to be bendable, the heat transfer member can be stably coupled even if the distance between the hot gas flow path and the heating source is different from the designed distance.

In addition, in the refrigerator of the present invention, since the heat transfer member is formed to be in surface contact with the heating heat source, it can receive sufficient heat from the heating heat source.

In addition, the refrigerator of the present invention can conduct sufficient heat to the hot gas flow path because the heat transfer member is formed to be in surface contact with the hot gas flow path.

In addition, in the refrigerator of the present invention, since the heat transfer member is connected to the flow-side flow path of the hot gas flow path, the refrigerant whose temperature has decreased while passing through the evaporator can be reheated.

1 is a state diagram showing the front appearance of a refrigerator according to an embodiment of the present invention;
Figure 2 is a state diagram showing the appearance of the rear side of the refrigerator according to an embodiment of the present invention
3 is a state diagram showing the internal structure of a refrigerator according to an embodiment of the present invention;
4 is a state diagram showing a refrigeration system including a hot gas flow path of a refrigerator according to an embodiment of the present invention.
5 is a perspective view illustrating a state in which a hot gas flow path and a heating source are installed in an evaporator of a refrigerator according to an embodiment of the present invention;
6 is an enlarged view illustrating a state in which a hot gas flow path and a heating heat source are connected to an evaporator of a refrigerator according to an embodiment of the present invention by a heat transfer member.
7 and 8 are perspective views of main parts of a state in which a hot gas flow path and a heating heat source are connected to an evaporator of a refrigerator by a heat transfer member according to an embodiment of the present invention, viewed from different directions;
9 and 10 are state views of the heat transfer member of the refrigerator according to an embodiment of the present invention viewed from different directions;
11 is a front view of a state in which a hot gas flow path and a heating heat source are connected to an evaporator of a refrigerator according to an embodiment of the present invention by a heat transfer member.
12 is a state diagram illustrating a refrigerant flow during a cooling operation for a storage compartment of a refrigerator according to an embodiment of the present invention.
13 is a state diagram illustrating a flow of refrigerant when a heat supply operation is performed to an evaporator of a refrigerator according to an embodiment of the present invention.
14 is a state diagram showing a refrigeration system including a hot gas flow path of a refrigerator according to another embodiment of the present invention.

Hereinafter, a preferred embodiment of the refrigerator of the present invention will be described with reference to FIGS. 1 to 14 attached.

Prior to the description of the embodiment, each direction mentioned in the description of the installation position of each component takes an installation state in actual use (the same state as in the illustrated embodiment) as an example.

1 is a state diagram showing a front appearance of a refrigerator according to an embodiment of the present invention, FIG. 2 is a state diagram showing a rear appearance of a refrigerator according to an embodiment of the present invention, and FIG. 3 is an embodiment of the present invention. It is a state diagram showing the internal structure of the refrigerator according to

As shown in these drawings, the refrigerator according to the embodiment of the present invention is provided with a heating heat source 310 and hot gas so that heat can be selectively supplied to a region requiring heat.

In particular, in the refrigerator according to an embodiment of the present invention, the hot gas flow path 320 through which the high-temperature refrigerant (hot gas) flows can be heated by the heating heat source 310 . In this way, sufficient heat can be provided until the high-temperature refrigerant flowing along the hot gas flow path 320 completely passes through the evaporator 240 .

The refrigerator according to the embodiment of the present invention will be described in more detail for each configuration as follows.

First, a refrigerator according to an embodiment of the present invention may include a refrigerator body 100 providing a storage compartment 101 .

The storage compartment 101 can be opened and closed by a door 110 as a storage space for storing items. At this time, the door 110 may be a rotary door or a drawer-type door.

At the same time, the storage compartment 101 is operated to maintain the set reference temperature NT.

The set reference temperature NT may be set by a user, and when the user does not set the set reference temperature NT, an arbitrarily designated temperature is used as the set reference temperature NT.

Meanwhile, two or more of the storage compartments 101 may be provided, and if a plurality of storage compartments 101 are provided, each of the storage compartments 101 may have different set reference temperatures NT.

For example, one storage compartment may serve as a freezing compartment and the other storage compartment may serve as a refrigerating compartment.

Next, a refrigerator according to an embodiment of the present invention may be configured to include a refrigeration system as shown in FIG. 4 attached.

That is, cold air capable of maintaining the storage compartment 101 at the set reference temperature NT is supplied by the refrigeration system.

The refrigeration system may include a compressor 210. The compressor 210 is a device that compresses the refrigerant and may be located in the machine room 103 in the refrigerator body 100 .

In addition, the refrigeration system may include a condenser 220. The condenser 220 is a device for condensing the refrigerant compressed by the compressor 210, and may be located in the machine room 103 in the refrigerator body 100.

In addition, the refrigeration system may include an expander 230. The expander 230 is a conduit for depressurizing and expanding the refrigerant condensed in the condenser 220 .

In addition, the refrigeration system may include an evaporator 240 .

The evaporator 240 is a device that evaporates the refrigerant depressurized by the expander 230 to exchange heat with air (cold air) flowing in the storage chamber 101 .

The evaporator 240 is located in the storage chamber 101 and heat-exchanges cold air flowing by the driving of the blowing fan 281 .

In particular, the evaporator 240 is configured to include a heat exchange pin 241 and a refrigerant pipe 242 through which a refrigerant flow is guided while penetrating the heat exchange pin 241 .

Here, the heat exchange fins 241 may be composed of a plurality of rows spaced vertically. For example, the heat exchange fins 241 may be arranged in 6 rows. That is, the uppermost first row heat exchange fins 241 and the lowermost sixth row heat exchange fins 241 may be sequentially arranged for each column.

In addition, the refrigerant pipe 242 may be formed to flow out after sequentially passing through the heat exchange fins 241 of each row.

For example, the refrigerant pipe 242 sequentially passes in a zigzag structure from the heat exchange fins 241 of one outer row (the uppermost row) to the heat exchange fins 241 of the other outer row (the lowermost row). can be formed to In addition, after passing through the heat exchange fins 241 of the other outer row, they may be reversely bent and pass sequentially in a zigzag structure up to the heat exchange fins 241 of the one outer row.

That is, the refrigerant is heat-exchanged sequentially from the heat exchange fins 241 of the uppermost row to the heat exchange fins 241 of the lowermost row, and then heat-exchanged again to the heat exchange fins 241 of the uppermost row, then may be discharged.

In addition, the refrigeration system may include a refrigerant passage 260.

The refrigerant passage 260 is formed to guide the flow of the refrigerant recovered from the condenser 220 through the expander 230 and the evaporator 240 to the compressor 210 . That is, the refrigerant passage 260 may be a refrigerant flow path for the freezing operation of the storage chamber 101 .

The refrigerant passage 260 may be formed to be connected to the refrigerant pipe 242 of the evaporator 240 . Of course, although not shown, a part of the refrigerant passage 260 may be formed as a refrigerant pipe 241 of the evaporator 240 .

Next, a heating source 310 may be included in the refrigerator according to the embodiment of the present invention.

The heating heat source 310 is a heat source that provides high-temperature heat.

The heating heat source 310 can be used for various purposes. For example, it may be used to provide heat to defrost the evaporator 240. That is, it may be configured as a defrost heater that generates heat to defrost frost generated on the surface of the evaporator 240 (the surface of each heat exchange pin and the surface of the refrigerant pipe).

The heating source 310 may be located adjacent to either side of the evaporator 240 .

Specifically, the heating heat source 310 may be spaced apart from the bottom of the heat exchange fin 241 of the lowermost column constituting the evaporator 240 . That is, considering that the heat generated by heat generated by the heating source 310 flows upward, it is preferable to place the heating source 310 below the evaporator 240 .

The heating heat source 310 and the evaporator 240 may be configured as a single body. That is, at least one side of the heating heat source 310 may be installed on at least one side plate 243 of the two side plates 243 on both sides for supporting the refrigerant pipe 241 . Of course, the heating heat source 310 may be configured separately from the evaporator 240 .

In addition, the heating heat source 310 may be configured as a sheath heater generating heat by power supply. As a result, frost (or freezing) of the evaporator 240 can be removed by the radiant heat of the heating heat source 310 .

Next, the hot gas flow path 320 may be included in the refrigerator according to the embodiment of the present invention.

The hot gas flow path 320 may serve as a heat source for supplying high-temperature heat together with the heating heat source 310 .

The hot gas passage 320 may be formed to guide the high-temperature refrigerant (hot gas) passing through the condenser 220 . That is, the high-temperature refrigerant (hot gas) guided by the hot gas passage 320 provides high-temperature heat.

The hot gas passage 320 is formed to guide the refrigerant flow separately from the refrigerant passage 260 . That is, the hot gas flow path 230 is formed so that the refrigerant passing through the condenser 220 is directly supplied to the evaporator 240 without passing through the expander 230 and then passed through the evaporator 240 and returned to the compressor 210. It can be.

The hot gas passage 320 may be branched from the refrigerant passage 260 . In addition, a flow path switching valve 330 for switching the refrigerant flow may be provided at a branch portion of the hot gas flow path 320 . That is, the refrigerant passing through the condenser 220 by the operation of the flow path switching valve 330 is provided to the evaporator 240 via the expander 230 through the refrigerant flow path 260, or the hot gas flow path 320 It may be provided to the evaporator 240 without passing through the expander 230 through.

The flow path conversion valve 320 may be provided alone as in the illustrated embodiment, or may be provided in a plurality of two or more although not shown.

When only one flow path conversion valve 320 is provided, it may be formed as a multi-way valve, such as a 4-way valve.

When two or more flow path conversion valves 320 are provided in plurality, they may be formed as, for example, a 3-way valve or a check valve.

In addition, a portion passing through the evaporator 240 of the hot gas flow path 320 may be formed in a zigzag structure from one side of the evaporator 240 to another side via the other side. . As a result, the hot gas (high-temperature refrigerant) flowing along the hot gas flow path 320 may affect all parts of the evaporator 240 .

A portion of the hot gas passage 320 passing through the evaporator 240 may include an inlet flow-side passage 321 , a connection flow-side passage 322 , and an outflow flow-side passage 323 .

Here, the inlet flow-side passage 321 is formed to guide the flow of the refrigerant (hot gas) flowing into the evaporator 240 to the connection flow-side passage 322, and the outflow flow-side passage 323 It is formed to guide the outflow of the refrigerant passing through the connection flow-side passage 322. In addition, the connection flow-side passage 322 is formed to be heated by receiving heat from the heating heat source 310 while connecting the inlet flow-side passage 321 and the outflow flow-side passage 323 .

The connection flow-side passage 322 may be connected to pass through an area adjacent to the heating heat source 310 . That is, the refrigerant (hot gas) whose temperature is lowered by defrosting the evaporator 240 while passing through the inlet flow-side passage 321 is reheated from the heating heat source 310 while passing through the connection flow-side passage 322 and then flows out. It is made to pass through the flow-side passage 323.

In addition, considering that the heating heat source 310 is located at the bottom of the evaporator 240, the flow-side passage 322 connects the heat exchange fins 241 of the lowermost row (sixth row) of the evaporator 240. It is preferable to be formed so as to penetrate sequentially.

In particular, the refrigerant inlet of the inlet flow-side passage 321 may be located on the opposite side of the evaporator 240 to the portion where the heating source 310 is located. That is, the refrigerant having the hottest temperature is introduced into a portion of the evaporator 240 that is least affected by the heating heat source 310 .

To this end, the inlet flow-side passage 321 may be formed to sequentially pass through from the heat exchange fins 241 of the uppermost row (column 1) to the heat exchange fins 241 of the lowermost row (column 6). there is.

In addition, the outflow flow-side passage 323 may be formed to sequentially penetrate from the heat exchange fins 241 in the lowermost row (row 6) to the heat exchange fins 241 in the uppermost row (column 1). . That is, while the refrigerant reheated in the connection flow-side passage 322 flows along the connection flow-side passage 322, the heat exchange fins 241 of each row can be heated (defrosted) again.

In particular, each of the flow-side passages 321, 322, and 323 of the aforementioned hot gas passage 320 may be coupled to pass through the heat exchange pins 241 and then come into contact with each of the heat exchange pins 241 through a pipe expansion operation. That is, the hot gas passage 320 can defrost the heat exchange fins 241 through heat conduction.

In addition, the refrigerant inlet of the inlet flow-side passage 321 and the refrigerant outlet of the outflow flow-side passage 323 are installed to pass through the heat exchange fin 241 located at the end of the uppermost row (column 1). That is, hot gas is introduced from the heat exchange fin 241 located at the end of one row, and the hot gas is discharged through the corresponding heat exchange fin 241 last.

Next, the refrigerator according to the embodiment of the present invention may be configured to include the heat transfer member 340 .

The heat transfer member 340 is formed to conduct heat from the heating heat source 310 to the hot gas flow path 320 .

One end of the heat transfer member 340 may be formed to contact the heating heat source 310 . That is, a first contact end 341 contacting the heating heat source 310 is formed at one end of the heat transfer member 340 . Thus, the heat transfer member 340 can provide heat to the hot gas flow path 320 through heat conduction according to contact with the heating heat source 310 .

In particular, the first contact end 341 of the heat transfer member 340 may be formed to be in surface contact while surrounding at least a portion of the heating heat source 310 . For example, the first contact end 341 of the heat transfer member 340 may have a round structure having the same inner diameter as the outer diameter of the heating heat source 310 . As a result, the contact area with the heating heat source 310 is increased so that the heat transfer member 340 can smoothly receive the heat of the heating heat source 310 .

Also, the other end of the heat transfer member 340 may be formed to contact the hot gas flow path 320 . That is, the second contact end 342 contacting the hot gas flow path 320 is formed at the other end of the heat transfer member 340 . Thus, the heat transfer member 340 can smoothly conduct heat received from the heating source 310 in contact with the hot gas flow path 320 .

In particular, the second contact end 342 of the heat transfer member 340 may surround at least a portion of the hot gas flow path 320 and be in surface contact with it. For example, the second contact end 342 of the heat transfer member 340 may have a round structure having the same roundness as the hot gas flow path 320 . As a result, the contact area with the hot gas passage 320 is increased so that the heat of the heat transfer member 340 can be smoothly conducted to the hot gas passage 320 .

In addition, the heat transfer member 340 may be formed of a metal plate. In other words, it is possible to improve the thermal conductivity by using a metal material, and to improve the thermal conduction area by using a plate material.

In addition, two or more heat transfer members 340 may be provided in plurality. For example, one heat transfer member may be connected to one part of the connected flow-side passage 322 and another heat transfer member may be connected to another part of the connected flow-side passage 322 . It is preferable that each of the heat transfer members 340 be disposed adjacent to each other to minimize heat loss due to open exchange with outdoor air.

In particular, the heat transfer member 340 may be formed to be elastically deformable. As a result, even if the distance between the hot gas flow path 320 and the heating source 310 is formed differently from the designed distance, the heat transfer member 340 can be combined.

At least a portion of the heat transfer member 340 may be formed to be rounded or bent for elastic deformation. That is, the heat transfer member 340 can have elasticity due to the round or bent structure.

At this time, the bending direction or bending angle of the heat transfer member 340 may be formed differently depending on the distance between the hot gas flow path 320 and the heating heat source 310 or the shape of the heating heat source 310 .

In the following, the operation of the refrigerator according to the above-described embodiment of the present invention and the defrosting operation will be described in detail.

Prior to the description, it is taken as an example that various operations are performed by a controller in the refrigerator. Of course, although not described in detail, various operations can be performed by a control means (for example, a home network or an online service server) on a network connected by wired or wireless communication so as to control the controller of the refrigerator instead of the corresponding refrigerator. can be performed

First, the cooling operation for the storage compartment 101 supplies cold air according to the upper limit reference temperature (NT+Diff) and the lower limit reference temperature (NT-Diff) based on the set reference temperature (NT) of the storage compartment 101, or , which is carried out by stopping the supply of cold air.

For example, when the internal temperature of the storage compartment 101 exceeds the upper limit reference temperature (NT+Diff) and reaches an unsatisfactory temperature, cold air is supplied to the storage compartment 101 . And, when the internal temperature of the storage compartment 101 reaches the lower limit reference temperature (NT-Diff), the supply of cold air to the storage compartment 101 is stopped.

When cold air is supplied to the storage chamber 101, the compressor 210 of the refrigeration system 210 is operated, and the flow path switching valve 330 is operated so that the refrigerant flows through the refrigerant flow path 260.

The refrigerant compressed by the operation of the compressor 210 is condensed while passing through the condenser 220, and the condensed refrigerant is reduced in pressure and expanded while passing through the expander 230. Subsequently, the refrigerant passes through the refrigerant pipe 242 of the evaporator 240, exchanges heat with air flowing around through the heat exchange fin 241, flows into the compressor 210, and is compressed, repeating a circular operation.

In addition, the air in the storage compartment 101 is flowed through the evaporator 240 by the operation of the blowing fan 281 and then re-supplied into the storage compartment 101 to repeat the circulation operation. In this process, the air exchanges heat with the evaporator 240 and is supplied into the storage compartment 101 at a lower temperature to lower the temperature in the storage compartment 101 . This is as shown in the attached Figure 12.

In addition, while the above-described operation for maintaining the set reference temperature NT of the storage chamber 101 is performed, whether or not the defrosting operation of the evaporator 240 is satisfied (whether or not the defrosting operation is performed) is continuously determined.

Satisfaction with the defrosting operation can be determined in various ways. For example, it is possible to determine whether the defrosting operation is satisfied by checking whether the accumulated operation time of the compressor 310 has elapsed. In addition, whether or not the defrosting operation is satisfied may be determined by checking the air flow rate or flow velocity of the front and rear of the evaporator 240 . In addition, it is also possible to determine whether the defrost operation is satisfied by checking whether the storage chamber 101 achieves an unsatisfactory temperature continuously for a predetermined period of time.

If it is determined that the defrosting operation is satisfied by at least one method, the defrosting operation of the evaporator 240 is performed.

The defrosting operation may be performed by heating of the heating heat source 310 and operation of the compressor 210 and the flow path conversion valve 330 . At this time, the flow path switching valve 330 is operated so that the refrigerant flows into the hot gas flow path 320 . This is as shown in the attached Figure 13.

That is, heat generated by the heating source 310 provides heat to the evaporator 240, and the high-temperature refrigerant (hot gas) compressed in the compressor 210 passes through the condenser 220 and passes through the hot gas passage 230. Heat is provided to the evaporator 240 while being guided to pass through the evaporator 240. When hot gas is provided through the hot gas flow path 320 , the cooling fan 221 cooling the condenser 220 may be controlled not to operate. That is, the high-temperature refrigerant passing through the compressor 210 due to the inactivity of the cooling fan 221 does not decrease in temperature while passing through the condenser 220 and can be maintained in a high-temperature state.

In particular, the hot gas is introduced to the upper end of the evaporator 240 along the inlet flow-side passage 321 and then sequentially passes through the heat exchange fins 241 of each row to provide conduction heat to the corresponding heat exchange fins 241.

In addition, while the hot gas flows along the connection flow-side passage 322 connected to the inlet flow-side passage 321, it receives heat from the heating heat source 310 from the heat transfer member 340.

At this time, since the heat transfer member 340 is installed to be in surface contact with the heating heat source 310, it can receive sufficient heat. In addition, since the heat transfer member 340 is installed to be in surface contact with the flow-side flow path 322 connected to the hot gas flow path 320, sufficient heat can be conducted.

Thus, while the hot gas introduced through the inlet flow-side passage 321 flows along a part of the evaporator 240, it provides conduction heat by heat exchange with the heat exchange pin 241, and after the temperature gradually decreases, the connection flow While flowing along the side passage 322, it is reheated.

In addition, the reheated hot gas flows along the outflow flow-side passage 323 while providing conduction heat to another part of the corresponding evaporator 240 and then discharged to the outside of the corresponding evaporator 240 . Accordingly, the evaporator 240 may receive sufficient heat for defrosting at all locations where the hot gas flow path 320 is located.

In particular, considering that each of the flow-side passages 321 , 322 , and 323 through which the hot gas flows is in contact with the heat exchange fins 241 of each row, the heat exchange fins 241 are heated faster than the heating heat source 310 providing radiant heat. will do As a result, the upper side of the evaporator 240, where frost is most severe, can receive sufficient heat, so that defrosting can be completed quickly and defective defrosting can be prevented.

Then, the hot gas (refrigerant) that has passed through the evaporator 240 flows into the compressor 210, is compressed, and then flows into the condenser 220 to repeat the cycle.

As described above, since the defrosting operation is performed while the heating heat source 310 and the hot gas are used together in the refrigerator of the present invention, the time for the defrosting operation is shortened. In addition, power consumption for defrosting operation is reduced.

In particular, since the refrigerator of the present invention reheats the hot gas flow path 320 with heat generated by the heat generated by the heating heat source 310 using the heat transfer member 340, until the hot gas completely passes through the evaporator 240 Sufficient heat can be provided for defrosting.

In addition, in the refrigerator of the present invention, since the heat transfer member 340 is formed to be bendable, the heat transfer member 340 is stably coupled even if the interval between the hot gas flow path 320 and the heating source 310 is formed differently from the designed interval. It can be.

In addition, in the refrigerator of the present invention, since the heat transfer member 340 is formed to be in surface contact with the heating heat source 310, it can receive sufficient heat from the heating heat source 310.

In addition, the refrigerator of the present invention can conduct sufficient heat to the hot gas passage 320 because the heat transfer member 340 is formed to be in surface contact with the hot gas passage 320 .

In addition, in the refrigerator of the present invention, since the heat transfer member 340 is connected to the flow-side flow path 322 of the hot gas flow path 320, the hot gas (refrigerant) whose temperature has decreased while passing through the evaporator 240 can be reheated. there is. Accordingly, sufficient heat may be provided until the hot gas completely passes through the evaporator 240 .

Meanwhile, the hot gas flow path 320, the heating heat source 310, and the heat transfer member 340 constituting the refrigerator of the present invention can be applied to a refrigerator having two or more evaporators 240 unlike the above-described embodiment. .

For example, as shown in FIG. 14, the evaporator 240 for the refrigerating compartment In the refrigerator provided with a) and the freezer compartment evaporator 240b, the hot gas flow path 320 guides the refrigerant flow directly to the freezer compartment evaporator 240b through the condenser 220 without passing through the freezer compartment expander 230b. The hot gas passage 320 may be configured to receive heat from the heating heat source 310 installed in the evaporator 240b for the freezing compartment to the heat transfer member 340 .

As such, the hot gas passage 320, the heating heat source 310, and the heat transfer member 340 of the present invention can be applied to all refrigerator evaporators requiring defrosting.

In addition, the hot gas flow path 320 and the heating heat source 310 of the present invention may be utilized in various ways other than for defrosting operation of the evaporator 240 .

For example, the hot gas passage 320 may be used to provide heat to prevent freezing of the door 110 .

In addition, the hot gas flow path 320 may also be used to provide heat for breaking ice in an ice maker.

In addition, the hot gas passage 320 may also be used for removing moisture from glass or the like.

In addition, the hot gas passage 320 may also be used to prevent overcooling of the storage compartment.

In addition, the heating heat source 310 can be used for heating the hot gas flow path 320 for each purpose described above. At this time, the heat transfer member 340 may be used to transfer the heat of the heating heat source 310 to the hot gas flow path 320 or to transfer the heat of the hot gas flow path 320 to the heating heat source 310. there is.

100. Refrigerator main body 101. Storage room
103. machine room 110. door
210. Compressor 220. Condenser
230. Expander 240. Evaporator
241. Heat exchange fin 242. Refrigerant pipe
243. Side plate 281. Blowing fan
260. Refrigerant flow 310. Heating source
320. Hot gas flow path 321. Flow-side flow path
322. Connection flow-side passage 323. Outflow flow-side passage
330. Euro conversion valve 340. Heat transfer member
341. First contact stage 342. Second contact stage

Claims (19)

A compressor that compresses the refrigerant;
a condenser condensing the refrigerant compressed in the compressor;
an expander for depressurizing the refrigerant condensed in the condenser;
an evaporator for evaporating the refrigerant reduced in pressure from the expander;
a refrigerant passage for guiding a flow of refrigerant recovered from the condenser through an expander and an evaporator to a compressor;
a hot gas flow path provided separately from the refrigerant flow path and guiding a flow of the high-temperature refrigerant compressed in the compressor to return to the compressor through a region requiring heat without passing through the expander;
A refrigerator comprising: a heating heat source that provides heat while being heated by power supply. According to claim 1,
A refrigerator including a heat transfer member that conducts heat from the heating heat source to the hot gas flow path. According to claim 2,
The refrigerator, characterized in that the heat transfer member is in contact with the heating heat source. According to claim 2,
The refrigerator, characterized in that the heat transfer member is in contact with the hot gas flow path. According to claim 2,
The refrigerator, characterized in that the heat transfer member is formed of a metal plate. According to claim 2,
The refrigerator, characterized in that the heat transfer member is formed to be elastically deformable. According to claim 2,
The heat transfer member is characterized in that it is formed to be rounded or bent as it goes from a contact area with the heating heat source to a contact area with the hot gas flow path. According to claim 2,
Refrigerator characterized in that one end of the heat transfer member is formed to be in surface contact while surrounding at least a portion of the heating heat source. According to claim 2,
The refrigerator characterized in that the other end of the heat transfer member is formed to be in surface contact while surrounding at least a portion of the hot gas flow path. According to claim 2,
Refrigerator, characterized in that the heat transfer member is provided in a plurality of two or more. According to claim 1,
The refrigerator, characterized in that the heating heat source is located adjacent to one side of the evaporator. According to claim 11,
The hot gas flow
A refrigerator, characterized in that a hot gas inlet side is connected to a portion of the evaporator opposite to a portion where the heating heat source is located. According to claim 11,
The hot gas flow
A refrigerator, characterized in that a hot gas outlet side is connected to a portion opposite to a portion of the evaporator where the heating heat source is located. According to claim 11,
The refrigerator, characterized in that the hot gas inlet side and the hot gas outlet side of the hot gas flow path are located at opposite sides of the portion where the heating heat source is located. According to claim 11,
The refrigerator according to claim 1 , wherein at least a portion of the hot gas flow path is connected to pass through an area adjacent to the heating heat source. According to claim 1,
The evaporator is configured to include a plurality of rows of heat exchange fins spaced apart from each other from one side to the other,
The hot gas flow path is formed to sequentially penetrate from heat exchange fins of one outer row among heat exchange fins of each row to heat exchange fins of the other outer row. 17. The method of claim 16,
The hot gas flow path,
An inlet flow-side flow path formed to sequentially penetrate from the heat exchange fins of one outer row to the heat exchange fins of the other outer row;
a connection flow-side passage extending from the inlet flow-side passage and sequentially passing through the heat exchange fins of the other outer row;
The refrigerator characterized in that it comprises an outflow flow-side passage extending from the connection flow-side passage and sequentially penetrating heat exchange fins of any one of the outer rows. 18. The method of claim 17,
The refrigerator, characterized in that the heating heat source is located adjacent to the connection flow-side passage. 18. The method of claim 17,
A heat transfer member for conducting the heat of the heating heat source to the hot gas flow path is further included,
The refrigerator, characterized in that the heat transfer member is formed to connect the connection flow-side passage and the heating heat source.

Images