JP2001280666A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent an unmelted portion being left after defrosting operation even when a thermostat is turned off. SOLUTION: This air conditioner is provided with a refrigerant circuit (20) in which a refrigerant is circulated through a compressor (30), a condenser (37), an expanding mechanism (36), and an evaporator (34) in this order and is operated for at least heating. The air conditioner discriminates whether or not the duration of heating operation exceeds rush time which is preset for starting defrosting operation by counting the duration. When the duration exceeds the rush time, the air conditioner performs the defrosting operation. In addition, when the thermostat is turned off during the heating operation within the rush time, the conditioner only shortens the rush time. Particularly, as the number of thermostat turning-offing times increases during the heating operation within the rush time, the conditioner successively shortens the rush time.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner, and more particularly to a measure for defrosting.

[0002]

2. Description of the Related Art Conventionally, air conditioners have been disclosed in
As disclosed in Japanese Patent Application Publication No. 120120, a compressor, an outdoor heat exchanger, an expansion valve, and a refrigerant circuit to which an indoor heat exchanger is connected are provided. The refrigerant circuit circulates the refrigerant to perform a cooling cycle and a heating cycle. There is something to do.

[0003] In the above-mentioned air conditioner, during the heating operation, frost is formed on the outdoor heat exchanger, so that a defrosting operation is performed. In the determination of the defrosting operation, whether or not to perform defrosting is determined based on the integrated heating capacity. On the other hand, when a preset inrush time elapses, defrosting is performed.

That is, in the above-described determination based on the integrated heating capacity, frost formation may increase, so that defrosting is performed at least when the operation time continues and the rush time elapses.

[0005]

In the above-described air conditioner, the defrosting operation is performed by the rush time in addition to the integrated heating capacity, but the rush time is fixed.

[0006] Within this fixed time, the room temperature reaches the set temperature, the heating operation is stopped, and so-called thermo-off is performed. If this thermo-off is repeated, hard ice will be formed, and it cannot be completely melted by the defrosting operation,
Residual melting occurs. As a result, there is a problem that the heating capacity is reduced.

[0007] The present invention has been made in view of such a point, and an object of the present invention is to prevent the occurrence of unmelted residue due to the defrosting operation even when the thermostat is turned off.

[0008]

More specifically, as shown in FIG. 1, the first invention comprises an air conditioner having a refrigerant circuit (20) constituting a vapor compression refrigeration cycle and performing at least a heating operation. Is assumed. When the heating operation is continued and the inrush time set in advance for the start of the defrosting operation has elapsed, the defrosting operation is performed, and when the heating operation is turned off within the inrushing time, the inrush time is reduced. .

In a second aspect, the refrigerant is a compressor (30)
And a refrigerant circuit (20) circulating in the order of a condenser (37), an expansion mechanism (36), and an evaporator (34), and is intended for an air conditioner that performs at least a heating operation. And the determination means (62) which counts the continuation time of the heating operation and judges whether or not the continuation time has passed a preset inrush time for starting the defrosting operation is provided. Further, the determination means (6
2) is provided with a defrosting means (63) for performing a defrosting operation when judging the elapse of the inrush time. In addition, the determination means (6
A correction means (64) for correcting the determination means (62) so as to shorten only the entry time when the heating operation is turned off within the entry time of 2) is provided. An air conditioner comprising:

[0010] In a third aspect based on the second aspect, the correcting means (64) increases the rush time as the number of times of heating-off of the heating operation increases within the rush time of the determining means (62). It is configured to be shortened in order.

That is, in the present invention, the judging means (62) counts the duration of the heating operation, and judges whether or not the duration has passed a preset inrush time for starting the defrosting operation. I do. And the defrosting means (63)
If 2) determines that the rush time has elapsed, the defrosting operation is performed.

On the other hand, the correcting means (64) comprises a judging means (62)
When the thermostat of the heating operation is turned off within the entry time, the judgment means (62) is corrected so as to shorten only the entry time, and the entry time corrected by the judgment means (62) is set.
In particular, the correcting means (64) in the third invention determines the corrected inrush time by sequentially shortening and correcting the inrush time as the number of times of the thermo-off of the heating operation increases within the inrush time of the determining means (62). (62).

That is, during the heating operation, when the temperature of the room air reaches the set temperature, the driving of the compressor (30) is stopped, the heating operation is stopped, and a so-called thermo-off state is established. Thereafter, when the temperature of the indoor air decreases, the compressor (30) is driven to restart the paused heating operation, and a so-called thermo-on state is set.

In the thermo-on state, the evaporator (34) as an outdoor heat exchanger is cooled by the refrigerant.
However, when the thermo-off state is reached, the cooling of the evaporator (34) is stopped, and the evaporator (34) is slightly warmed, so that the ice on the surface of the heat transfer tube among the ice adhered to the heat transfer tube of the evaporator (34) is melted. Thereafter, when the thermo-on state is reached, the evaporator (34) is cooled again, and the water melted from the ice becomes ice again.

When this melting and icing are repeated, the ice becomes hard ice, and as a result, unmelted residue occurs after the defrosting operation.

Therefore, in the present invention, the inrush time is corrected by the correction means (64). Specifically, for example, if one thermo-off is performed within the above-mentioned inrush time,
The entry time is reduced by 10 minutes, and a corrected entry time of 2 hours and 50 minutes is set. Then, after the correction entry time has elapsed, the defrost operation is performed.

If the thermostat is turned off twice during the rush time, the rush time is reduced by 20 minutes, and a corrected rush time of 2 hours and 40 minutes is set. Then, after the correction entry time has elapsed, the defrost operation is performed.

If the thermostat is not turned off within the rush time, a three-hour rush time is set without correcting the rush time. Then, after the rush time elapses, a defrost operation is performed.

[0019]

Therefore, according to the present invention, the preset inrush time for the start of the defrosting operation is corrected based on the thermo-off, so that the hard-to-melt ice is not generated by the defrosting operation. Since the defrosting operation is performed, the unmelted residue can be reliably prevented. As a result, a decrease in heating capacity can be reliably prevented, and comfort can be improved.

According to the third aspect of the present invention, the rush time is reduced in proportion to the number of times of thermo-off.
Before the hard-to-melt ice occurs, the defrost operation is performed reliably,
The unmelted residue can be more reliably prevented.

[0021]

Embodiments of the present invention will be described below in detail with reference to the drawings.

As shown in FIG. 1, the air conditioner (1
0) includes a refrigerant circuit (20) and a controller (60). The refrigerant circuit (20) includes an outdoor circuit (21), an indoor circuit (22), a liquid-side communication pipe (23), and a gas-side communication pipe (24). The outdoor circuit (21) is connected to the outdoor unit (1
1) is provided. This outdoor unit (11) is provided with an outdoor fan (12). Meanwhile, the indoor circuit (22)
Is provided in the indoor unit (13). This indoor unit (13)
Is provided with an indoor fan (14).

The outdoor circuit (21) includes a compressor (30), a four-way switching valve (33), an outdoor heat exchanger (34), and a receiver (3).
5) and an electric expansion valve (36) as an expansion mechanism are provided. In addition, a bridge circuit (4
0), a liquid side shutoff valve (25), and a gas side shutoff valve (26) are provided. Further, a gas introduction circuit (50) and a pressure equalization circuit (52) are connected to the outdoor circuit (21).

In the outdoor circuit (21), the compressor (3
The discharge port (32) of (0) is connected to the first port of the four-way switching valve (33). A high pressure switch (71) is provided in a pipe connecting the discharge port (32) of the compressor (30) and the four-way switching valve (33). Four-way switching valve (3
The second port of 3) is connected to one end of the outdoor heat exchanger (34). The other end of the outdoor heat exchanger (34) is connected to a bridge circuit (40). The bridge circuit (40) includes a receiver (35), an electric expansion valve (36),
The liquid side stop valve (25) is connected. The suction port (31) of the compressor (30) is connected to the third port of the four-way switching valve (33). The fourth port of the four-way switching valve (33) is connected to the gas side shut-off valve (26).

The bridge circuit (40) is connected to the first pipeline (4
1), the second pipe (42), the third pipe (43), and the fourth pipe (44) are connected in a bridge shape. That is, the outlet end of the first pipe (41) is connected to the outlet end of the second pipe (42), and the inlet end of the second pipe (42) is connected to the third pipe (43).
And the inlet end of the third pipe (43) is connected to the inlet end of the fourth pipe (44), and the outlet end of the fourth pipe (44) is connected to the first pipe (41). Connected to the entrance end of the

Check valves (CV-1, CV-2, CV-1) permitting only the flow of refrigerant from the inlet end to the outlet end are provided in the first to fourth pipes (41) to (44). -3, CV-4).

The other end of the outdoor heat exchanger (34) is connected to the inlet end of the first conduit (41) in the bridge circuit (40) and to the fourth end.
It is connected to the outlet end of the pipe (44). The outlet end of the first conduit (41) and the outlet end of the second conduit (42) in the bridge circuit (40) are connected to the upper end of a receiver (35) formed in a cylindrical container shape. The lower end of the receiver (35) is connected to a bridge circuit (4) via an electric expansion valve (36).
0) at the inlet end of the third conduit (43) and the fourth conduit (4
4) Connected to the inlet end. The inlet end of the second pipe (42) and the outlet end of the third pipe (43) in the bridge circuit (40) are connected to the liquid-side shutoff valve (25).

The indoor circuit (22) is provided with an indoor heat exchanger (37). One end of the indoor circuit (22) is connected to a liquid side closing valve (25) via a liquid side communication pipe (23). The other end of the indoor circuit (22) is connected to a gas-side shut-off valve (26) via a gas-side communication pipe (24). That is,
The liquid side communication pipe (23) and the gas side communication pipe (24) are provided from the outdoor unit (11) to the indoor unit (13). After the installation of the air conditioner (10), the liquid-side stop valve (25) and the gas-side stop valve (26) are always open.

One end of the gas introduction circuit (50) is connected to the receiver (35), and the other end is connected to the suction side of the compressor (30). Specifically, one end of the gas introduction circuit (50) is connected to the upper end of the receiver (35). This is to introduce the gas refrigerant in the receiver (35) into the gas introduction circuit (50).
It is to take in. On the other hand, the other end of the gas introduction circuit (50) is connected between the suction port (31) of the compressor (30) and the four-way switching valve (33). This gas introduction circuit (5
0) is for sending the gas refrigerant of the receiver (35) to the suction port (31) of the compressor (30).

In the middle of the gas introduction circuit (50), an electromagnetic valve (51) is provided. When the solenoid valve (51) is opened and closed, the flow of the gas refrigerant in the gas introduction circuit (50) is interrupted. That is, the solenoid valve (51) forms an opening / closing mechanism.

One end of the pressure equalizing circuit (52) is connected between the solenoid valve (51) and the receiver (35) in the gas introduction circuit (50), and the other end is connected to the compressor in the outdoor circuit (21). It is connected between the discharge port (32) of (30) and the four-way switching valve (33). The equalizing circuit (52) is provided with an equalizing check valve (53) that allows only the flow of the refrigerant from one end to the other end. The pressure equalizing circuit (52) allows the gas refrigerant to escape when the outside temperature rises abnormally while the air conditioner (10) is stopped and the pressure of the receiver (35) becomes too high. To prevent the rupture. Therefore, the refrigerant does not flow through the pressure equalizing circuit (52) during the operation of the air conditioner (10).

The compressor (30) is of a closed type and a high pressure dome type. Specifically, this compressor (30)
A scroll-type compression mechanism and an electric motor for driving the compression mechanism are housed in a cylindrical housing. The refrigerant sucked from the suction port (31) is directly introduced into the compression mechanism. The refrigerant compressed by the compression mechanism is once discharged into the housing and then sent out from the discharge port (32). The illustration of the compression mechanism and the electric motor is omitted.

The electric motor of the compressor (30) is supplied with electric power through an inverter (not shown). When the output frequency of the inverter is changed, the number of revolutions of the motor changes, and the capacity of the compressor changes. That is, the compressor (30) has a variable capacity.

The outdoor heat exchanger (34) constitutes a heat source side heat exchanger. The outdoor heat exchanger (34) is composed of a cross-fin type fin-and-tube heat exchanger. Outdoor air is supplied to the outdoor heat exchanger (34) by the outdoor fan (12). Then, the outdoor heat exchanger (34) exchanges heat between the refrigerant in the refrigerant circuit (20) and the outdoor air.

The indoor heat exchanger (37) constitutes a use side heat exchanger. The indoor heat exchanger (37) is constituted by a cross-fin type fin-and-tube heat exchanger. Indoor air is supplied to the indoor heat exchanger (37) by an indoor fan (14). Then, the indoor heat exchanger (37) exchanges heat between the refrigerant in the refrigerant circuit (20) and the indoor air.

The four-way switching valve (33) has a state where the first port and the second port communicate with each other and the third port and the fourth port communicate with each other (a state shown by a solid line in FIG. 1). The state is switched to a state in which the first port and the fourth port communicate with each other and the second port and the third port communicate with each other (a state shown by a broken line in FIG. 1). By the switching operation of the four-way switching valve (33),
The direction of circulation of the refrigerant in the refrigerant circuit (20) is reversed.

The air conditioner (10) is provided with various temperature sensors. The detected temperature of each temperature sensor is
The data is input to the controller (60) and used for operation control of the air conditioner (10). Specifically, the outdoor unit (1
1) is provided with an outside air temperature sensor (72) for detecting the temperature of outdoor air. The outdoor heat exchanger (34)
An outdoor heat exchanger temperature sensor (73) for detecting the heat transfer tube temperature is provided. A pipe connected to the discharge port (32) of the compressor (30) is provided with a discharge pipe temperature sensor (74) for detecting the temperature of refrigerant discharged from the compressor (30). The indoor unit (13) is provided with an internal air temperature sensor (75) for detecting the temperature of indoor air. The indoor heat exchanger (37) is provided with an indoor heat exchanger temperature sensor (76) for detecting the temperature of the heat transfer tube.

The refrigerant circuit (20) is configured as a so-called accumulation-less circuit. That is, in the general refrigerant circuit (20), an accumulator (gas-liquid separator) is provided on the suction side of the compressor (30), but in the refrigerant circuit (20) according to the present embodiment, the accumulator is omitted. In this way, the configuration is simplified.

The controller (60) includes operation control means, determination means (62) for defrosting operation, and defrosting means (63).
And a correction means (64). The operation control means adjusts the degree of opening of the electric expansion valve (36) based on the temperature detected by each of the temperature sensors (72 to 76), and changes the rotational speed of the electric motor in the compressor (30) to change the compressor speed. It is configured to adjust the capacity. The opening of the electric expansion valve (36) is adjusted mainly based on the temperature detected by the discharge pipe temperature sensor (74).

The determining means (62) counts the duration of the heating operation, and determines whether or not the duration has passed a preset inrush time for starting the defrosting operation. Have been.

The defrosting means (63) performs so-called timer control as to whether or not to perform a defrosting operation. When the determining means (62) determines that the inrush time has elapsed, the defrosting operation is performed. Have been.

The correcting means (64) corrects the judging means (62) so as to shorten only the rush time when the heating operation is turned off within the rush time of the judging means (62). In particular, the correction means (64) is configured to sequentially reduce the rush time as the number of times of the thermostat of the heating operation increases within the rush time of the determination means (62).

The defrosting means (63) is configured to perform so-called integral heating capacity control in addition to timer control. In other words, the defrosting means (63) stores the integrated heating capacity from the start of the heating operation after the end of the defrost operation, and calculates the integrated heating capacity by adding the heating operation time after the defrost operation and the preset expected defrost operation time. The average heating capacity is calculated by dividing the capacity, and when the average heating capacity becomes smaller than the previous average heating capacity, the defrost operation is executed.

-Operation- Next, the operation of the air conditioner (10) will be described.

The air conditioner (10) switches between a cooling operation by a refrigeration cycle operation and a heating operation by a heat pump operation. In the heating operation, a defrosting operation is appropriately performed to perform defrosting (defrosting) of the outdoor heat exchanger (34).

<Cooling Operation> During the cooling operation, the four-way switching valve (33) is switched to the state shown by the solid line in FIG. 1, the electric expansion valve (36) is adjusted to a predetermined opening, and the solenoid valve (51) Is closed. Further, the outdoor fan (12) and the indoor fan (14) are operated. In this state, the refrigerant circulates in the refrigerant circuit (20), and the refrigeration cycle operation is performed using the outdoor heat exchanger (34) as a condenser and the indoor heat exchanger (37) as an evaporator.

Specifically, the discharge port (3) of the compressor (30)
The refrigerant discharged from 2) is sent to the outdoor heat exchanger (34) through the four-way switching valve (33). In the outdoor heat exchanger (34), the refrigerant radiates heat to outdoor air and condenses. The condensed refrigerant flows into the receiver (35) through the first pipe (41) of the bridge circuit (40). The refrigerant flowing out of the receiver (35) is decompressed by the electric expansion valve (36), and then flows from the third pipe (43) of the bridge circuit (40) to the liquid-side communication pipe (2).
It is sent to the indoor heat exchanger (37) through 3).

In the indoor heat exchanger (37), the refrigerant absorbs heat from indoor air and evaporates. In other words, the indoor heat exchanger (3
In 7), the indoor air taken into the indoor unit (13) radiates heat to the refrigerant. Due to this heat radiation, the temperature of the indoor air decreases, and low-temperature conditioned air is generated. The generated conditioned air is supplied indoors from the indoor unit (13) and used for cooling.

The refrigerant evaporated in the indoor heat exchanger (37) flows through the gas side communication pipe (24) and the four-way switching valve (33),
It is sucked into the compressor (30) from the suction port (31). The compressor (30) compresses the sucked refrigerant and discharges the refrigerant again from the discharge port (32). In the refrigerant circuit (20), the refrigerant circulates as described above to perform the refrigeration cycle operation.

During the cooling operation, the controller (60) controls the electric expansion valve (36) and the compressor (30) according to the operation state. That is, the controller (60) adjusts the opening of the electric expansion valve (36) and changes the rotation speed of the electric motor in the compressor (30) based on the detected temperatures of the temperature sensors (72 to 76). To adjust compressor capacity. The opening of the electric expansion valve (36) is adjusted mainly based on the temperature detected by the discharge pipe temperature sensor (74).

<Heating Operation> During the heating operation, the four-way switching valve (33) is switched to the state shown by the broken line in FIG. 1, the electric expansion valve (36) is adjusted to a predetermined opening, and the electromagnetic valve (51) Is closed. Further, the outdoor fan (12) and the indoor fan (14) are operated. In this state, the refrigerant circulates in the refrigerant circuit (20), and the heat pump operation is performed using the indoor heat exchanger (37) as a condenser and the outdoor heat exchanger (34) as an evaporator. The controller (60) controls the electric expansion valve (36) and the compressor (30) in the same manner as in the cooling operation.

Specifically, the refrigerant discharged from the discharge port (32) of the compressor (30) passes through the gas side communication pipe (24) from the four-way switching valve (33), and the indoor heat exchanger (37). ). In the indoor heat exchanger (37), the refrigerant radiates heat to the indoor air and condenses. In other words, in the indoor heat exchanger (37),
Indoor air taken into the indoor unit (13) is heated by the refrigerant. This heating raises the temperature of the indoor air,
Warm conditioned air is produced. The generated conditioned air is supplied indoors from the indoor unit (13) and used for heating.

The refrigerant condensed in the indoor heat exchanger (37) flows into the receiver (35) through the liquid side communication pipe (23) and the second pipe (42) of the bridge circuit (40). The refrigerant flowing out of the receiver (35) is decompressed by the electric expansion valve (36), and then sent to the outdoor heat exchanger (34) through the fourth pipe (44) of the bridge circuit (40). Outdoor heat exchanger (3
In 4), the refrigerant absorbs heat from the outdoor air and evaporates.

The refrigerant evaporated in the outdoor heat exchanger (34) passes through the four-way switching valve (33) and is drawn into the compressor (30) from the suction port (31). The compressor (30) compresses the sucked refrigerant and discharges the refrigerant again from the discharge port (32). In the refrigerant circuit (20), the refrigerant circulates and the heat pump operation is performed as described above.

<Defrosting Operation> As described above, the defrosting operation is performed during the heating operation. This defrosting operation is performed to melt frost attached to the outdoor heat exchanger (34).
The defrosting operation in the air conditioner (10) is performed by a so-called reverse cycle method. That is, during the defrosting operation, the direction of circulation of the refrigerant in the refrigerant circuit (20) is the same as in the refrigeration cycle operation.

First, the refrigerant discharged from the discharge port (32) of the compressor (30) is sent to the outdoor heat exchanger (34) through the four-way switching valve (33). In the outdoor heat exchanger (34), the refrigerant releases heat and condenses. By the heat radiation from this refrigerant,
Frost attached to the outdoor heat exchanger (34) is melted. The condensed refrigerant flows into the receiver (35) through the first pipe (41) of the bridge circuit (40). The refrigerant flowing out of the receiver (35) is decompressed by the electric expansion valve (36), and then flows from the third pipe (43) of the bridge circuit (40) to the liquid-side communication pipe (2).
It is sent to the indoor heat exchanger (37) through 3).

In the indoor heat exchanger (37), the refrigerant absorbs heat from indoor air and evaporates. However, during the defrosting operation, the indoor fan (14) is stopped. This is because when the indoor fan (14) is operated, cool air is blown into the room and the comfort is impaired. The refrigerant evaporated in the indoor heat exchanger (37) flows through the gas side communication pipe (24) and the four-way switching valve (33), and is sucked into the compressor (30) from the suction port (31). The compressor (30) compresses the sucked refrigerant and discharges the refrigerant again from the discharge port (32).

Thereafter, the operation is switched from the defrosting operation to the heat pump operation, and the heat pump operation is restarted.

<Defrost Control> In this defrost control, the case where the defrost means (63) performs timer control of the defrost operation will be described.

First, as shown in FIG. 2, the judgment means (62)
Counts the duration of the heating operation, and determines whether the duration has exceeded the inrush time A set in advance for the start of the defrosting operation. That is, the defrosting operation is performed in principle, for example, when the heating operation continues for 3 hours (rush time A).

When the determining means (62) determines that the rush time A has elapsed, the defrosting means (63) performs the above-described defrosting operation.

On the other hand, the correcting means (64) corrects the judging means (62) so as to shorten only the inrush time A when the heating operation becomes thermo-off F within the inrush time A of the judging means (62). The determination means (62) sets the corrected inrush time B. In particular, the correction means (64) includes the determination means (6
As the number of times that the heating operation becomes thermo-off within the inrush time A of 2) increases, the inrush time A is shortened in order and the corrected inrush time B is set to the determination means (62).

That is, when the temperature of the indoor air reaches the set temperature during the heating operation, the driving of the compressor (30) is stopped while the indoor fan (14) is driven, and the heating operation is stopped, so that the so-called sleep state is established. The thermo-off state is set. Thereafter, when the temperature of the indoor air decreases, the compressor (30) is driven to restart the paused heating operation, and a so-called thermo-on state is set.

In the thermo-on state, the outdoor heat exchanger (34) is cooled by the refrigerant. However, when the thermo-off state is reached, the cooling of the outdoor heat exchanger (34) is stopped, and the outdoor heat exchanger (34) is slightly warmed. Of the ice adhered to the heat transfer tubes of the outdoor heat exchanger (34), the ice on the heat transfer tube surface melts. Become.
Thereafter, when the thermo-on state is reached, the outdoor heat exchanger (34) is cooled again, and the water melted from the ice becomes ice again.

When this melting and icing are repeated, the ice becomes hard ice, and as a result, there remains unmelted after the defrosting operation.

Therefore, according to the present invention, the inrush time A is corrected by the correcting means (64). Specifically, FIG.
For example, if the thermo-off F is performed once within the inrush time A, the inrush time A is shortened by 10 minutes, and a corrected inrush time B1 of 2 hours and 50 minutes is set. Then, when the corrected inrush time B1 has elapsed, the defrost operation is performed.

If two thermo-offs F are performed during the inrush time A, the inrush time A is reduced by 20 minutes, and a corrected inrush time B2 of 2 hours and 40 minutes is set. When the corrected inrush time B2 has elapsed, the defrost operation is performed.

If the thermo-off F is not performed within the inrush time A, the inrush time A is corrected without being corrected.
A 3-hour inrush time A (B3) is set. Then, when the inrush time A has elapsed, the defrost operation is performed.

That is, a value obtained by subtracting a value obtained by multiplying the number of times of thermo-off Y by 10 minutes from the inrush time A is set as the corrected inrush time B (B = A−Y × 10).

-Effects of Embodiment- As described above, according to the present embodiment, the inrush time set in advance for the start of the defrosting operation is corrected based on the thermo-off. The defrosting operation is performed before hard-to-melt ice is generated, so that unmelted residue can be reliably prevented. As a result, a decrease in heating capacity can be reliably prevented, and comfort can be improved.

Further, since the inrush time is shortened in proportion to the number of times of the thermo-off, the defrosting operation is carried out reliably before hard-to-melt ice is generated. it can.

[0072]

In the above embodiment, the inrush time of the defrosting operation is shortened and corrected by the number of times of the thermo-off. However, the shortening time does not necessarily have to be proportional to the number of times of the thermo-off. The number of times may be divided into a plurality of times, and the shortened time may be set for each of the divided times. When the thermostat is turned off, a fixed shortening time may be set regardless of the number of times, and the inrush time may be shortened by the shortening time.

Further, the air conditioner of the present invention is not limited to the refrigerant circuit of the embodiment, and may be a dedicated heating device.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of an air conditioner according to an embodiment.

FIG. 2 is a timing chart showing an operation of defrost control of the air conditioner.

[Explanation of symbols]

 10 Air conditioner 20 Refrigerant circuit 30 Compressor 34 Outdoor heat exchanger 36 Electric expansion valve 37 Indoor heat exchanger 62 Judgment means 63 Defrosting means 64 Correction means

Claims (3)

[Claims] 1. An air conditioner having a refrigerant circuit (20) constituting a vapor compression refrigeration cycle and performing at least a heating operation, wherein the heating operation is continued and an inrush set for starting a defrosting operation is set in advance. An air conditioner characterized by performing a defrosting operation after a lapse of time, and shortening the rush time when the heating operation is turned off within the rush time. 2. An air conditioner comprising a refrigerant circuit (20) in which refrigerant circulates in the order of a compressor (30), a condenser (37), an expansion mechanism (36), and an evaporator (34), and performs at least a heating operation. A determining means (62) for counting the duration of the heating operation and determining whether or not the duration has exceeded a preset inrush time for starting the defrosting operation; ) Determines the elapse of the rush time, the defrosting means (63) for performing the defrosting operation, and the above-mentioned means for shortening only the rushing time when the heating operation is turned off within the rush time of the determining means (62). An air conditioner comprising: a correction unit (64) for correcting the determination unit (62). 3. The correction means (64) according to claim 2, wherein the correction means (64) is configured to sequentially reduce the rush time as the number of times of the heating operation to be thermo-off within the rush time of the determination means (62) increases. An air conditioner, comprising: