KR20230010384A - refrigerator - Google Patents

Abstract

The refrigerator of the present invention allows the heating heat source or the refrigerant (hot gas) that has passed through the condenser to be used as a heat source for heating the first evaporator, thereby minimizing the temperature increase in the first storage compartment after performing the heat supply operation to reduce the temperature drop. This is to reduce power consumption for heat supply operation and to have physical properties suitable for heat exchange in the second evaporator in the process of the refrigerant flowing along the hot gas flow path passing through the first evaporator and flowing into the second evaporator during the heat supply operation. Accordingly, damage to the compressor due to different physical properties of the refrigerant returned to the compressor can be prevented.

Description

refrigerator {refrigerator}

The present invention relates to a refrigerator having two evaporators for temperature control of two storage compartments.

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.

In particular, frost formed on the surface of the evaporator gradually accumulates and affects the flow of cold air passing through the evaporator. That is, as the flow of cold air passing through the evaporator worsens in proportion to the amount of frost, the heat exchange efficiency decreases.

Thus, conventionally, the evaporator is operated for defrosting (defrosting operation) when a predetermined time elapses after operating the refrigerator or when conditions for the defrosting operation are satisfied.

The defrosting operation is performed using one or a plurality of defrost heaters installed in the evaporator, and when the defrosting operation is performed by the heat generated by these defrost heaters, the cooling operation for each storage compartment is stopped.

However, in the case of the defrosting method using only the defrosting heater, it takes a considerable amount of time to lower each storage compartment to a set temperature after the defrosting operation is finished, and there is a disadvantage in that power consumption is severe.

In particular, a defrost method using a defrost heater does not perform uniform defrost and requires more heating than necessary, which causes an increase in the temperature in the refrigerator, which adversely affects food stored in the storage compartment.

Accordingly, 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, it is as suggested in Patent Publication No. 10-2010-0034442 (Prior Document 1).

However, in the technology of Prior Document 1 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 defrosting heater.

In particular, the technique of Prior Document 1 is a method in which the hot gas discharged from the compressor flows directly into the evaporator without passing through the expander, and then defrosts the evaporator and then recovers the hot gas to the compressor. As a result, since the refrigerant is not sufficiently expanded, the refrigerant (hot gas) liquefied inside the evaporator does not circulate sufficiently and remains in the pipe.

In addition, the above-described technology of Prior Document 1 is applied only to a refrigerator in which a single compressor performs a cooling operation for one evaporator, and cannot be applied to a refrigerator in which a single compressor performs a cooling operation for two or more evaporators. .

Meanwhile, recently, a defrosting technique using hot gas has been provided in a refrigerator in which a single compressor performs a cooling operation for two evaporators. This is as presented in Patent Publication No. 10-2017-0013766 (Prior Document 2) and Publication Patent Publication No. 10-2017-0013767 (Prior Document 3).

However, since the technologies of Prior Art 2 and Prior Art 3 described above are defrosting the evaporator using only hot gas, power consumption is reduced, while defrosting time is not significantly shortened compared to the method using a defrost heater.

In addition, the above-described technologies of Prior Documents 2 and 3 pass through the expander for the evaporator of the other storage compartment when the hot gas passing through the evaporator is injected into the evaporator of the other storage compartment. Accordingly, there is a problem in that it is difficult to control the amount of refrigerant introduced into the evaporator of the other storage compartment.

That is, the refrigerant flowing directly through the condenser into the evaporator of the other storage compartment and the refrigerant flowing into the evaporator of the other storage compartment after passing through the condenser and one evaporator have different pressures and temperatures. For this reason, a difference in heat exchange performance due to a difference in decompression in the process of passing through the same expander is inevitable.

As such, in the prior art, various efforts have been made to enable rapid defrosting while minimizing power consumption, and to shorten recovery time while minimizing temperature rise in the storage compartment, but a sufficiently improved effect has not been obtained.

Patent Publication No. 10-2010-0034442 Publication Patent 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 described above, and an object of the present invention is to shorten the operation time for supplying heat to the first evaporator to reduce the increase in temperature inside the furnace due to the supply of heat. it did

In addition, another object of the present invention is to improve power consumption by minimizing power consumption for heat supply operation.

In addition, another object of the present invention is to rapidly cool the internal temperature of the refrigerator, which has risen due to defrosting of the evaporator, to a set temperature range.

According to the refrigerator of the present invention for achieving the above object, a physical property adjusting unit may be provided on a flow path of the refrigerant passing through the first evaporator and flowing into the second evaporator. As a result, the physical properties of the refrigerant flowing into the second evaporator can always be maintained constant.

In addition, according to the refrigerator of the present invention, the resistance of the second expander and the physical property controller that depressurizes the refrigerant flowing into the second evaporator may be different from each other. Thus, even if there is a difference in physical properties between the refrigerant passing through the first evaporator and flowing into the second evaporator and the refrigerant flowing directly into the second evaporator without passing through the first evaporator, the difference can be resolved when flowing into the second evaporator. .

Further, according to the refrigerator of the present invention, a flow path switching valve may be included to switch the flow path so that the refrigerant flows from the discharge tube to at least one of the first flow path, the second flow path, or the hot gas flow path.

Further, according to the refrigerator of the present invention, the hot gas flow path may include a first pass from the flow path switching valve to the first evaporator.

In addition, according to the refrigerator of the present invention, the hot gas flow path may include a second pass from the first pass through the first evaporator to the physical property controller.

Further, according to the refrigerator of the present invention, the first path of the hot gas flow path may be formed to have the same diameter as the flow path from the condenser to the flow path switching valve.

Also, according to the refrigerator of the present invention, the second pass of the hot gas flow path may be formed to have a larger diameter than the first pass.

Also, according to the refrigerator of the present invention, the second path of the hot gas flow path may be formed to have a diameter smaller than that of the flow path passing through the first evaporator of the first flow path.

In addition, according to the refrigerator of the present invention, the physical property control unit may be formed to have different resistance by varying the length of the second expander.

In addition, according to the refrigerator of the present invention, the length of the property control unit may be shorter than that of the second expander so that the resistance of the property control unit is smaller than that of the second expander.

In addition, according to the refrigerator of the present invention, the physical property control unit may be formed to have different resistances by having a different tube diameter from the second expander.

In addition, according to the refrigerator of the present invention, the tube diameter of the property control unit may be larger than that of the second expander so that the resistance of the property control unit is smaller than that of the second expander.

In addition, according to the refrigerator of the present invention, a heating heat source may be provided.

Also, according to the refrigerator of the present invention, the second path of the hot gas flow path may be connected to pass through the heating heat source.

In addition, according to the refrigerator of the present invention, the second path of the hot gas flow path may be connected to heat with hot gas from a side far from the heating heat source of the first evaporator.

In addition, according to the refrigerator of the present invention, the heating heat source is located on either side of the first evaporator, and the second pass is formed such that the hot gas inlet side is located on the opposite side of the first evaporator to where the heating heat source is located. can

Also, according to the refrigerator of the present invention, at least a part of the second pass may be formed to be heated while passing a region adjacent to the heating heat source.

In addition, according to the refrigerator of the present invention, the second path may be formed such that the hot gas outlet side is located on the opposite side from where the heating heat source is located.

In addition, according to the refrigerator of the present invention, the second path of the hot gas flow path may be connected so that the hot gas flows out of the first evaporator away from the heating heat source through the heating heat source.

Also, according to the refrigerator of the present invention, the first evaporator may be configured such that a portion of the first evaporator into which hot gas is introduced through the second pass of the hot gas flow path is heated faster than a portion adjacent to the heating heat source during a defrosting operation.

In addition, according to the refrigerator of the present invention, the heating heat source may be provided at the lower part of the first evaporator.

In addition, according to the refrigerator of the present invention, the second pass may be connected to pass through each heat exchange pin of the first evaporator and come into contact therewith.

Further, according to the refrigerator of the present invention, the flow path switching valve may be operated so that the refrigerant passing through the condenser passes through the hot gas flow path when the first evaporator is defrosted.

In addition, according to the refrigerator of the present invention, the first evaporator may be configured to generate cold air supplied to the first storage compartment, and the second evaporator may generate cold air supplied to the second storage compartment maintained at a higher temperature than the first storage compartment. there is.

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

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

In addition, since the refrigerator of the present invention is configured such that hot gas used for defrosting of the first evaporator passes through the second evaporator, the cooling operation of the second storage compartment is possible despite the defrosting operation of the first evaporator. In addition, since only the cooling operation of the first storage compartment needs to be performed after the defrosting operation, power consumption is reduced.

In particular, since the hot gas is supplied to the second evaporator after the physical properties of the refrigerant are adjusted in the physical property control unit after passing through the first evaporator, heat exchange by the refrigerant supplied to the second evaporator during the defrosting operation of the first evaporator is poor. prevented

In addition, since the refrigerator of the present invention is configured to heat while supplying hot gas from a place far from the heating heat source in the first evaporator to the second pass of the hot gas flow path for defrosting the first evaporator, the entire area of the first evaporator is Selective defrosting is possible.

In addition, since the refrigerator of the present invention is formed such that the second pass is in contact with the heat exchange pin, the defrosting effect by conductive heat is improved.

In addition, since the refrigerator of the present invention is formed such that the second pass is heated while passing through a region adjacent to the heating heat source, heat for defrosting is sufficiently supplied to the refrigerant outflow side of the second pass.

In addition, since the refrigerator of the present invention is configured to heat from the upper end of the first evaporator where the most frost is generated in the second pass, defrost failure in which frost remains after defrosting is prevented.

In addition, in the refrigerator of the present invention, since the first pass is formed to have the same diameter as the discharge tube, pressure fluctuations are prevented during the transfer of the refrigerant (hot gas), and a common tube can be used.

In addition, in the refrigerator of the present invention, the physical property control unit is formed to a length different from that of the second expander in consideration of the pipe diameter of the second pass and the state (temperature or pressure, etc.) of the refrigerant (hot gas) passing through it. Because of this, poor heat exchange in the process of passing through the second evaporator and poor compression in the process of passing through the compressor are prevented.

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 a first evaporator of a refrigerator according to an embodiment of the present invention;
6 is a side view illustrating a state in which a hot gas flow path and a heating source are installed in a first evaporator of a refrigerator according to an embodiment of the present invention;
7 is a state diagram illustrating a refrigerant flow during a cooling operation for a first storage compartment of a refrigerator according to an embodiment of the present invention;
8 is a state diagram illustrating a refrigerant flow during a cooling operation for a second storage compartment of a refrigerator according to an embodiment of the present invention.
9 is a state diagram illustrating a refrigerant flow during a cooling operation for a second storage compartment of a refrigerator according to an embodiment of the present invention.
10 is a graph showing the average temperature change of the first evaporator when the heat supply operation of the first evaporator is performed using different heat sources by a refrigerator according to an embodiment of the present invention;
11 is a graph showing temperature changes in a first storage compartment when a heat supply operation of a first evaporator is performed using different heat sources by a refrigerator according to an embodiment of the present invention;
12 is a graph showing power consumption when a heat supply operation of a first evaporator is performed using different heat sources by a refrigerator according to an embodiment of the present invention;
13 is a graph showing temperature changes in a second storage compartment when a heat supply operation of a first evaporator is performed using different heat sources by a refrigerator according to an embodiment of the present invention;
14 is a graph showing a PH diagram according to a cooling operation of a second storage compartment of a refrigerator according to an embodiment of the present invention.
15 is a graph showing the temperature change of the second storage compartment during the normal cooling operation of the second storage compartment and the heat supply operation of the first storage compartment by the refrigerator according to an embodiment of the present invention.
16 is a graph showing temperature changes of a refrigerant inlet and a refrigerant outlet of a second evaporator during a normal cooling operation for a second storage compartment of a refrigerator according to an embodiment of the present invention.
17 is a graph showing temperature changes at the refrigerant inlet and the refrigerant outlet of the second evaporator during the heat supply operation of the first storage compartment by the refrigerator according to an 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 17 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, in the refrigerator according to an embodiment of the present invention, the heating heat source 310 or the refrigerant (hot gas) passing through the condenser 220 can be used as a heat source for heating the first evaporator 250. it was made to

In addition, in the refrigerator according to an embodiment of the present invention, the refrigerant (hot gas) flowing to the second evaporator 260 sequentially passes through the condenser 220 and the first evaporator 250 passes through the condenser 220 to the second evaporator. It has the same physical properties as a refrigerant flowing directly to (260). Accordingly, damage to the compressor 210 due to differences in physical properties of the refrigerant recovered to the compressor 210 can be prevented.

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

First, as shown in the accompanying FIGS. 1 to 3 , the refrigerator according to the embodiment of the present invention may include a refrigerator body 100 providing at least one or more storage compartments.

For example, the storage compartment includes a first storage compartment 101 and a second storage compartment 102 as a storage space for storing stored goods. Of course, a plurality of first storage compartments 101 may be provided or a plurality of second storage compartments 102 may be provided.

In addition, the first storage compartment 101 and the second storage compartment 102 can be opened and closed by the first door 110 and the second door 120, respectively. Of course, although not shown, the first storage compartment 101 and the second storage compartment 102 may be simultaneously opened and closed with one door, or partially opened and closed with two or more doors.

The first storage compartment 101 is operated to maintain the first set reference temperature NT1. The first set reference temperature NT1 may be a temperature at which stored objects may be frozen. For example, the first set reference temperature NT1 may be set to a temperature of 0°C or less and -24°C or more.

The first set reference temperature NT1 may be set by the user, and when the user does not set the first set reference temperature NT1, an arbitrarily designated temperature is used as the first set reference temperature NT1. .

In addition, the second storage compartment 102 may be operated to be maintained at a different temperature range from that of the first storage compartment 101 .

For example, the second storage compartment may be operated to be maintained at the second set reference temperature NT2, and in this case, the second set reference temperature NT2 may be a temperature at which stored objects do not freeze. That is, the second set reference temperature NT2 may be in a higher temperature range than the first set reference temperature NT1.

Specifically, the second set reference temperature NT2 may be set to a temperature below 32°C and above 0°C. Of course, the second set reference temperature NT2 may be set higher than 32° C., equal to or lower than 0° C., as needed (eg, depending on room temperature or type of storage).

In the embodiment of the present invention, it is exemplified that the first storage compartment 101 is a freezing compartment and the second storage compartment 102 is a refrigerating compartment.

On the other hand, supply of cold air to each storage chamber 101 or 102 described above is continued or stopped according to the upper or lower limit temperature of each set reference temperature NT1 or NT2. For example, when the temperature of the storage compartments 101 and 102 exceeds the upper limit reference temperatures (NT1 + Diff, NT2 + Diff), the control is performed so that cold air is supplied to the corresponding storage compartments 101 and 102, and is lower than the lower limit reference temperatures (NT1-Diff, NT2-Diff). When it is low, the cold air supply is controlled to be stopped. As a result, each of the storage chambers 101 and 102 can be maintained at the respective set reference temperatures NT1 and NT2.

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

That is, the cold air that can be maintained at the set reference temperatures NT1 and NT2 is supplied to each of the storage compartments 101 and 102 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 a first expander 230 and a second expander 240 . The first expander 230 and the second expander 240 are conduits for reducing and expanding the refrigerant condensed in the condenser 220 .

In particular, the first expander 230 is formed to depressurize the refrigerant flowing into the first evaporator 250 after passing through the condenser 220, and the second expander 240 passes through the condenser 220 to reduce the pressure of the refrigerant. It may be formed to depressurize the refrigerant flowing into the evaporator 260.

Also, the refrigeration system may include a first evaporator 250 and a second evaporator 260 .

The first evaporator 250 is a device that evaporates the refrigerant depressurized by the first expander 230 to exchange heat with air (cold air) flowing in the first storage compartment 101 . The second evaporator 260 is a device that evaporates the refrigerant depressurized by the second expander 240 to exchange heat with air (cold air) flowing in the second storage compartment 102 .

In particular, while the first evaporator 250 is located in the first storage compartment 101, cold air flowing by the driving of the blowing fan 281 for the first storage compartment undergoes heat exchange, and the second evaporator 260 performs heat exchange with the second storage compartment. Cool air flowing by the driving of the blowing fan 282 for the second storage compartment while being located in the 102 is heat-exchanged.

At this time, the blowing fan 281 for the first storage compartment may be installed in the grill 280 for the first storage compartment in the first storage compartment 101, and the blowing fan 291 for the second storage compartment may be installed in the second storage compartment 102. ) It can be installed in the grill 290 for the second storage compartment in.

Also, the refrigeration system may include a first flow path 201 .

The first flow path 201 is formed to guide the flow of refrigerant recovered from the condenser 220 to the compressor 210 through the first expander 230 and the first evaporator 250 . That is, the first passage 201 may be a flow path of the refrigerant for the freezing operation of the first storage chamber 101 .

Also, the refrigeration system may include a second flow path 202 .

The second flow path 202 is formed to guide the flow of the refrigerant recovered from the condenser 220 to the compressor 210 through the second expander 240 and the second evaporator 260 . That is, the second passage 202 may be a flow path of the refrigerant for the refrigerating operation of the second storage chamber 102 .

Meanwhile, the refrigerant recovered to the compressor 210 through the respective evaporators 250 and 260 may be recovered through the recovery passage 211 connected to the compressor 210 .

In this case, the recovery passage 211 may be respectively connected to the first passage 201 and the second passage 202 .

In addition, the refrigeration system may include a physical property control unit 270.

The physical property control unit 270 is formed to provide resistance to the flow of the refrigerant passing through the first evaporator 250 and flowing into the second evaporator 260 . That is, resistance is provided to the flow of the refrigerant so that the physical properties of the refrigerant are adjusted (changed). At this time, the physical properties of the refrigerant may include any one of temperature, flow rate, and flow rate of the refrigerant.

The physical property control unit 270 may be formed as a conduit through which the refrigerant flows.

That is, the refrigerant condensed and liquefied while passing through the first evaporator 250 has physical properties in a state where heat exchange can be easily performed in the second evaporator 260 while passing through the property control unit 270 . As a result, a problem affecting the operation reliability of the compressor 210 due to excessive liquefaction of the refrigerant returned to the compressor 210 after passing through the second evaporator 260 can be prevented.

In particular, the resistance provided by the physical property control unit 270 may be formed differently from the resistance provided by the second expander 240 . Accordingly, a difference in physical properties between the refrigerant passing through the first evaporator 250 and flowing into the second evaporator 260 and the refrigerant flowing directly into the second evaporator 260 without passing through the first evaporator 250 can be minimized. .

The physical property control unit 270 may be designed in consideration of the flow path length, the pressure within the flow path, and the density of the refrigerant within the flow path. That is, the resistance may be adjusted by changing at least one of the flow path length of the material property controller 270, the pressure within the flow path, and the density of the refrigerant within the flow path.

For example, the above-mentioned physical property adjusting unit 270 may be formed to have a different diameter or a different length from that of the second expander 240 . That is, the physical properties of the refrigerant flowing into the second evaporator 260 via the first evaporator 250 and the physical properties of the refrigerant flowing directly from the condenser 220 into the second evaporator 260 are different from each other. Accordingly, the physical properties of the refrigerant flowing into the second evaporator 260 via the first evaporator 250 are almost similar to or , so that the same can be achieved.

Specifically, the physical property control unit 270 may have the same diameter as the second expander 240 but may have a different length. That is, the lengths of the physical property control unit 270 and the second expander 240 may be formed to be different so that the physical properties of each other may be different. At this time, the physical property control unit 270 may be formed shorter than the second expander 240 . In particular, since the material property controller 270 and the second expander 240 have the same diameter, they can be used in common.

As another embodiment, the physical property control unit 270 may be formed to have the same length as the second expander 240 but have different pipe diameters, so that the resistance provided to the refrigerant may vary. At this time, the material property control unit 270 may have a larger pipe diameter than the second expander 240 .

In addition, the refrigeration system may include a flow path conversion valve 330.

Specifically, the refrigerant passing through the condenser 220 is formed to be guided through the discharge tube 203, and the first flow path 201, the second flow path 202 and the hot gas flow path 320 are the discharge tube ( 203) may be formed to be branched from each other.

The flow path conversion valve 330 may be installed at a portion where each flow path 201 , 202 , 320 is branched from the discharge tube 203 . That is, the refrigerant flowing into the discharge tube 203 by the operation of the flow path switching valve 330 is directed to any one of the first flow path 201, the second flow path 202, and the hot gas flow path 320. that could be supplied.

For example, the flow path conversion valve 330 may be formed as a 4-way valve.

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

The hot gas passage 320 may be formed to provide high-temperature heat to a place where heat is needed.

The hot gas passage 320 may be formed to guide the refrigerant (hot gas) compressed in the compressor 210 and passing through the condenser 220 . That is, the refrigerant guided by the hot gas flow path 320 provides heat.

For example, the hot gas flow path 320 passes through the condenser 220 separately from the first flow path 201 and the second flow path 202, passes through the first evaporator 250, and then passes through the second evaporator 260. It can be formed so that the refrigerant (hot gas) flows. That is, the hot gas passage 320 is formed so that the high-temperature refrigerant compressed by the compressor 210 passes through the condenser 220 and then passes through the first evaporator 250 to heat the first evaporator 250. It can be.

When hot gas is provided through the hot gas flow path 320 , the cooling fan provided in the condenser 220 may be controlled not to operate. That is, the high-temperature refrigerant passing through the compressor 210 by not operating the cooling fan can be maintained in a high-temperature state without decreasing in temperature while passing through the condenser 220 .

Meanwhile, the hot gas flow path 320 includes a first path 321 from the flow path switching valve 330 to the first evaporator 250 and a second path 322 passing through the first evaporator 250. ), and a third pass 323 from the first evaporator 250 to the property control unit 270.

Here, the first pass 321 and the third pass 323 may be formed to have the same diameter as the discharge tube 203 extending from the condenser 220 to the flow path conversion valve 330 . Thus, common use of the discharge tube 203 and the first pass 321 and the third pass 323 is possible.

And, the second pass 322 may be formed to have a larger diameter than the first pass 321 . That is, the second pass 322 does not simply pass through the first evaporator 250, but penetrates through each heat exchange fin 251 constituting the first evaporator 250 and then expands the heat exchange fin ( 251) was brought into contact. As a result, the hot gas passing through the second pass 322 can smoothly remove the frost frozen in the first evaporator 250 .

At this time, the second path 322 may be formed to have a smaller diameter than the refrigerant pipes 252a and 252b passing through the first evaporator 250 among the first flow paths 201 . That is, the refrigerant pipes 252a and 252b of the first evaporator 250 are formed to have a larger diameter than the second pass 322, thereby providing higher heat exchange performance. At this time, the refrigerant pipes 252a and 252b are the inlet refrigerant pipe 252a located on one side and the outlet refrigerant pipe 252b located on the other side when looking at the heat exchange fins 251 of each row as a standard. may be included.

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

The heating heat source 310 is a heat source that provides high-temperature heat together with the hot gas flow path 320 .

The heat provided by the heating heat source 310 or the hot gas flow path 320 may be used in various ways.

For example, heat provided by the heating heat source 310 or heat provided by the hot gas flow path 320 may be used to defrost the first evaporator 250 .

The heating heat source 310 may be formed of a sheath heater (Sheath HTR) that generates heat by power supply.

The heating heat source 310 may be provided at any one adjacent part of the first evaporator 250 .

For example, as shown in FIGS. 5 and 6 , when the first evaporator 250 is installed in an upright state, the heating source 310 may be located below the first evaporator 250. .

Specifically, the heating heat source 310 may be spaced apart from the lowermost heat exchange fin 251 of the first evaporator 250 .

In addition, the heating heat source 310 and the first evaporator 250 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 253 of the two side plates 253 on both sides for supporting the refrigerant pipes 252a and 252b. Of course, the heating heat source 310 may be configured separately from the first evaporator 250 .

In addition, the second path 322 constituting the hot gas flow path 320 may be formed so that the hot gas inlet side is located on the opposite side of the first evaporator 250 from where the heating source 310 is located. That is, the second pass 322 may be formed to provide heat by hot gas (refrigerant) from a side far from the heating heat source 310 while the hot gas inlet side is located at the upper end of the first evaporator 250. .

Specifically, the second pass 322 is connected to pass through the heat exchange fins 251 of the uppermost row of the first evaporator 250, and then the heat exchange fins 251 of each row in order of the lower row. are connected to pass through them sequentially.

In particular, at least a portion of the second pass 322 may pass through an area adjacent to the heating heat source 310 . For example, a portion passing through the heat exchange fins 251 of the lowermost row of the second pass 322 may be connected to pass through a portion adjacent to the heating heat source 310 . Thus, even if the temperature of the refrigerant passing through the second pass 322 is lowered while passing through the first evaporator 250, it can be reheated by the heat provided from the heating source 310.

In addition, the second path 322 may be formed so that the hot gas outlet side is located on the opposite side from where the heating heat source 310 is located. That is, the second pass 322 passes through the heat exchange fins 251 of the lowermost row, then sequentially penetrates the heat exchange fins 251 of the uppermost row in the order of the upper row, and then connects to the physical property adjusting unit 270. can be formed

The second pass 322 may be installed to pass through the heat exchange fins 251 of each row in the same order as the refrigerant pipes 252a and 252b of the first evaporator 250 .

Meanwhile, the second pass 322 may be positioned between the inlet-side refrigerant pipe 252a and the outlet-side refrigerant pipe 252b among the heat exchange fins 251 of each row constituting the first evaporator 250. . That is, as shown in FIG. 9 , when the first evaporator 250 is viewed from the side, the second path 322 may be positioned between the left and right refrigerant pipes 252a and 252b. Accordingly, it is possible to design for uniform conduction of heat to all parts of the heat exchange fin 251 .

Of course, although not shown, the second pass 322 may be located outside the refrigerant pipes 252a and 252b of the first evaporator 250 . That is, the second pass 322 is intensively located at a portion of the first evaporator 250 where a greater amount of frost is generated than other portions (eg, a portion on the refrigerant inlet side of the refrigerant pipe), or Among 322, the hot gas inlet side can be arranged so that it is located.

Due to the connection structure of the second pass 322, the hot gas inlet and the hot gas outlet may be connected so as to pass through the uppermost heat exchange fins 251.

In addition, by the structure in which the second pass 322 is in contact with the heat exchange pin 251, the first evaporator 250 is in the hot gas flow path ( An area where the hot gas is introduced through the second pass 322 of 320 may be heated more quickly. That is, the connection structure of the second pass 322 that conducts heat while directly contacting the heat exchange pin 251 can heat the heat exchange pin 251 faster than the heating source 310 that heats the heat exchange pin 251 with radiant heat.

In particular, in the case of the first evaporator 250, more frost is generated at the upper portion where the refrigerant flows through the refrigerant pipes 252a and 252b due to a larger temperature difference than at other portions. Considering this, frost generated on the upper side of the first evaporator 250 can be sufficiently removed by using the second pass 322 .

Next, a guide passage 350 may be included in the refrigerator according to an embodiment of the present invention.

The guide passage 350 may be formed to guide the refrigerant flowing into the second evaporator 260 through the second expander 240 or the property control unit 270 .

That is, the refrigerant passing through the second expander 240 or the property control unit 270 passes through the guide passage 350, or is mixed with each other in the guide passage 350, and then enters the second evaporator 260. can flow into As a result, the deviation between the physical properties of the refrigerant passing through the second expander 240 and flowing into the second evaporator 260 and the physical properties of the refrigerant flowing into the second evaporator 260 through the property adjusting unit 270 can be reduced. .

Hereinafter, the operation of each storage chamber and defrosting operation of the refrigerator according to the above-described embodiment of the present invention will be described in detail.

Prior to the description, it is taken as an example that the operation of each storage compartment and the defrosting operation are performed by a controller (not shown) provided for operation of the refrigerator.

Of course, although not described in detail, the operation and defrosting operation for each storage compartment are a control means on a network connected by wired or wireless communication (eg, a home network or an online service server, etc.).

First of all, the cooling operation for each storage room (101, 102) is based on the set reference temperature (NT1, NT2) for each storage room. ), it is performed by supplying cold air or stopping the supply of cold air.

For example, when the internal temperature of the first storage compartment 101 exceeds the upper limit reference temperature (NT1+Diff) and reaches an unsatisfactory temperature, cold air is supplied to the first storage compartment 101 . And, when the internal temperature of the first storage compartment 101 reaches the lower limit reference temperature (NT1-Diff), the supply of cold air to the first storage compartment 101 is stopped.

When cold air is supplied to the first storage compartment 101, the compressor 210 of the refrigeration system and the blowing fan 281 for the first storage compartment operate, and the flow path switching valve 330 passes through the first flow path 201. It is operated so that the refrigerant flows.

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 first expander 230. Subsequently, the refrigerant passes through the first evaporator 250, exchanges heat with air flowing around the refrigerant, flows into the compressor 210, and repeats a circular operation in which it is compressed.

In addition, the air in the first storage compartment 101 passes through the first evaporator 250 and is re-supplied into the first storage compartment 101 by the operation of the blowing fan 281 for the first storage compartment, and the circulation operation is repeated. In this process, the air exchanges heat with the first evaporator 250 and is supplied into the first storage compartment 101 at a lower temperature to lower the temperature in the first storage compartment 101 . The flow of the refrigerant during the cooling operation of the first storage chamber 101 is as shown in FIG. 7 .

On the other hand, when the internal temperature of the second storage compartment 102 reaches an unsatisfactory temperature, the operation is performed so that cold air is supplied to the second storage compartment 102 .

When cold air is supplied to the second storage compartment 102, the compressor 210 of the refrigeration system and the blowing fan 282 for the second storage compartment operate, and the flow path switching valve 330 passes through the second flow path 202. It is operated so that cold air flows.

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 second expander 240. Subsequently, the refrigerant passes through the second evaporator 260, exchanges heat with air flowing around it, flows into the compressor 210, and repeats a cycle of being compressed.

Then, by the operation of the blowing fan 282 for the second storage compartment, the air in the second storage compartment 102 passes through the second evaporator 260 and is re-supplied into the second storage compartment 102, repeating the circulation operation. In this process, the air exchanges heat with the second evaporator 260 and is supplied into the second storage compartment 102 at a lower temperature to lower the temperature in the second storage compartment 102 . The flow of the refrigerant during the cooling operation of the second storage chamber 102 is as shown in FIG. 8 .

If the internal temperature of the first storage compartment 101 and the second storage compartment 102 both reach unsatisfactory temperatures, the operation may be performed so that cold air is preferentially supplied to one storage compartment and then to supply cold air to the other storage compartment. there is.

For example, the operation may be performed such that cold air is preferentially supplied to the second storage compartment 102 to achieve a satisfactory temperature, and then cold air is supplied to the first storage compartment 101 . This is because since the second storage compartment 102 is a storage compartment maintained at room temperature, the stored goods stored in the corresponding storage compartment may be sensitive to temperature changes.

In addition, while the operation of maintaining the set reference temperatures (NT1, NT2) for each of the storage chambers 101 and 102 described above is performed, the satisfaction for performing the heat supply operation for the first evaporator 250 can be continuously determined. . At this time, in the following embodiment, the heat supply operation is a defrosting operation as an example.

Whether or not the heat supply operation is satisfied (satisfaction of the conditions for performing the defrosting operation) can be determined in various ways.

For example, it is possible to determine whether the defrost operation is satisfied by checking whether the cumulative operation time of the compressor has elapsed.

As another example, whether or not the defrosting operation is satisfied may be determined by checking the flow rate or flow rate of air before and after the first evaporator 250 .

As another example, it may be determined whether or not the defrosting operation is satisfactory by checking whether the first storage chamber 101 reaches an unsatisfactory temperature continuously for a predetermined period of time.

If it is confirmed that the heat supply operation (defrosting operation) is satisfied by at least one method, the heat supply operation for the first evaporator 250 is performed.

The heat supply operation may be performed by generating heat from the heating source 310 and operating the compressor 210 and the flow path switching 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 .

That is, the heat generated by the heating source 310 provides heat to the first evaporator 250, and the hot gas (refrigerant) that has passed through the condenser 220 after being compressed in the compressor 210 passes through the hot gas flow path 320. While being guided to pass through the first evaporator 250 , heat is provided to the first evaporator 250 . The flow of refrigerant during the heat supply operation to the first evaporator 250 is as shown in FIG. 9 .

The hot gas is introduced to the top of the first evaporator 250 along the second path 322, and then passes through the heat exchange fins 251 of each row sequentially, providing conduction heat to the corresponding heat exchange fins 251. In addition, in the process of passing through the heating heat source 310 and the adjacent part of the second pass 322, the hot gas is heated again and then passes through the heat exchange fins 251 of each row sequentially, and is applied to the corresponding heat exchange fins 251. Again, conduction heat is provided.

In particular, considering that the second path 322 through which the hot gas flows is in contact with each of the heat exchange fins 251, the heat exchange fins 251 are heated faster than the heating heat source 310 providing radiant heat. . As a result, the upper side of the first evaporator 250, where frost is most severe, can receive sufficient heat, so that defrosting can be completed quickly and defective defrosting can be prevented.

10 shows the average temperature change of the first evaporator 250 when the heat supply operation of the first evaporator 250 is performed using different heat sources.

That is, performing the heat supply operation using the heating heat source 310 and the hot gas as in the embodiment of the present invention is performing the heat supply operation using the conventional heating heat source and the L-cord heat source (L-cord). A higher temperature can be achieved compared to the same time, and the time for the heat supply operation (defrosting operation) can be shortened accordingly.

In addition, the hot gas (refrigerant) that has passed through the first evaporator 250 passes through the property control unit 270 and has its physical properties adjusted (reduced and expanded), and then passes through the guide passage 350 to the second evaporator 260. After passing through the second evaporator 260, it exchanges heat with the air (cold air) in the second storage compartment 102, and then flows to the compressor 210 to be compressed, repeating the cycle.

As such, the refrigerator of the present invention performs a cooling operation of supplying cold air to the second storage chamber 102 despite the heat supply operation of the first evaporator 250 using hot gas.

Thus, after the defrosting operation is completed, only the operation for cooling the first storage compartment 101 needs to be performed, so that the first storage compartment 101 is set to a satisfactory temperature (the set reference temperature NT1 and the lower limit reference temperature NT-diff). The time to return to (between) can be shortened.

At this time, the attached FIG. 11 shows first before and after the end of the heat supply operation for the case of using only the heating heat source, the case of using the heating heat source and the L-cord heat source together, and the case of using the heating heat source and hot gas together. The temperature of the storage compartment 101 is shown by time.

That is, it can be seen that the temperature of the first storage chamber 101 immediately after the end of the heat supply operation is lowest when the heating heat source and hot gas are used together, and thus, the first storage chamber 101 immediately after the end of the heat supply operation ) to a satisfactory temperature (between the set reference temperature (NT1) and the lower limit reference temperature (NT-diff)).

In addition, 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 required for the heat supply operation to the first evaporator 250 can be shortened. In addition, power consumption for heat supply operation is reduced.

That is, the heat supply operation of the present invention can further shorten the defrosting time even though it consumes less power than the conventional defrosting operation performed using both the conventional defrost heater and the L-cord heater. This can be seen through the bar indicated in the attached graph of FIG. 12 .

In addition, in the refrigerator of the present invention, since the second pass 322 of the hot gas flow path 320 heats while supplying hot gas from a place far from the heating heat source 310 of the first evaporator 250, during the defrosting operation, the first Even defrosting of all parts of the evaporator 250 is possible.

In addition, in the refrigerator of the present invention, since the second pass 322 is formed to contact the heat exchange pins 251, the heating effect (defrosting effect) by conduction heat is improved.

In addition, since the refrigerator of the present invention is formed so that the second pass 322 is heated while passing through a region adjacent to the heating heat source 310, high-temperature heat can be provided to the refrigerant outflow side of the second pass 322.

In addition, since the refrigerator of the present invention is configured to heat the second pass 322 from the top of the first evaporator 250 where the most frost is generated, defrost defects in which frost remains after defrosting are prevented.

In addition, since the refrigerator of the present invention is configured so that the hot gas used for defrosting the first evaporator 250 passes through the second evaporator 260, despite the defrosting operation of the first evaporator 250, the second storage compartment ( The cooling operation of 102) is possible.

In addition, since only the cooling operation of the first storage compartment 101 needs to be performed after the defrosting operation, power consumption can be reduced. That is, even though the defrosting operation is performed as shown in the accompanying graph of FIG. 13, since the temperature of the second storage compartment 102 is lower than before the defrosting operation, the cooling operation of the second storage compartment 102 after the defrosting operation is performed. Since it is not required, power consumption can be reduced.

In particular, when the refrigerator of the present invention is operated for cooling the second storage chamber 102 using hot gas, higher cooling power can be obtained with lower output than in general cooling operation. This is as shown in the PH diagram of FIG. 14 attached.

Further, in the refrigerator of the present invention, since the first pass 321 is formed to have the same diameter as the discharge tube 203, pressure fluctuations are prevented during the transfer of refrigerant (hot gas), and it is possible to use a common tube. Do.

That is, since flow resistance can be reduced by optimizing the diameter or length of each part of the hot gas flow path 320 to increase the refrigerant flow rate, the cooling rate of the second storage chamber 102 using hot gas for the same period of time is reduced to normal cooling. The cooling rate of the second storage compartment 102 may be faster than the cooling rate by operation. This is as shown in the attached graph of FIG. 15 .

In particular, as it is designed to minimize the flow resistance of the refrigerant flowing along the hot gas flow path 320, the temperature difference between the refrigerant inlet and the refrigerant outlet of the second evaporator 260 during normal cooling operation (see attached FIG. 16) During the heat supply operation using hot gas, the temperature difference between the refrigerant inlet and the refrigerant outlet of the second evaporator 260 (see attached FIG. 17) can be significantly reduced.

In addition, in the refrigerator of the present invention, since the hot gas that has passed through the first evaporator 250 is provided to the second evaporator 260 after its physical properties (eg, pressure or temperature) are adjusted in the physical property controller 270, Poor heat exchange due to a difference in physical properties between the refrigerant supplied to the second evaporator 260 during the defrosting operation of the first evaporator 250 and the refrigerant supplied to the second evaporator 260 during the cooling operation of the second storage compartment 102 is prevented. .

In particular, the property control unit 270 is formed with a length different from that of the second expander 240 in consideration of the pipe diameter of the second pass 322 and the state (temperature or pressure, etc.) of the refrigerant (hot gas) passing through it. . Therefore, poor heat exchange in the process of passing through the second evaporator 260 and poor compression in the process of passing through the compressor 210 are prevented.

Meanwhile, the refrigerator of the present invention can be implemented in various forms not shown unlike the above-described embodiments.

In one embodiment, the refrigerator of the present invention may not be provided with a heating source 310 .

That is, the hot gas flow path 320 may be configured to perform the function of the heating heat source 310 (supplying heat to a region requiring heat) instead.

In another embodiment, in the refrigerator of the present invention, when the heating heat source 310 is not provided, the positions of the hot gas inlet side and the hot gas outlet side of the second path 322 of the hot gas flow path 320 are similar to those of the above-described embodiment. can be designed differently.

As another embodiment, in the refrigerator of the present invention, heat generated by the refrigerant (hot gas) flowing through the hot gas flow path 320 may be used for other purposes other than defrosting operation of the first evaporator 250 .

For example, the hot gas flow path 320 may be used for heating a part requiring heat (eg, an ice maker for ice removal, a door to prevent frost formation, and a storage compartment to prevent overcooling).

As another embodiment, in the refrigerator of the present invention, the hot gas passage 320 may be formed as a conduit having the same outer diameter (or inner diameter) without being divided into a first pass 321 and a second pass 322 .

As another embodiment, in the refrigerator of the present invention, the flow path switching valve 330 may be operated to simultaneously open two or more flow paths.

For example, while the first flow path 201 and the hot gas flow path 320, the second flow path 202 and the hot gas flow path 320, or the first flow path 201 and the second flow path 202 are simultaneously opened, the condenser The refrigerant passing through 220 may flow.

As another embodiment, the refrigerator of the present invention may be formed such that the hot gas flow path 320 is branched from the flow path between the compressor 210 and the condenser 220 . That is, the high-temperature refrigerant passing through the compressor 210 may be formed to pass directly through the first evaporator 250 without passing through the condenser 220 and the first expander 230 by the hot gas flow path 320. will be.

As another embodiment, in the refrigerator of the present invention, the hot gas passage 320 may be used to cool the second storage compartment 102 .

That is, cool air is supplied to the second storage compartment 102 by allowing the refrigerant passing through the first evaporator 250 through the hot gas flow path 320 to flow to the second evaporator 260 after passing through the property control unit 270. this is possible At this time, if the cooling fan 221 provided in the condenser 220 (provided in the machine room) is controlled to operate, simultaneous cooling of the first storage compartment 101 and the second storage compartment 102 is possible.

100. Refrigerator main body 101. First storage compartment
102. Second storage room 103. Machine room
110. First door 120. Second door
201. 1st Euro 202. 2nd Euro
203. Discharge tube 210. Compressor
211. recovery path 220. condenser
221. Cooling fan 230. First expander
240. Second expander 250. First evaporator
251. Heat exchange fins 252a, 252b. Refrigerant pipe
253. Side plate 260. Second evaporator
270. Property control unit 280. Grill for the first storage room
281. Blowing fan for the first storage room 290. Grill for the second storage room
282. Blowing fan for second storage room 310. Heating heat source
320. Hot gas flow path 321. First pass
322. Second Pass 323. Third Pass
330. Oil conversion valve 350. Guide oil

Claims (20)

A compressor that compresses the refrigerant;
a condenser condensing the refrigerant compressed in the compressor and discharging it to a discharge tube;
a first expander for depressurizing the refrigerant condensed in the condenser;
a first evaporator for evaporating the refrigerant depressurized by the first expander;
a first passage for guiding a flow of refrigerant from the discharge tube passing through the first expander and the first evaporator;
a second expander for depressurizing the refrigerant condensed in the condenser;
a second evaporator for evaporating the refrigerant depressurized in the second expander;
a second passage for guiding the flow of the refrigerant from the discharge tube passing through the second expander and the second evaporator;
a hot gas passage for guiding a flow of refrigerant from the discharge tube to a second evaporator via a first evaporator;
a physical property control unit for controlling the physical properties of the refrigerant supplied to the hot gas passage and flowing into the second evaporator through the first evaporator;
a guide passage for guiding the refrigerant flowing into the second evaporator through the second expander or the property control unit;
A refrigerator comprising: a flow path switching valve for switching a flow path so that the refrigerant flows from the discharge tube to at least one of the first flow path, the second flow path, or the hot gas flow path. According to claim 1,
The refrigerator, characterized in that the property control unit is formed to provide a resistance different from that of the second expander. According to claim 2,
The property control unit is configured to vary resistance according to a difference between the physical properties of the refrigerant flowing through the first evaporator and into the second evaporator and the physical properties of the refrigerant flowing directly into the second evaporator after passing through the discharge tube. According to claim 2,
The refrigerator, characterized in that the resistance is formed to be different by varying the length of the physical property control unit with the second expander. According to claim 4,
The refrigerator, characterized in that the length of the physical property control unit is formed shorter than the length of the second expander. According to claim 2,
The refrigerator, characterized in that the resistance is formed to be different by differentiating the second expander and the tube diameter of the physical property control unit. According to claim 6,
The refrigerator, characterized in that the pipe diameter of the physical property control unit is formed larger than the pipe diameter of the second expander. According to claim 1,
The hot gas flow
A first pass from the flow path switching valve to a first evaporator;
A refrigerator characterized in that a second pass from the first pass through the first evaporator to the physical property controller is included. According to claim 8,
The refrigerator, characterized in that the first pass is formed to have the same diameter as the discharge tube. According to claim 8,
The refrigerator, characterized in that the second pass is formed to have a larger diameter than the first pass. According to claim 8,
The second path is formed to have a smaller diameter than a portion passing through the first evaporator of the first flow path. According to claim 8,
A refrigerator characterized in that a heating heat source is provided at the first evaporator or at a portion adjacent to the first evaporator. According to claim 12,
The refrigerator, characterized in that the second path is connected so as to pass through an area adjacent to the heating heat source. According to claim 12,
The heating heat source is located on either side of the first evaporator,
The refrigerator, characterized in that the second pass is formed such that the hot gas inlet side is located on the opposite side of the first evaporator to the place where the heating heat source is located. 15. The method of claim 14,
Refrigerator characterized in that at least a part of the second pass is formed to be heated while passing through a region adjacent to the heating heat source. 15. The method of claim 14,
The refrigerator, characterized in that the second path is formed such that the hot gas outlet side is located on the opposite side to where the heating heat source is located. According to claim 8,
The first evaporator includes a plurality of heat exchange fins,
The second pass is connected to pass through each heat exchange pin of the first evaporator and come into contact with the refrigerator. According to claim 1,
A refrigerator characterized in that a heating heat source is provided at the first evaporator or at a portion adjacent to the first evaporator. According to claim 18,
Refrigerator characterized in that at least a portion of the hot gas flow path is formed to be heated by receiving heat from the heating heat source. According to claim 1,
The flow path switching valve,
Refrigerator characterized in that when defrosting the first evaporator, the refrigerant passing through the discharge tube is operated to pass through the hot gas flow path.

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