KR20230010382A - operating method for a refrigerator - Google Patents

Abstract

The present invention relates to an refrigerator, in which the heat supply operation can be performed by simultaneously using a heating heat source and hot gas. Accordingly, it is possible to shorten the operation time required to provide heat, lower the temperature rise of a first storage compartment, and reduce power consumption for temperature recovery of the first storage compartment.

Description

Refrigerator operation control method {operating method for a refrigerator}

The present invention relates to an operation control method of a refrigerator configured to provide heat to an evaporator using 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.

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 heating heat sources installed in the evaporator, and when the defrosting operation is performed by the heat generated by these heating heat sources, the cooling operation for each storage compartment is stopped.

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

In particular, the defrosting method using a heating heat source does not perform uniform defrosting and requires more heating than necessary, which causes an increase in the internal temperature of the refrigerator, which adversely affects foods stored in the storage compartment.

Accordingly, a hot gas defrosting method using a hot refrigerant (hot gas) passing through a compressor has been conventionally provided, thereby shortening a defrosting time and minimizing an increase in temperature inside the refrigerator during a 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 heating heat source.

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 technique for defrosting an evaporator 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 Documents 2 and 3 described above use only hot gas to defrost the evaporator, power consumption is reduced, while defrosting time is not significantly reduced compared to the method using a heating source.

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 operating time for providing heat to the evaporator to reduce the rise in temperature inside the furnace due to the heat supply. .

In addition, another object of the present invention is to improve the heating performance of the first evaporator by supplying the high-temperature refrigerant compressed in the compressor to the first evaporator in a state where the temperature drop is minimized.

In addition, another object of the present invention is to quickly supply enough refrigerant to the first evaporator so that the first storage compartment can be quickly cooled when the heat supply operation is finished.

According to the operation control method of the refrigerator of the present invention for achieving the above object, a general cooling operation in which cooling is performed while supplying cold air to each storage compartment, a heat supply operation in which heat is supplied to the first evaporator, and a heat supply operation performed before Heat transfer operation may be included.

According to the operation control method of the refrigerator of the present invention, the heat supply operation may include a heat generation process in which heat is generated from a heating heat source and a heat exchange process in which heat is provided by hot gas.

According to the operation control method of the refrigerator of the present invention, when the room temperature is within the reference temperature range, the heating process of the heat supply operation may be performed with priority over the heat exchange process.

According to the refrigerator operation control method of the present invention, the heat generation condition of the heat generation process may include a case where the temperature FD of the first evaporator is equal to or higher than the temperature F in the first storage compartment.

According to the refrigerator operation control method of the present invention, the temperature FD of the first evaporator may include the temperature of the refrigerant outlet side of the first evaporator.

According to the refrigerator operation control method of the present invention, the temperature FD of the first evaporator may include the cold air outflow side temperature of the first evaporator.

According to the operation control method of the refrigerator of the present invention, a stop process of stopping the operation of the compressor from the end of the heat supply operation until the start of the heat supply operation may be included.

According to the operation control method of the refrigerator of the present invention, supply of cold air to the second storage compartment may be cut off after the heat supply operation is finished until the heat supply operation is performed.

According to the operation control method of the refrigerator of the present invention, the heat supply operation may include a heating process of heating the first evaporator.

According to the refrigerator operation control method of the present invention, the heat generation process may be performed when heat supply conditions for heating the first evaporator are satisfied after the heat supply operation of each storage compartment starts.

According to the refrigerator operation control method of the present invention, the heating process may be performed by supplying power to a heating heat source.

According to the operation control method of the refrigerator of the present invention, when the heating heat source satisfies the heat generation termination condition, heat generation may be stopped.

According to the refrigerator operation control method of the present invention, the heat generation termination condition may include a case where the temperature of the first evaporator reaches the set first temperature X1.

According to the refrigerator operation control method of the present invention, the heat supply operation may include a heat exchange process of heating the first evaporator and simultaneously cooling the second evaporator.

According to the refrigerator operation control method of the present invention, the heat exchange process can be performed while the high-temperature refrigerant compressed in the compressor through the hot gas flow path is guided to flow sequentially through the first evaporator and the second evaporator.

According to the refrigerator operation control method of the present invention, the refrigerant passing through the first evaporator during the heat exchange process may flow into the second evaporator after adjusting its physical properties.

According to the refrigerator operation control method of the present invention, the heat exchange process may be performed when the hot gas supply condition is satisfied after the heat transfer operation of each storage compartment is started.

According to the refrigerator operation control method of the present invention, hot gas supply conditions in the heat exchange process may include a case where a set time elapses after the heat transfer operation of each storage compartment is completed.

According to the refrigerator operation control method of the present invention, hot gas supply conditions in the heat exchange process may include a case where a set time elapses after power is supplied to the heating heat source.

According to the refrigerator operation control method of the present invention, the hot gas supply condition in the heat exchange process may include a case where the first evaporator temperature reaches the set second temperature X2 after the heat transfer operation of each storage compartment is completed. .

According to the operation control method of the refrigerator of the present invention, the compressor may be operated when the hot gas supply condition is satisfied after the operation is stopped when the heat supply operation is finished.

According to the operation control method of the refrigerator of the present invention, during the heat exchange process of the heat supply operation, the operation of the blowing fan for the first storage compartment for circulating cold air in the first storage compartment may be stopped.

According to the operation control method of the refrigerator of the present invention, during the heat exchange process of the heat supply operation, the blowing fan for the second storage compartment for circulating cold air in the second storage compartment can be controlled to operate.

According to the operation control method of the refrigerator of the present invention, the heat exchange process of the heat supply operation may be terminated when the heat exchange termination condition is satisfied.

According to the refrigerator operation control method of the present invention, the heat exchange termination condition may include a case where the temperature of the first evaporator reaches the set first temperature X1.

According to the refrigerator operation control method of the present invention, the heat exchange termination condition may include a case where the temperature in the second storage chamber reaches a satisfactory temperature.

According to the refrigerator operation control method of the present invention, the satisfactory temperature may include a temperature equal to or less than the lower limit reference temperature set based on the set reference temperature of the second storage compartment.

According to the refrigerator operation control method of the present invention, the heat exchange termination condition may include a case where a set time elapses from when the heating heat source generates heat.

According to the refrigerator operation control method of the present invention, the operation of the compressor may be stopped when the heat exchange termination condition is satisfied.

According to the refrigerator operation control method of the present invention, the supply of refrigerant to the hot gas flow path may be cut off when the heat exchange termination condition is satisfied.

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

Since the refrigerator of the present invention provides heat to the first evaporator by generating heat from a heating source and supplying hot gas, the operation time required to provide heat is longer than that in the case of providing heat to the first evaporator using only the high-temperature refrigerant. can shorten In addition, the temperature rise of the first storage compartment can be reduced as much as possible, and power consumption for temperature recovery of the first storage compartment can be reduced.

In addition, since the refrigerator of the present invention is controlled so that the compressor and the blower fan for the second storage compartment operate together during the heat exchange process of the heat supply operation, heat is provided to the first evaporator using a high-temperature refrigerant and cooling to the second storage compartment is simultaneously performed. can be performed

In addition, in the refrigerator of the present invention, after the heat supply operation, before the heat supply operation is performed, the flow path conversion valve is closed while the compressor continues to operate for a certain period of time to pump down, so that the high-temperature refrigerant during the heat exchange process is performed. can be sufficiently supplied while rapidly being supplied to the first evaporator.

In addition, since the heat supply operation of the refrigerator of the present invention is controlled to end when the temperature R of the second storage compartment is out of a satisfactory temperature, overcooling of the second storage compartment caused by excessive cooling of the second evaporator can be prevented.

In addition, the refrigerator of the present invention preferentially heats the first evaporator when the heating condition of the heating heat source is satisfied even during the rest process after the heat supply operation and before the heat supply operation, so the time for the overall heat supply operation is shortened. .

In addition, in the refrigerator of the present invention, unnecessary power consumption is minimized because the heating source generates heat when the first evaporator temperature (FD) is equal to the first storage compartment temperature (F).

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 showing an operating state of each component related to a heat supply operation of a refrigerator according to an embodiment of the present invention;
8 to 10 are state diagrams illustrating the flow of refrigerant during a cooling operation for each storage compartment of a refrigerator according to an embodiment of the present invention.
11 is a flowchart illustrating a process of a heat transfer operation of a refrigerator according to an embodiment of the present invention.
12 is a flowchart illustrating a process during a heat supply operation of a refrigerator according to an embodiment of the present invention.
13 is a state diagram illustrating a flow of refrigerant during a heat supply operation of a refrigerator according to an embodiment of the present invention;
14 is a flowchart illustrating a process of temperature return operation of a refrigerator according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of a refrigerator and an operation control method thereof according to 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 figures, in the refrigerator according to the embodiment of the present invention, the heat supply operation (S220) can be performed by simultaneously using the heating heat source 310 and hot gas. As a result, the operation time required to provide heat can be shortened, the temperature rise of the first storage compartment 101 can be reduced, and power consumption for temperature recovery of the first storage compartment 101 can be reduced.

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.

The storage compartment may include a first storage compartment 101 and a second storage compartment 102 as a storage space for storing stored goods.

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.

Each of the storage chambers 101 and 102 has a first upper limit reference temperature (NT11+Diff, NT21+Diff) and a first lower limit reference temperature (NT11-Diff, NT11-Diff, NT21-Diff) is operated to maintain the temperature.

Here, the first set reference temperature NT11 of the first storage chamber 101 may be a temperature sufficient to freeze stored goods. For example, the first set reference temperature NT11 of the first storage compartment 101 may be set to a temperature of 0°C or less and -24°C or more.

The first set reference temperature NT21 of the second storage chamber 102 may be a temperature at which the stored goods are not frozen. For example, the first set reference temperature NT21 of the second storage compartment 102 may be set to a temperature below 32°C and above 0°C.

The first set reference temperature (NT11, NT21) can be set by the user, and if the user does not set the first set reference temperature (NT11, NT21), the arbitrarily designated temperature is the first set reference temperature (NT11 , NT21).

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.

The 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 the first set reference temperatures NT11 or NT21. For example, when the temperature of the storage compartments 101 and 102 exceeds the first upper limit reference temperature (NT11 + Diff, NT21 + Diff), it is controlled to supply cold air to the storage compartment 101 and 102, and the first lower limit reference temperature (NT11 - Diff, NT21 -Diff), the cold air supply is controlled to stop. As a result, each of the storage compartments 101 and 102 has a first upper limit reference temperature (NT11+Diff, NT21+Diff) and a first lower limit reference temperature (NT11-Diff, NT21- Diff) can be maintained at a temperature between

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, cold air capable of being maintained at the first set reference temperatures NT11 and NT21 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 for compressing refrigerant and may be located in the refrigerator body 100 . Specifically, the compressor 210 may be located in the machine room 103 in the refrigerator body 100 .

In addition, a recovery passage 211 may be connected to the compressor 210 . The recovery passage 211 is a passage for guiding the suction flow of the refrigerant recovered to the compressor 210 . The recovery passage 211 may be formed of a pipe.

The recovery passage 211 may be formed such that each passage through which the refrigerant flows (eg, a first passage and a second passage or a hot gas passage, etc.) are connected and merged into one, and then returned to the compressor 210 . Of course, although not shown, two or more recovery passages 211 may be provided in plurality and connected individually or in plurality to each passage.

In addition, the refrigeration system may include a condenser 220.

The condenser 220 is a device that condenses the refrigerant compressed by the compressor 210, and may be located in the refrigerator body 100. Specifically, the condenser 220 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.

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 .

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 adjusting 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 first evaporator 250 while being connected to the discharge tube 203 of the condenser 220 separately from the first flow path 201 and the second flow path 202. 2 It may be formed so that the refrigerant (hot gas) flows into the evaporator 260 . 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.

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 second pass 322 to the material property adjusting unit 270.

Here, the first pass 321 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 is possible.

In addition, the second pass 322 may be formed to contact the heat exchange pins 251 through a pipe expansion operation after penetrating through each of the heat exchange pins 251 constituting the first evaporator 250 . As a result, the hot gas passing through the second pass 322 can smoothly remove the frost frozen in the first evaporator 250 .

Also, the third pass 323 may be formed to have the same diameter as the first pass 321 .

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, when the first evaporator 250 is installed in an erected state as shown in FIGS. 5 and 6, the heating heat 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 .

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. .

Meanwhile, reference numeral 280 denotes a first grill assembly guiding the flow of cold air into the first storage compartment, and reference numeral 290 denotes a second grill assembly guiding the flow of cold air into the second storage compartment.

Hereinafter, an operation control method for operation according to each situation and heat supply operation using the refrigerator according to the above-described embodiment of the present invention will be described in detail with reference to FIGS. 7 to 14 attached.

Prior to the description, it is taken as an example that the operation for each situation and the heat supply operation are performed by a controller provided for operation of the refrigerator. Of course, although not described in detail, the operation for each situation and the heat supply operation are a control means on a network connected by wired or wireless communication (eg, a home network or an online service server, etc.) can also be performed.

First, the operation of the refrigerator for each situation may include a general cooling operation (S100).

This general cooling operation (S100) is an operation for cooling the first storage compartment 101 and the second storage compartment 102 according to the first set reference temperatures NT11 and NT21, respectively, as shown in the flowchart of FIG.

That is, the first upper limit reference temperature (NT11+Diff, NT21+Diff) and the first lower limit reference temperature (NT11-Diff, NT21-Diff) based on the first set reference temperature (NT11, NT21) for each storage room (101, 102) A general cooling operation (S100) is performed by supplying cold air or stopping the supply of cold air according to.

For example, when the internal temperature of the first storage compartment 101 exceeds the first upper limit reference temperature (NT11 + Diff) and reaches an unsatisfactory temperature, cold air is supplied to the first storage compartment 101 (S131). Then, when the internal temperature of the first storage compartment 101 reaches the first lower limit reference temperature (NT11-Diff), the supply of cold air to the first storage compartment 101 is stopped (S132).

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 as shown in FIG. The refrigerant is operated to flow through the passage 201 .

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, and then returns to the compressor 210 to be compressed, repeating a circular operation.

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 .

In addition, when the internal temperature F of the first storage compartment 101 reaches the lower limit reference temperature (NT11-Diff), the supply of cold air to the first storage compartment 101 is stopped (S132).

During the normal cooling operation (S100), when the internal temperature (second storage compartment temperature) (R) of the second storage compartment 102 exceeds the first upper limit reference temperature (NT21 + Diff) to reach an unsatisfactory temperature, the second storage compartment 102 It is operated to supply cold air to (S121).

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 as shown in FIG. It is operated so that cold air flows through the flow path 202 .

And, when the compressor 210 is operated, the refrigerant is compressed and supplied to the condenser 220 to be condensed, and the condensed refrigerant passes through the second expander 240 to be reduced in pressure and expanded. 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. At this time, the cooling fan 221 provided to cool the condenser 220 is interlocked with the compressor 210 . That is, when the compressor 210 is operated during the normal cooling operation, the cooling fan 221 is also operated.

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 R of the second storage compartment.

Then, when the internal temperature R of the second storage compartment 102 reaches the lower limit reference temperature (NT21-Diff), the supply of cold air to the second storage compartment 102 is stopped (S122).

If the internal temperature (F, R) of the first storage chamber 101 and the second storage chamber 102 together form an unsatisfactory temperature (temperature higher than the first upper limit reference temperature (NT11+Diff, NT21+Diff)) It may be operated to supply cold air to one storage compartment first, and then to supply cold air to another storage compartment.

For example, cold air is preferentially supplied to the second storage compartment 102 to satisfy a temperature (a temperature between the first upper limit reference temperature (NT11+Diff, NT21+Diff) and the first lower limit reference temperature (NT11-Diff, NT21-Diff)). ), and then it can be operated so that 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.

Next, the operation of the refrigerator for each situation may include a heat transfer operation (S210).

The heat supply operation (S210) is a deep cooling operation performed before performing the heat supply operation (S220) when the start condition of the heat supply operation (S220) is satisfied during the above-described general cooling operation (S100). .

The heat transfer operation (S210) may be performed to sequentially cool the first storage compartment 101 and the second storage compartment 102 (S211 and S212), as shown in FIG.

That is, even if the temperature of each storage chamber (101, 102) rises while the heat supply operation (S220) is being performed, in order not to affect the stored goods, the heat supply operation (S220) is performed by performing the heat supply operation (S210) It is to cool each storage chamber (101, 102).

In particular, during the heat transfer operation (S210), each of the storage compartments 101 and 102 is cooled to the second lower limit reference temperature (NT12-Diff, NT22-Diff) set based on the second set reference temperature (NT12, NT22). It can be driven as much as possible.

At this time, the second set reference temperatures NT12 and NT22 may be set to different temperatures from the first set reference temperatures NT11 and NT21 during normal cooling operation. For example, the second set reference temperatures NT12 and NT22 may be set to a lower temperature than the first set reference temperatures NT11 and NT21. Accordingly, the second lower limit reference temperatures NT12-Diff and NT22-Diff may also be set to a lower temperature than the first lower limit reference temperatures NT11-Diff and NT21-Diff.

Of course, the second set reference temperature (NT12, NT22) is set to be the same as the first set reference temperature (NT11, NT21), and the first lower limit reference temperature (NT11-Diff, NT21-Diff) is the second lower limit reference temperature. It may be set to a temperature different from (NT12-Diff, NT22-Diff). Even in this case, the second lower limit reference temperatures NT12-Diff and NT22-Diff may be set to a lower temperature than the first lower limit reference temperatures NT11-Diff and NT21-Diff.

In addition, during the heat transfer operation (S210), the second flow path 202 and the first flow path 201 are sequentially opened or closed by the operation of the flow path switching valve 330, and the compressor 210 continues to operate. operation, and the blower fan 291 for the second storage compartment and the blower fan 281 for the first storage compartment are operated sequentially.

For example, during the cooling operation of the first storage compartment 101 (S212), the refrigerant flows into the first flow path 201 by the operation of the flow path switching valve 330, and the compressor 210 and the blowing fan for the first storage compartment ( 281) is operated.

If, during the cooling operation of the second storage compartment 102 (S211), the refrigerant flows into the second flow path 202 by the operation of the flow path switching valve 330, and the compressor 210 and the blowing fan for the second storage compartment ( 291) is operated.

The heat transfer operation (S210) may be performed so that the second storage compartment 102 is first cooled and then the first storage compartment 101 is cooled. That is, since the temperature of the second storage compartment 102 gradually decreases during the heat supply operation (S220), it may be desirable to minimize the temperature drop in the first storage compartment 101 by cooling it before the first storage compartment 101.

In addition, when the cooling of the first storage compartment 101 in the heat transfer operation (S210) is finished (S213), the pump may be controlled to be down. That is, even if the cooling operation of the first storage compartment 101 is completed and the flow path switching valve 330 is operated to block the flow of refrigerant to the respective flow paths 201 and 202, the compressor 210 is additionally operated for a certain period of time and the second evaporator 260 ) The refrigerant collected in is recovered to the compressor 210. Accordingly, when the heat exchange process (S222) of the heat supply operation (S220) is performed, the high-temperature refrigerant can be quickly supplied to the first evaporator (250) and supplied in a sufficient amount.

In addition, after the cooling of the first storage compartment 101 is completed (S213) and before the heat supply operation (S220) is performed, as shown in FIGS. 7, 11 and 12, a pause process (S216) is performed for a certain time is carried out That is, excessive continuous operation of the compressor 210 is prevented by providing the pause process (S216).

The pause process (S216) may be set by time. For example, after cooling of the first storage compartment 101 is completed, a pause process (S216) may be performed for a predetermined time before the heat supply operation (S220) is performed. That is, excessive continuous operation of the compressor 210 is prevented by providing the pause process (S216).

Preferably, the pause process (S216) may be set to a longer time than the minimum pause time of the compressor 210. For example, when the minimum pause time of the compressor 210 is 2 minutes, the pause process may be set to 3 minutes.

On the other hand, during the heat transfer operation (S210), the blowing fan 281 for the first storage compartment, which is operated during the cooling operation of the first storage compartment 101, supplies cold air to the first storage compartment 101 at the temperature of the first evaporator ( FD) may be operated until the first storage compartment temperature (F) is reached. That is, when the temperature of the first evaporator (FD) reaches the temperature (F) of the first storage compartment, the operation of the blowing fan 281 for the first storage compartment is stopped (S215).

In particular, the blower fan 281 for the first storage compartment 281 provides the heating heat source 310 after the operation of the compressor 210 is stopped, rather than before the operation of the compressor 210 is stopped due to the completion of cooling of the first storage compartment 101. It may be rotated at a higher speed until the heating condition is satisfied (S214). That is, maximizing the flow rate circulating in the first storage chamber 101 after the compressor 210 is stopped until the heating heat source 310 is operated is the most effective way to shorten the heating time (eg, the defrosting time of the first evaporator). It is advantageous.

At this time, the rotational speed of the blowing fan 281 for the first storage compartment before the operation of the compressor 210 is stopped after the heat supply operation (S210) is completed is performed to cool the first storage compartment 101 during the general cooling operation. It may be set equal to or slower than the rotational speed.

In addition, after the heat supply operation (S210) ends, the supply of cold air to the second storage chamber 102 may be blocked until the heat supply operation (S220) is performed.

A method of blocking the cold air supply may be performed in various ways.

As an example, after the heat supply operation (S210) is finished, the second storage compartment temperature (R) checked before the heat supply operation (S220) is performed may be excluded from the conditions for the cooling operation of the second storage compartment (102). can That is, after the heat supply operation (S210) is completed and before the heat supply operation (S220) is performed, the second storage room temperature (R) is an unsatisfactory temperature (temperature exceeding the second upper limit reference temperature (NT22 + diff)). Even if it is, the cooling operation of the second storage chamber 102 is not performed. As a result, supply of cold air to the second storage compartment 102 may be blocked.

As another example, after the heat supply operation (S210) ends, the operation of the compressor 210 may be stopped until the heat supply operation (S220) is performed. As a result, supply of cold air to the second storage compartment 102 may be blocked.

As another example, after the heat supply operation (S210) is finished, the second storage compartment temperature (R) may be controlled not to be measured until the heat supply operation (S220) is performed. As a result, supply of cold air to the second storage compartment 102 may be blocked.

As another example, after the heat supply operation (S210) ends, the flow path switching valve 330 may be controlled so that the refrigerant supply flowing to the second evaporator 260 is blocked until the heat supply operation (S220) is performed. there is. As a result, supply of cold air to the second storage compartment 102 may be blocked.

As another example, the operation of the blower fan 291 for the second storage compartment may be controlled to be stopped after the heat supply operation ( S210 ) ends until the heat supply operation ( S220 ) is performed. As a result, supply of cold air to the second storage compartment 102 may be blocked.

Next, the operation of the refrigerator for each situation may include a heat supply operation (S220).

The heat supply operation (S220) may be an operation to provide heat for heating the first evaporator (250). For example, the heat supply operation (S220) may be used to defrost frost generated on the surface of the first evaporator 250.

This heat supply operation (S220) may be performed when the operation conditions are satisfied. For example, when the defrosting operation of the first evaporator 250 is required, it may be determined that the operating conditions of the heat supply operation (S220) are satisfied.

At this time, the defrosting operation checks the amount or flow rate of cold air passing through the first evaporator 250, checks whether the cumulative operation time of the compressor 210 has elapsed, Whether or not operation is necessary can be determined by checking whether the temperature is continuously maintained at unsatisfactory temperature.

If it is confirmed that the operating condition (eg, the condition for the defrosting operation of the first evaporator) is satisfied by at least one method, the heat supply operation (S210) is preferentially performed and then the heat supply operation (S220) is performed. can be performed

The heat supply operation (S220) may include a heating process of providing heat to the first evaporator 250 using the heating heat source 310.

As shown in FIGS. 12 and 13, when the heat supply operation (S210) of each storage compartment 101 and 102 starts and the heating condition for heating the first evaporator 250 is satisfied, the heating heat source 310 This can be done by supplying power. That is, the first evaporator 250 is heated by generating heat from the heating source 310 only when the heating condition is satisfied.

An exothermic condition of the exothermic process may be set by time. For example, it may be determined that the heating condition is satisfied when a set time elapses after the heat supply operation (S210) ends.

However, if the heating condition is set to time, a disadvantage in that it is difficult to respond to changes in various surrounding environments may be caused. Considering this, it may be preferable that the heating condition of the heating process is set to temperature. That is, by setting the heating condition to temperature, it is possible to accurately respond to changes in various surrounding environments.

When the heating condition is set to temperature, the first evaporator temperature (FD) is checked (S221), and when the first evaporator temperature (FD) is equal to or higher than the first storage compartment temperature (F), it is determined that the heating condition is satisfied. do. That is, when the first evaporator temperature (FD) gradually rises and becomes equal to or higher than the first storage compartment temperature (F) during the heat transfer operation (S210) or after the heat transfer operation (S210) is completed, the heating condition is satisfied. It is determined that the heating heat source 310 generates heat (S222) and the heat generation process is performed.

In this case, the first evaporator temperature FD may include the temperature of the refrigerant outlet side or the cold air outlet side temperature of the first evaporator 250 .

When the heating heat source 310 generates heat due to the satisfaction of the heat generating condition described above, the time set in the pause process (S216) may be disregarded. That is, even before the time set for the pause process (S216) elapses, if the heating condition of the heating heat source 310 is satisfied, the heating heat source 310 can be controlled to generate heat.

Of course, even if the temperature of the first evaporator (FD) reaches the temperature of the first storage compartment (F), if the minimum idle time of the compressor 210 does not elapse, heat generation of the heating source 310 is delayed until the minimum idle time has elapsed. It is preferable to set it so that it is. For example, if 2 minutes have not elapsed after the heat supply operation (S210) is finished, even if the first evaporator temperature (FD) reaches the first storage compartment temperature (F), the heating heat source 310 will not pass the 2 minutes. It can be set to delay heat generation until

In addition, the heat supply operation (S220) may include a heat exchange process of providing heat to the first evaporator 250 using circulation of the refrigerant.

In the heat exchanging process, as shown in FIGS. 12 and 13, the first evaporator 250 may be heated and the second evaporator 260 may be cooled (S223). That is, it is possible to supply cold air to the second storage chamber 102 while performing the defrosting operation of the first evaporator 250 by the heat exchange process.

Thus, when the heat exchange process is performed, the temperature F of the first storage compartment may increase, while the temperature R of the second storage compartment may decrease.

Such a heat exchange process may be performed by supplying cold air to the hot gas flow path 320 after a pause process (S216) for a set time (eg, 3 minutes) is completed at the end of the heat transfer operation (S210). That is, the high-temperature refrigerant generated by the operation of the compressor 210 passes through the condenser 220 and flows along the hot gas flow path 320 to the first evaporator 250 without passing through the first expander 230. The first evaporator 250 is heated, the pressure is continuously reduced through the physical property control unit 270, and the heat is exchanged while passing through the second evaporator 260 to cool the second evaporator 260.

When the heat exchange process by the refrigerant is performed, the refrigerant passing through the discharge tube 203 of the condenser 220 is guided to flow along the hot gas flow path 320 by the operation of the flow path switching valve 330.

In addition, when the above heat exchange process is performed, the blowing fan 291 for the second storage compartment is also operated. Accordingly, the refrigerant that has passed through the first evaporator 250 passes through the physical property control unit 270 and is decompressed, and then exchanges heat with the cold air in the second storage compartment 102 in the process of passing through the second evaporator 260, and the cold air is It is provided to the second storage compartment 102 to lower the temperature in the second storage compartment 102 .

On the other hand, the heat exchange process by the refrigerant may be performed prior to the exothermic process or performed later than the exothermic process according to the room temperature.

For example, when the room temperature is divided into a reference temperature range and a high-temperature temperature range higher than the reference temperature range, the heating process may take precedence over the heat exchange process in the reference temperature range, as in the above-described embodiment. That is, considering that the temperature of the second storage chamber 102 may drop excessively due to the heat exchange process, the first evaporator 250 is first heated with the heating heat source 310, and then the first evaporator 250 is heated using a high-temperature refrigerant ( 250) may be desirable.

In particular, the heat exchange process is preferably performed when the hot gas supply condition of each storage compartment 101 or 102 is satisfied. That is, the operation of the compressor 210 is stopped when the heat supply operation (S210) ends, and then resumes operation when the hot gas supply condition is satisfied, supplying hot gas (high-temperature refrigerant) to the hot gas flow path 320.

These hot gas supply conditions may include various cases.

As an example, the hot gas supply condition may include a case where a set time elapses after power is supplied to the heating heat source 310 . For example, when 10 minutes have elapsed after supplying power to the heating heat source 310, it is determined that the hot gas supply condition is satisfied and the heat exchange process is performed.

Thus, when the heat from the heating heat source 310 starts to affect the first evaporator 250 after the heating heat source 310 generates heat, the high-temperature refrigerant flows along the hot gas flow path 320 to the first evaporator 250. While passing through, the corresponding first evaporator 250 can be additionally heated.

As another example, the hot gas supply condition may include a case where a set time elapses after the heat supply operation ( S210 ) of each storage chamber ( 101 , 102 ) ends. That is, when a set time elapses after the heat supply operation (S210) is finished, it is determined that the hot gas supply condition is satisfied, and the heat exchange process may be performed.

As another example, in the hot gas supply condition, after the heat supply operation (S210) of each storage chamber (101, 102) is completed, the first evaporator temperature (FD) reaches the set second temperature (X2) (FD≥X2). ℃) may be included. That is, when the first evaporator temperature (FD) reaches the set second temperature (X2) after the heat transfer operation (S210) is finished (FD≥X2°C), it is determined that the hot gas supply condition is satisfied and the heat exchange process is performed. It can be.

At this time, the second temperature (X2) may be a temperature higher than the first storage compartment temperature (F) and lower than the first temperature (X1) at which heat generation of the heating heat source 310 is terminated.

Of course, when the second temperature (X2) is set to the first temperature (X1) at which the heat generation of the heating heat source 310 is terminated, heating by heat from the heating heat source 310 and heating using hot gas are not simultaneously performed. may not be Considering this, the second temperature (X2) may be set to a lower temperature than the first temperature (X1) at which heat generation of the heating heat source 310 is terminated.

In addition, when the hot gas supply condition is satisfied and the heat exchange process is performed, the cooling fan 221 provided to cool the condenser 220 is not operated until the heat exchange process) is completed even when the compressor 210 is operated. can be controlled

That is, while the high-temperature refrigerant compressed in the compressor 210 passes through the condenser 220, the temperature drop (heat loss) caused by the operation of the cooling fan 221 is prevented, so that the highest-temperature refrigerant is transferred to the first evaporator ( 250) so that it can be provided.

In addition, when the hot gas supply condition is satisfied and the heat exchange process is performed, the blowing fan 281 for the first storage compartment for circulating cold air in the first storage compartment 101 may be controlled to stop its operation. That is, it is controlled to prevent the temperature rise of the first evaporator 250 from slowing due to the operation of the blowing fan 281 for the first storage compartment.

In addition, when the hot gas supply condition is satisfied and the heat exchange process is performed, the blowing fan 291 for the second storage compartment 102 may be controlled to operate. That is, when the refrigerant flows along the hot gas passage 320, the blowing fan 291 for the second storage compartment is operated so that the cold air in the second storage compartment 102 passes through the second evaporator 260 to exchange heat. Accordingly, while heating the first evaporator 250 , a process of supplying cold air to the second storage chamber 102 can be simultaneously performed.

Meanwhile, in the heat generation process and the heat exchange process of the above-described heat supply operation (S220), the heat generation process ends (S224) or the heat exchange process ends (S225) when the heat generation end condition or the heat exchange end condition is satisfied.

Here, the heat generation termination condition is a condition for terminating heat generation of the heating heat source 310 and may include a case where the first evaporator temperature FD reaches the preset first temperature X1. That is, when the first evaporator temperature (FD) reaches the first temperature (X1), it is determined that the heat generation end condition is satisfied, and the power supplied to the heating source 310 is cut off.

At this time, the first temperature (X1) is a temperature in consideration of damage to the storage due to the temperature rise of the first storage chamber 101, and may be set to, for example, 5 °C. In particular, the first temperature X1 described above may be equal to or higher than the second temperature X2 for confirming the satisfaction of the hot gas supply condition.

In addition, the heat exchange termination condition is a condition in which the supply of hot gas (refrigerant) is terminated, and may actually be a condition in which the heat supply operation for heating the first evaporator 250 is terminated.

These heat exchange termination conditions may include a case where the second storage chamber 102 reaches a satisfactory temperature. That is, since the second storage compartment 102 is a storage compartment for refrigerated storage, damage such as freezing of stored items may occur when the temperature drops excessively.

Considering this, it is necessary to maintain the temperature (R) of the second storage compartment in a satisfactory range so as not to cause damage (overcooling) of stored items. As a result, it is determined that the heat exchange termination condition is satisfied when the second storage compartment 102 reaches the satisfactory temperature. Thus, the supply of refrigerant to the hot gas flow path 320 is blocked.

At this time, the satisfactory temperature is a temperature equal to or less than the lower limit reference temperature (NT2-Diff) set based on the set reference temperature (NT2) of the second storage compartment (102). That is, when the temperature R of the second storage chamber reaches the lower limit reference temperature (NT2-Diff) or becomes lower than the lower limit reference temperature (NT2-Diff), the supply of refrigerant to the hot gas passage 320 is cut off.

Of course, when the second storage compartment 102 reaches the lower limit reference temperature (NT2-Diff), the blowing fan 291 for the second storage compartment may be controlled to stop. That is, by delaying the time for the second storage chamber 102 to reach a satisfactory temperature, it is possible to secure time for the first evaporator 250 to be sufficiently heated.

As another example, the heat exchange termination condition may be determined based on the total operating time of the heat supply operation (S220).

For example, when a set time elapses from the start of the heat exchange process, it is determined that the heat exchange termination condition is satisfied, and the supply of the refrigerant to the hot gas passage 320 is cut off, thereby ending the heat exchange process. At this time, the operation of the blowing fan 291 for the second storage compartment may be stopped.

Alternatively, when a set time elapses from when the heating heat source 310 generates heat, it is determined that the heat exchange termination condition is satisfied, and the supply of refrigerant to the hot gas flow path 320 is cut off, thereby ending the heat exchange process. At this time, the operation of the blowing fan 291 for the second storage compartment may be stopped.

The supply of refrigerant to the hot gas flow path 320 may be cut off by stopping the operation of the compressor 210 .

However, while the first evaporator 250 is in a high temperature state during the heat exchange process, the second evaporator 260 is in a low temperature state, and when the heat exchange process is completed and the operation of the compressor 210 is stopped, the pressure difference As a result, the refrigerant flows into the second evaporator 260. Accordingly, when the refrigerant is supplied to the first evaporator 250 for the cooling operation of the first storage chamber 102 after the heat exchange process is finished, a delay in the flow of the refrigerant to the first evaporator 250 inevitably occurs. There is a problem that the consumption efficiency is inevitably lowered due to this.

Accordingly, when the heat exchange process is finished, the supply of refrigerant to the hot gas passage 320 is cut off by preferentially closing the hot gas passage by controlling the operation of the passage switching valve 330 before stopping the operation of the compressor 210. It is preferable that the operation of the compressor 210 is controlled to be stopped after the compressor 210 is additionally operated in one state.

That is, the refrigerant collected in the second evaporator 260 is recovered to the compressor 210 by performing a pump down operation (S226) in which the compressor 210 is additionally operated while the flow of the refrigerant is blocked. Accordingly, when the cooling operation for the first storage chamber 101 of the temperature return operation (S230) is performed, the high-temperature refrigerant can be quickly and sufficiently supplied to the first evaporator 250.

Meanwhile, the heat supply operation (S220) according to the above-described embodiment of the present invention may be set differently according to the room temperature.

For example, when the room temperature is divided into a reference temperature range, a high-temperature range higher than the reference temperature range, and a low-temperature range lower than the reference temperature range, an exothermic process occurs in the reference temperature range or low temperature temperature range, as in the above-described embodiment. It may be performed prior to the heat exchange process. That is, if the room temperature is not in the high temperature range, the effect of the room temperature on the first evaporator 250 is insignificant. For this reason, the heating time of the first evaporator 250 is shortened by heating the periphery of the first evaporator 250 using the heating heat source 310 and then directly heating the first evaporator 250 using hot gas. be able to do

In this case, the reference temperature range may be set to an average indoor temperature range in spring and autumn, or may be a temperature considering other indoor conditions. In addition, the high-temperature temperature range may be set as an average indoor temperature range in summer or may be a temperature considering other indoor conditions.

Next, operation of the refrigerator for each situation may include a temperature return operation (S230).

The temperature return operation (S230) is an operation for cooling the first storage compartment 101, the temperature of which has risen in the heat supply operation (S220), to a satisfactory range.

14, the temperature return operation (S230) is performed by supplying cold air to the first storage compartment (101) after a pause process (S231) for a set time (eg, 3 minutes) at the end of the heat supply operation (S220). It can be.

Specifically, after the pause process (S231) is performed, an operation for cooling the first storage compartment 101 is performed. At this time, the flow path switching valve 330 is operated so that cold air flows through the first flow path 201, and the compressor 210 and the cooling fan 221 are operated together.

As a result, the refrigerant flows sequentially through the compressor 210, the condenser 220, the first expander 230, and the first evaporator 250.

In addition, when performing the operation for cooling the first storage compartment 101 described above, the blowing fan 281 for the first storage compartment may be operated. At this time, the blowing fan 281 for the first storage compartment may be operated from when the first evaporator temperature (FD) becomes lower than the first storage compartment temperature (F). As a result, the temperature F of the first storage compartment may gradually decrease.

Also, while the cooling operation of the first storage chamber 101 is being performed, defrosting (primary defrosting) may be performed in the second evaporator 260 . At this time, the blowing fan 291 for the second storage compartment is maintained in an inoperative state.

That is, since the blowing fan 291 for the second storage compartment is not operated, the second evaporator 260 is naturally defrosted. The operation of the blowing fan 291 for the second storage compartment may be stopped until the second evaporator temperature RD is equal to or higher than the first set temperature. For example, the first set temperature may be set to 3°C.

In particular, when the second evaporator temperature (RD) does not reach the first set temperature, cool air is supplied to the first storage compartment (101) until the temperature (F) of the first storage compartment reaches the lower limit reference temperature (NT11-Diff). The supply cooling operation is performed.

On the other hand, when the second evaporator temperature (RD) reaches the first set temperature, even if the first storage room temperature (F) does not reach the lower limit reference temperature (NT11-Diff), after pump down (S235) An alternate operation (S236) for cooling operation of the second storage compartment 102 and the first storage compartment 101 is performed.

That is, after the pump down (S235), the flow path switching valve 330 is operated so that the second flow path 202 is opened (refrigerant flows through the second flow path), and the blowing fan 291 for the second storage compartment is operated, The operation of the blowing fan 281 for the first storage compartment is stopped.

At this time, the pump-down (S235) may be performed for a predetermined time.

As such, since the refrigerator of the present invention provides heat to the first evaporator 250 by supplying heat from the heating heat source 310 and hot gas, heat is supplied to the first evaporator 250 using only the high-temperature refrigerant. It is possible to shorten the operation time required to provide heat compared to the case of providing heat, thereby reducing the temperature rise of the first storage compartment 101 as much as possible.

In addition, in the refrigerator of the present invention, during the heat exchange process (S222) of the heat supply operation (S220), the compressor 210 is operated and the blowing fan 291 for the second storage compartment is controlled to operate at the same time. Heat supply to the evaporator 250 and cooling of the second storage chamber 102 can be performed simultaneously.

In addition, in the refrigerator of the present invention, after the heat supply operation (S210) and before the heat supply operation (S220) is performed, the flow path switching valve 330 is closed while the compressor 210 continues to operate for a certain period of time. Down) (S226) is performed. For this reason, when the heat exchange process (S222) of the heat supply operation (S220) is performed, the high-temperature refrigerant can be rapidly and sufficiently supplied to the first evaporator (250).

In addition, in the refrigerator of the present invention, the heat supply operation (S220) of cooling the second evaporator 260 while providing heat to the first evaporator 250 is terminated when the temperature of the second storage compartment 102 exceeds the desired temperature. Since it is controlled, overcooling of the second storage compartment 102 caused by excessive cooling of the second evaporator 260 can be prevented.

In addition, the refrigerator of the present invention operates the first evaporator 250 when the heating condition of the heating heat source 310 is satisfied even during the stop process (S216) before the heat supply operation (S220) after the heat supply operation (S210) is performed. Since it is made to heat first, it is possible to shorten the time for the entire heat supply operation (S220).

In particular, since the heating condition of the heating heat source 310 includes a case where the first evaporator temperature FD is equal to the first storage compartment temperature F, the exact time of heat generation of the heating heat source 310 can be specified.

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

As an 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 than the 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, ice-breaking of an ice maker, prevention of frost formation on a door, prevention of overcooling in each storage compartment 101, 102, etc.) can

In another embodiment, in the refrigerator of the present invention, the hot gas flow path 320 is not divided into a first pass 321, a second pass 322, and a third pass 323 and has the same outer diameter (or inner diameter). It can be formed as a single conduit.

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.

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
260. Second evaporator 270. Property control unit
280. First grill assembly 281. Blowing fan for first storage compartment
290. Second grill assembly 291. Blowing fan for second storage compartment
310. Heating source 320. Hot gas flow path
321. First Pass 322. Second Pass
323. Third pass 330. Euro conversion valve
350. Guide flow

Claims (19)

A general cooling operation of supplying cold air to at least one of the first storage compartment and the second storage compartment;
A heat supply operation in which heat is provided to the first evaporator by using the heat generated by the heating heat source by supplying power and the high-temperature refrigerant flowing along the hot gas flow path;
A heat transfer operation for cooling the first storage compartment and the second storage compartment before the heat transfer operation is performed when the start condition of the heat supply operation is satisfied during the normal cooling operation;
The heat transfer operation
A heating process of heating the first evaporator by generating heat from a heating heat source when the heating condition for heating the first evaporator is satisfied after the heat transfer operation of each storage compartment starts;
After the heat transfer operation of each storage compartment starts, when the hot gas supply condition is satisfied, the compressor is driven, and among the passages connected to the discharge tube of the condenser, it sequentially passes through the first evaporator and the second evaporator without passing through the expander to return to the compressor. A method for controlling operation of a refrigerator, comprising a heat exchange process of heating the first evaporator with the high-temperature refrigerant and simultaneously cooling the second evaporator by opening a hot gas flow path for the flow of the refrigerant to be used. According to claim 1,
When the indoor temperature is divided into a standard temperature range and a high temperature range higher than the standard temperature range
The operation control method of a refrigerator, characterized in that the heating process is performed prior to the heat exchange process in the reference temperature range. According to claim 1,
The exothermic condition of the exothermic process is
A method for controlling operation of a refrigerator, comprising a case where the temperature (FD) of the first evaporator is equal to or higher than the temperature (F) in the first storage compartment. According to claim 3,
The operation control method of a refrigerator, characterized in that the temperature (FD) of the first evaporator includes the temperature of the refrigerant outlet side of the first evaporator. According to claim 3,
The operation control method of a refrigerator, characterized in that the temperature (FD) of the first evaporator includes the cold air outflow side temperature of the first evaporator. According to claim 1,
The operation control method of a refrigerator, characterized in that when the heating heat source satisfies a heat generation end condition, heat is stopped. According to claim 6,
The operation control method of a refrigerator characterized in that the heat generation end condition includes a case where the temperature of the first evaporator reaches a set first temperature range. According to claim 1,
The hot gas supply condition of the heat exchange process is
An operation control method of a refrigerator, characterized in that it includes a case where a set time elapses after the heat supply operation of each storage compartment is completed. According to claim 1,
The hot gas supply condition of the heat exchange process is
An operation control method of a refrigerator, characterized in that it includes a case where a set time elapses after supplying power to a heating heat source. According to claim 1,
The hot gas supply condition of the heat exchange process is
The operation control method of a refrigerator, characterized in that it includes a case where the temperature of the first evaporator reaches a set second temperature range after the heat transfer operation of each storage compartment is completed. According to claim 1,
The operation control method of a refrigerator according to claim 1 , wherein the operation of the compressor is stopped when the heat supply operation is terminated and then operated when hot gas supply conditions are satisfied. According to claim 1,
During the heat exchange process of the heat supply operation, the blower fan for the first storage compartment for circulation of cold air in the first storage compartment stops operating, and the blower fan for the second storage compartment for circulation of cold air in the second storage compartment is controlled to operate. Refrigerator operation control method. According to claim 1,
The operation control method of a refrigerator, characterized in that the heat exchange process of the heat supply operation is terminated when a heat exchange termination condition is satisfied. According to claim 13,
The heat exchange termination condition includes a case where the temperature of the first evaporator reaches a set first temperature range. According to claim 13,
The operation control method of a refrigerator, characterized in that the heat exchange end condition includes a case where the temperature in the second storage chamber reaches a satisfactory temperature. According to claim 15,
The operation control method of a refrigerator, characterized in that the satisfactory temperature includes a temperature equal to or less than a lower limit reference temperature (NT2-Diff) set based on the set reference temperature (NT2) of the second storage compartment. According to claim 13,
The operation control method of a refrigerator, characterized in that when the heat exchange termination condition is satisfied, the operation of the compressor is stopped and the heat exchange process is terminated. According to claim 13,
The operation control method of a refrigerator, characterized in that when the heat exchange termination condition is satisfied, the supply of refrigerant to the hot gas flow path is cut off and the heat exchange process is terminated. According to claim 1,
When the heat exchange process of the heat supply operation is finished, the pump is down for a predetermined time in a state in which the supply of refrigerant to the hot gas flow path is cut off, and then the operation of the compressor is controlled to stop.

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