JP2018035981A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suitably perform a defrosting operation.SOLUTION: An air conditioner 100 includes: a compressor 1 for compressing a refrigerant; an outdoor heat exchanger 7 for exchanging heat between the refrigerant and outdoor air; an indoor heat exchanger 3 for exchanging heat between the refrigerant and indoor air; decompression means 6 for decompressing the refrigerant; an outside air temperature sensor for measuring an outside air temperature; and control means. When a defrosting operation is performed, the control means changes a defrosting operation completion condition temperature that is used as a threshold value for completion determination of the defrosting operation or set time of the defrosting operation from start to completion of the defrosting operation, on the basis of the outside air temperature.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an air conditioner.

  In general, an air conditioner that performs a heating operation using a heat pump cycle compresses a refrigerant with a compressor during the heating operation, and guides the compressed high-temperature and high-pressure refrigerant to an indoor heat exchanger. The air conditioner heats the indoor air by radiating heat from the refrigerant to the room air by the indoor heat exchanger, and condenses the refrigerant to a low temperature and low pressure state. Thereafter, the air conditioner guides the condensed low-temperature and low-pressure refrigerant to the outdoor heat exchanger via the decompression unit. The air conditioner absorbs heat from the outdoor air to the refrigerant by the outdoor heat exchanger, evaporates the refrigerant, returns it to the compressor as a low-pressure gas refrigerant, and again compresses it by the compressor. By repeating such an operation, the air conditioner heats the room.

  In the process, when the outdoor air has a large amount of retained water, the retained water of the outdoor air becomes dew and adheres to the outdoor heat exchanger. And when the temperature of an outdoor heat exchanger is low, the dew may become frost and block the ventilation path of an outdoor heat exchanger.

  If such a state is left as it is, the outdoor heat exchanger deteriorates the ventilation state, and thereafter, the amount of attached frost increases more and more. As a result, the outdoor heat exchanger greatly reduces the heat exchange efficiency of the outdoor heat exchanger, and the heating performance is also greatly reduced.

  Therefore, in order to prevent such a phenomenon from occurring, the air conditioner has a function of reversing the flow of the refrigerant, causing the high-temperature and high-pressure refrigerant to flow into the outdoor heat exchanger, and removing the attached frost ( Defrosting operation).

  The defrosting operation is started when the temperature of the outdoor heat exchanger is detected, for example, when the temperature of the outdoor heat exchanger becomes equal to or lower than a predetermined value. However, if the frost once adheres to the base of the outdoor heat exchanger or the outdoor unit when the outside air temperature is low, even if the temperature of the outdoor heat exchanger rises above a certain temperature during the defrosting operation, the outdoor heat exchange The frost on the vessel could not be melted. Therefore, the prior art described in Patent Document 1 changes the defrosting operation prohibition time according to the outside air temperature and performs control for suppressing frost formation.

  In recent years, air conditioners are required to further improve heating performance. However, as the heating performance is improved, the outdoor heat exchanger functioning as an evaporator during heating tends to be frosted because its temperature tends to decrease. Therefore, the prior art described in Patent Document 2 changes the temperature used as the threshold value for determining the start of the defrosting operation based on the rotation speed of the compressor so that the defrosting time becomes an appropriate time. The defrosting operation is controlled.

Japanese Patent No. 3879458 JP-A-10-103818

  However, the conventional techniques described in Patent Document 1 and Patent Document 2 fix the temperature of the outdoor heat exchanger that determines the end of the defrosting operation to a constant value regardless of the outside air temperature, as described below. Therefore, when the outdoor temperature is low, there is a problem that the frost of the outdoor heat exchanger may not be completely melted.

  For example, when the next heating operation is started before the outside air temperature is very low and drain water from the defrosting operation is discharged outside the outdoor unit, the air conditioner is The drain water remaining in a portion that tends to be relatively low in temperature (for example, the lower portion of the outdoor unit) may freeze.

  In such a case, the conventional techniques described in Patent Document 1 and Patent Document 2 are freezing even if the freezing progresses and the next defrosting operation is performed when the heating operation is continued for a long time. The state may not be resolved. In the conventional techniques described in Patent Document 1 and Patent Document 2, the drainage of newly generated drain water is hindered by the remaining ice, and the amount of drain water remaining in the dew tray increases. A vicious circle occurs. As a result, the conventional techniques described in Patent Document 1 and Patent Document 2 sometimes fail to melt the frost of the outdoor heat exchanger when the outside air temperature is low.

  In particular, in an air conditioner for cold districts, an outdoor unit is increased in size and a refrigerant circulation rate is increased in order to improve heating capacity. Therefore, especially in air conditioners for cold regions, the temperature of the outdoor heat exchanger that functions as an evaporator during heating is likely to decrease due to pressure loss, and as a result, the frost formation amount of the outdoor heat exchanger is reduced. It is getting more. Therefore, particularly in an air conditioner for cold districts, when the outside air temperature is low, a phenomenon that the frost of the outdoor heat exchanger cannot be completely melted easily occurs.

  Moreover, generally the air conditioner also had the subject that it was desired to shorten defrost time as much as possible.

  The present invention has been made to solve the above-described problems, and has as its main object to provide an air conditioner that suitably performs a defrosting operation.

In order to achieve the above object, the present invention is an air conditioner, which is a compressor that compresses a refrigerant, an outdoor heat exchanger that exchanges heat between the refrigerant and outdoor air, and heat exchange between the refrigerant and indoor air. An indoor heat exchanger, a decompression means for decompressing the refrigerant, an outside temperature sensor for measuring the outside air temperature, and a control means. The control means measures the outside air temperature sensor when performing a defrosting operation. A configuration for changing a defrosting operation end condition temperature used as a defrosting operation end determination threshold value or a defrosting operation set time from the start of the defrosting operation to the end of the operation according to the outside air temperature And
Other means will be described later.

  According to the present invention, the defrosting operation can be suitably performed.

It is a figure which shows the cycle structure of the air conditioner which concerns on Embodiment 1. FIG. 1 is a block diagram illustrating a configuration of a control device according to a first embodiment. It is a flowchart which shows the process sequence of the defrost driving | operation of Embodiment 1. It is a figure which shows the relationship between the external temperature of Embodiment 1, and completion | finish condition temperature of a defrost driving | operation. It is a flowchart which shows the process sequence of the defrost operation of Embodiment 2. FIG. It is a flowchart which shows the process sequence of the defrost driving | operation of Embodiment 3. It is a figure which shows the relationship between the rotational speed of the indoor fan of Embodiment 3, and the starting condition temperature of a defrost operation. It is a figure which shows the relationship between the rotational speed of the compressor of Embodiment 4, and the opening degree of an expansion valve (decompression means). It is a figure which shows the relationship between the rotational speed of the compressor of Embodiment 5, and the rotational speed of an outdoor fan. It is a figure which shows the relationship between the rotational speed of the compressor of Embodiment 5, and the rotational speed of an outdoor fan. It is a flowchart which shows the process sequence of the defrost operation which concerns on the modification 1. It is a figure which shows the relationship between the external temperature which concerns on the modification 1, and the setting time of a defrost driving | operation. It is a flowchart which shows the process sequence of the defrost operation which concerns on the modification 2. It is a figure which shows an example of the temperature distribution of an outdoor unit. It is a figure which shows an example of the drain hole provided in an outdoor unit.

  Hereinafter, an embodiment of the present invention (hereinafter referred to as “the present embodiment”) will be described in detail with reference to the drawings. Each figure is only schematically shown so that the present invention can be fully understood. Therefore, the present invention is not limited to the illustrated example. Moreover, in each figure, the same code | symbol is attached | subjected about the common component and the same component, and those overlapping description is abbreviate | omitted.

[Embodiment 1]
In the first embodiment, even when the outdoor air temperature is low and the amount of frost on the outdoor heat exchanger is large due to snow or the like, the defrosting operation is suitably performed to ensure the frost on the outdoor heat exchanger. The technical idea is to provide an air conditioner for defrosting.

<Cycle structure of air conditioner>
Hereinafter, the cycle configuration of the air conditioner 100 according to the first embodiment will be described with reference to FIG. FIG. 1 is a diagram illustrating a cycle configuration of an air conditioner 100 according to the first embodiment.

As shown in FIG. 1, an air conditioner 100 according to the first embodiment includes a compressor 1, a four-way valve 2, an indoor heat exchanger 3, an indoor fan 4, a decompression unit 6, an outdoor heat exchanger 7, and an outdoor fan 8. And a control device 20.
The compressor 1 is a device that compresses a refrigerant.
The four-way valve 2 is a device that reverses the flow of the refrigerant during the cooling operation and the heating operation.
The indoor heat exchanger 3 is a device that exchanges heat between the refrigerant and indoor air.
The indoor fan 4 is a device that sends indoor air to the indoor heat exchanger.
The decompression means 6 is means for decompressing the refrigerant.
The outdoor heat exchanger 7 is a device that exchanges heat between the refrigerant and the outdoor air.
The outdoor fan 8 is a device that sends outdoor air to the outdoor heat exchanger.
The control device 20 is a device that controls the operation of each device.

  The compressor 1, the decompression means 6, the outdoor heat exchanger 7, and the outdoor fan (propeller fan) 8 are disposed in the outdoor unit 102. The indoor heat exchanger 3, the indoor fan 4, and the control device 20 are disposed in the indoor unit 101.

  The compressor 1 is connected to the four-way valve 2 by a refrigerant pipe. The four-way valve 2 is connected to the outdoor heat exchanger 7 and the indoor heat exchanger 3 by refrigerant piping. The outdoor heat exchanger 7 and the indoor heat exchanger 3 are connected to each other by refrigerant piping via the decompression means 6. The decompression means 6 is constituted by, for example, an electric expansion valve or a capillary tube.

The indoor air temperature sensor 5, the outdoor heat exchanger temperature sensor 9, and the outdoor air temperature sensor 10 are connected to the control device 20 so as to communicate with each other.
The indoor air temperature sensor 5 is a sensor that measures the temperature of indoor air. The indoor air temperature sensor 5 is disposed at a desired location of the indoor unit 101.
The outdoor heat exchanger temperature sensor 9 is a sensor that measures the temperature of the outdoor heat exchanger 7. The outdoor heat exchanger temperature sensor 9 is disposed at a desired location of the outdoor heat exchanger 7.
The outside air temperature sensor 10 is a sensor that measures the temperature of outdoor air (outside air). The outdoor temperature sensor 10 is disposed at a desired location of the outdoor unit 102.

  When performing the cooling operation, the air conditioner 100 discharges the refrigerant from the compressor 1 to the four-way valve 2 and causes the discharged refrigerant to flow along the direction of the broken line arrow in FIG. That is, the air conditioner 100 discharges the refrigerant from the compressor 1 to the four-way valve 2, and uses the discharged refrigerant as the four-way valve 2, the outdoor heat exchanger 7, the decompression means 6, the indoor heat exchanger 3, and the four-way valve 2. In order. Thereafter, the air conditioner 100 returns the refrigerant to the compressor 1.

In the cooling operation, the following processing is performed.
First, the compressor 1 compresses the refrigerant. Thereby, a refrigerant | coolant will be in a high temperature / high pressure state. The compressor 1 discharges a high-temperature and high-pressure refrigerant to the four-way valve 2.
The high-temperature and high-pressure refrigerant discharged to the four-way valve 2 flows into the outdoor heat exchanger 7. The refrigerant flowing into the outdoor heat exchanger 7 is condensed and becomes liquid refrigerant by exchanging heat with outdoor air sent by the outdoor fan 8. The liquid refrigerant passes through the decompression means 6 to become a low-temperature and low-pressure two-phase refrigerant and flows into the indoor heat exchanger 3.
The low-temperature and low-pressure two-phase refrigerant flowing into the indoor heat exchanger 3 exchanges heat with indoor air sent by the indoor fan 4. At this time, the indoor air sent to the indoor heat exchanger 3 is cooled by the low-temperature and low-pressure two-phase refrigerant flowing into the indoor heat exchanger 3 and discharged into the room from the outlet (not shown) of the indoor unit 101. Is done. The air discharged into the room is lower than the temperature of the air at the suction port (not shown) of the indoor unit 101. Therefore, the air conditioner 100 can lower the indoor temperature. Thereby, the air conditioner 100 can cool the room.
The refrigerant heat-exchanged by the indoor heat exchanger 3 returns to the compressor 1 through the four-way valve 2 again. Thereafter, the same processing is repeated during the cooling operation.

  On the other hand, when performing the heating operation, the air conditioner 100 discharges the refrigerant from the compressor 1 to the four-way valve 2 and causes the discharged refrigerant to flow along the direction of the solid line arrow in FIG. That is, the air conditioner 100 discharges refrigerant from the compressor 1 to the four-way valve 2, and discharges the discharged refrigerant to the four-way valve 2, the indoor heat exchanger 3, the decompression means 6, the outdoor heat exchanger 7, and the four-way valve 2. In order. Thereafter, the air conditioner 100 returns the refrigerant to the compressor 1.

In the heating operation, the following processing is performed.
First, the compressor 1 compresses the refrigerant. Thereby, a refrigerant | coolant will be in a high temperature / high pressure state. The compressor 1 discharges a high-temperature and high-pressure refrigerant to the four-way valve 2.
The high-temperature and high-pressure refrigerant discharged to the four-way valve 2 flows into the indoor heat exchanger 3. The refrigerant flowing into the indoor heat exchanger 3 exchanges heat with the indoor air sent by the indoor fan 4. At this time, the indoor air sent to the indoor heat exchanger 3 is heated by the high-temperature and high-pressure refrigerant that has flowed into the indoor heat exchanger 3, and is discharged into the room from the outlet (not shown) of the indoor unit 101. . The air discharged into the room is higher than the temperature of the air at the suction port (not shown) of the indoor unit 101. Therefore, the air conditioner 100 can raise indoor temperature. Thereby, the air conditioner 100 can heat the room.
The refrigerant heat-exchanged in the indoor heat exchanger 3 passes through the decompression means 6 and flows into the outdoor heat exchanger 7 to heat the outdoor heat exchanger 7. Thereafter, the refrigerant returns to the compressor 1 again through the four-way valve 2. Thereafter, the same processing is repeated during the heating operation.

  Such an air conditioner 100 has a function of performing a defrosting operation in order to melt and remove frost attached to the outdoor heat exchanger 7 in a cold time (mainly in winter). In the defrosting operation, the air conditioner 100 discharges the refrigerant from the compressor 1 to the four-way valve 2 in the same manner as in the cooling operation, and the discharged refrigerant flows along the direction of the broken line arrow in FIG. Shed. That is, the air conditioner 100 discharges the refrigerant from the compressor 1 to the four-way valve 2, and uses the discharged refrigerant as the four-way valve 2, the outdoor heat exchanger 7, the decompression means 6, the indoor heat exchanger 3, and the four-way valve 2. In order. Thereafter, the air conditioner 100 returns the refrigerant to the compressor 1. Thereby, since the air conditioner 100 can flow the high-temperature and high-pressure refrigerant into the outdoor heat exchanger 7, it can melt and remove the frost attached to the outdoor heat exchanger 7.

  However, the frost adhering to the outdoor heat exchanger 7 may not be melted unless the defrosting operation is suitably performed. Therefore, the air conditioner 100 according to the first embodiment has a function of suitably performing the defrosting operation under the control of the control device 20 so that the frost attached to the outdoor heat exchanger 7 can be surely melted. ing.

<Configuration of control device>
Hereinafter, the configuration of the control device 20 will be described with reference to FIG. FIG. 2 is a block diagram illustrating a configuration of the control device 20.

As illustrated in FIG. 2, the control device 20 includes a calculation control unit 21, a ROM 22, a RAM 23, and an EEPROM 24.
The arithmetic control means 21 is a control means for controlling the operation of each device.
The ROM 22 is a memory that stores programs for specifying the operation of the arithmetic control unit 21.
The RAM 23 is a memory that temporarily stores data for controlling the operation of each device.
The EEPROM 24 is a non-volatile memory that stores rewritable data (particularly work data and adjustment data that are not preferably erased by power-off) for controlling the operation of each device. .
The control device 20 operates based on programs and data stored in the ROM 22 and the EEPROM 24 using the RAM 23 as a work area.

The control device 20 is communicably connected to the sensors 25 and the actuators 26.
The sensors 25 are, for example, the indoor air temperature sensor 5 (see FIG. 1), the outdoor heat exchanger temperature sensor 9 (see FIG. 1), the outdoor air temperature sensor 10 (see FIG. 1), and the like. The control device 20 performs operation control of the air conditioner 100, speed control of the compressor 1, and the like based on various signals output from the sensors 25.
The actuators 26 are, for example, the compressor 1, the four-way valve 2, the pressure reducing means 6, the motor for the indoor fan 4, the motor for the outdoor fan 8, and the like. The control device 20 outputs a drive signal to the actuators 26 and executes a desired operation of the air conditioner 100.

  Further, the control device 20 is configured to be able to communicate with the remote controller 27 by infrared rays or the like. Thereby, the control device 20 receives an operation / stop instruction of the air conditioner 100, an instruction to control the air flow, data for various arithmetic controls, etc. from the operator via the remote controller 27, This is reflected in device operation control.

<Processing for defrosting operation>
The air conditioner 100 performs the defrosting operation at an arbitrary timing before and after the heating operation or during the heating operation. Hereinafter, with reference to FIG. 3, it demonstrates per the process sequence of the defrost driving | operation of this Embodiment 1. FIG. FIG. 3 is a flowchart illustrating a processing procedure of the defrosting operation according to the first embodiment. In the first embodiment, when performing the defrosting operation, the “defrosting operation end condition temperature Tend” described later is changed according to the outside air temperature To measured by the outside air temperature sensor 10 before the start of the defrosting operation. It is characterized by doing.

  Here, the temperature of the outdoor heat exchanger 7 (hereinafter referred to as “outdoor heat exchange temperature”) Te and the outdoor air temperature To are measured in advance by the outdoor heat exchanger temperature sensor 9 and the outdoor air temperature sensor 10. In the following description, it is assumed that the outdoor heat exchange temperature Te and the outdoor air temperature To are stored in the RAM 23 in advance.

  The “defrosting operation start condition temperature Tst” to be described later means a temperature used as a threshold value for determining the start of the defrosting operation. In the first embodiment, the defrosting operation start condition temperature Tst is assumed to be set in advance to a predetermined temperature.

  The “defrosting operation end condition temperature Tend” to be described later means a temperature used as a threshold value for determining whether the defrosting operation is finished. In the first embodiment, the end condition temperature Tend of the defrosting operation is calculated based on the following formula 1 according to the outside air temperature To measured in advance by the outside air temperature sensor 10 (see FIG. 1).

As shown in FIG. 3, the arithmetic control means 21 (see FIG. 2) of the air conditioner 100 determines whether the defrosting prohibition time has passed before or after the heating operation or during the heating operation. (Step S105).
When it is determined in step S105 that the defrosting operation prohibition time has not elapsed (in the case of “No”), the arithmetic control unit 21 periodically repeats the determination process in step S105. And when it determines with the determination of step S105 having passed the prohibition time of defrost operation (in the case of "Yes"), the calculation control means 21 is the outdoor heat exchanger temperature measured beforehand from RAM23. Te and the outside air temperature To are read (step S110). Here, the outdoor heat exchange temperature Te and the outside air temperature To are temperatures before the start of the defrosting operation.

  And the calculation control means 21 determines whether the outdoor heat exchanger temperature Te before the start of a defrost operation is below the start condition temperature Tst of a defrost operation (step S115).

When it is determined in step S115 that the outdoor heat exchange temperature Te before the start of the defrosting operation is not equal to or lower than the start condition temperature Tst of the defrosting operation (in the case of “No”), the arithmetic control unit 21 performs the step The determination process of S115 is periodically repeated. When it is determined in step S115 that the outdoor heat exchange temperature Te before the start of the defrosting operation is equal to or lower than the defrosting operation start temperature Tst (in the case of “Yes”), the arithmetic control unit 21. Calculates an end condition temperature Tend of the defrosting operation based on the following equation 1 (step S120).
Tend = A · To + B (1)

In the above-described equation 1, A and B are arbitrary constants set according to the operation.
The constant “A” is set to a value of A <0 so that the end condition temperature Tend of the defrosting operation becomes higher as the outside air temperature To before the start of the defrosting operation is lower.

  An upper limit value and a lower limit value are set in advance for the end condition temperature Tend of the defrosting operation. When the value calculated by the above equation 1 exceeds the upper limit value, the arithmetic control unit 21 sets the defrosting operation end condition temperature Tend to the upper limit value. Further, when the value calculated by the above-described equation 1 is lower than the lower limit value, the arithmetic control unit 21 sets the defrosting operation end condition temperature Tend to the lower limit value.

  Here, FIG. 4 shows the relationship between the outside air temperature To in the defrosting operation of Embodiment 1 and the end condition temperature Tend of the defrosting operation. FIG. 4 is a diagram illustrating a relationship between the outside air temperature To and the end condition temperature Tend of the defrosting operation according to the first embodiment. In FIG. 4, the outside temperature when the value calculated by Equation 1 exceeds the upper limit value becomes a value that matches the upper limit value is the temperature T2, and the value calculated by Equation 1 exceeds the lower limit value. The outside air temperature at which the value coincides with the lower limit value is shown as temperature T1 (where T2 <T1).

As shown in FIG. 4, when the outside air temperature To before the start of the defrosting operation is equal to or higher than the temperature T2 and equal to or lower than the temperature T1 (however, T2 <T1), the arithmetic control unit 21 performs the defrosting operation. The end condition temperature Tend is set to a value calculated based on Equation 1 described above. Thereby, the termination condition temperature Tend of the defrosting operation is set to a value that the outside air temperature To gradually decreases from the temperature T2 to the temperature T1. That is, the end condition temperature Tend of the defrosting operation is set to be higher as the outside air temperature To is lower.
On the other hand, when the outside air temperature To before the start of the defrosting operation is lower than the temperature T2, the arithmetic control unit 21 sets the end condition temperature Tend of the defrosting operation to the upper limit value. That is, when the outside air temperature To becomes equal to or lower than the temperature T2, the defrosting operation end condition temperature Tend becomes constant at the upper limit value.
Further, when the outside air temperature To before the start of the defrosting operation is higher than the temperature T1, the calculation control unit 21 sets the defrosting operation end condition temperature Tend to the lower limit value. That is, when the outside air temperature To becomes equal to or higher than the temperature T1, the defrosting operation end condition temperature Tend becomes constant at the lower limit value.

In addition, the lower the outside air temperature To before the start of the defrosting operation, the higher the value of the defrosting operation end condition temperature Tend is set so that the frost attached to the outdoor heat exchanger 7 is difficult to melt. This is because the frost is surely melted.
Conversely, the higher the outside air temperature To before the start of the defrosting operation is, the lower the defrosting operation end condition temperature Tend is set because the frost attached to the outdoor heat exchanger 7 is more easily melted. This is because the frost can be reliably melted in a short defrosting time. That is, it is to prevent the defrosting time from becoming too long.

In addition, the upper limit value is set for the end condition temperature Tend of the defrosting operation, and the outdoor heat exchange temperature Te increases as the defrosting operation continues even though the frost of the outdoor heat exchanger 7 has melted. This is to prevent it from passing.
Moreover, the reason why the lower limit value is set for the end condition temperature Tend of the defrosting operation is to shorten the defrosting time by setting the lowest temperature at which the frost of the outdoor heat exchanger 7 can be surely melted. is there.

  Returning to FIG. 3, after step S <b> 120, the arithmetic control unit 21 controls each device of the air conditioner 100 and starts the defrosting operation of the outdoor unit 102 (step S <b> 125). Then, the arithmetic control unit 21 determines whether or not the defrost time is equal to or longer than a preset time (step S130). Here, the “defrosting time” means an elapsed time from the start of the defrosting operation to that point.

  When it is determined in step S130 that the defrost time is not equal to or longer than the set time (in the case of “No”), the arithmetic control unit 21 determines that the outdoor heat exchange temperature Te at that time is the defrost operation end condition. It is determined whether or not the temperature is Tend or higher (step S135). On the other hand, when it is determined that the defrost time is equal to or longer than the set time (in the case of “Yes”), the process proceeds to step S140.

  When it is determined in step S135 that the outdoor heat exchange temperature Te at that time is not equal to or higher than the defrosting operation end condition temperature Tend (in the case of “No”), the process returns to step S130. On the other hand, when it is determined that the outdoor heat exchange temperature Te at that time is equal to or higher than the defrosting operation end condition temperature Tend (in the case of “Yes”), the process proceeds to step S140.

  If the determination in step S130 or the determination in step S135 is “Yes”, the arithmetic control unit 21 ends the defrosting operation of the outdoor unit 102 (step S140). Thereby, a series of routine processing ends.

  In the first embodiment, the reason for calculating the end condition temperature Tend of the defrosting operation before the start of the defrosting operation, not during the defrosting operation, is as follows. As described below, the outdoor heat exchanger 7 This is to prevent the occurrence of a phenomenon in which the frost attached to the glass cannot be completely melted.

That is, for example, once the defrosting operation is started, the outdoor heat exchange temperature Te rises, and the outside air temperature To measured by the outside air temperature sensor 10 also rises due to this influence. Although the temperature of each part rises when the defrosting operation is started, the outdoor heat exchanger 7 has a part where the temperature rise is slow (for example, a lower part of the outdoor heat exchanger 7).
And when the end condition temperature Tend of a defrost operation is calculated during execution of a defrost operation, the temperature is calculated according to the outdoor temperature To after a raise. Therefore, there is a possibility that the temperature becomes a temperature at which the frost attached to the portion where the temperature rise of the outdoor heat exchanger 7 is slow (for example, the lower portion of the outdoor heat exchanger 7) cannot be sufficiently melted. is there. Therefore, when the end condition temperature Tend of the defrosting operation is calculated during the defrosting operation, there is a possibility that a phenomenon that the frost attached to the outdoor heat exchanger 7 cannot be completely melted may occur.
On the other hand, when the end condition temperature Tend of the defrosting operation is calculated before the start of the defrosting operation as in the first embodiment, the temperature is calculated according to the outside air temperature To before the increase. Therefore, the temperature becomes a temperature at which the frost attached to a portion where the temperature rise of the outdoor heat exchanger 7 is slow (for example, the lower portion of the outdoor heat exchanger 7) can be sufficiently melted. Therefore, when the end condition temperature Tend of the defrosting operation is calculated before the start of the defrosting operation as in the first embodiment, it is possible to prevent the phenomenon that the frost attached to the outdoor heat exchanger 7 cannot be completely melted. Can do.

  In such an air conditioner 100 according to the first embodiment, the temperature of the part where the temperature rise of the outdoor heat exchanger 7 is slow (for example, the lower part of the outdoor heat exchanger 7) is sufficient for the frost at that part. The defrosting operation can be continued even after the temperature rises to a temperature at which it can be completely dissolved. Therefore, the air conditioner 100 ensures that the frost of the outdoor heat exchanger 7 is generated even when, for example, the outside air temperature To is extremely low and the amount of frost adhering to a site where frost is difficult to melt is large. Can be melted. The “part where frost hardly melts” refers to, for example, a lower portion of the outdoor heat exchanger 7 or a base portion of the outdoor unit 102 on which the outdoor heat exchanger 7 is placed.

  As mentioned above, according to the air conditioner 100 which concerns on this Embodiment 1, a defrost operation can be performed suitably and, as a result, the frost of the outdoor heat exchanger 7 can be melt | dissolved reliably.

[Embodiment 2]
Embodiment 1 described above is characterized in that, when performing the defrosting operation, the end condition temperature Tend of the defrosting operation is changed according to the outside air temperature To before the start of the defrosting operation.
In contrast, in the second embodiment, when the defrosting operation is performed, in addition to the outdoor air temperature To before the start of the defrosting operation, the temperature of the outdoor heat exchanger 7 before the start of the defrosting operation (the outdoor heat exchange temperature) Te) and the end condition temperature Tend of the defrosting operation are changed according to the set value of the rotational speed N of the indoor fan 4.

  Hereinafter, with reference to FIG. 5, it demonstrates per the process sequence of the defrost driving | operation of this Embodiment 2. FIG. FIG. 5 is a flowchart illustrating a processing procedure of the defrosting operation according to the second embodiment. Here, the processing procedure different from that of the first embodiment will be mainly described, and detailed description of the processing procedure similar to that of the first embodiment will be omitted.

  As shown in FIG. 5, the processing procedure of the defrosting operation of the second embodiment is a step instead of the processing of steps S110 and S120 when compared with the processing procedure of the defrosting operation of the first embodiment (see FIG. 3). The difference is that the processing of S110a and S120a is executed.

In step S110a, the following processing is executed.
That is, in step S110a, when it is determined in step S105 that the defrosting operation prohibition time has elapsed (in the case of “Yes”), the arithmetic control unit 21 is measured in advance from the RAM 23. The outdoor heat exchange temperature Te, the outdoor air temperature To, and the set value of the rotational speed N of the indoor fan 4 are read. Here, the outdoor heat exchange temperature Te and the outside air temperature To are temperatures before the start of the defrosting operation. The “set value of the rotational speed N of the indoor fan 4” means the set wind speed of the indoor fan 4.

In step S120a, the following processing is executed.
That is, in step S120a, when it is determined in step S115 that the outdoor heat exchange temperature Te is equal to or lower than the defrosting operation start condition temperature Tst (in the case of “Yes”), the arithmetic control unit 21 Based on Equation 2, the defrosting operation end condition temperature Tend is calculated.
Tend = a1 · To + b1 · Te + c1 · N + d1 (2)

In Equation 2 above, a1, b1, c1, and d1 are arbitrary constants set in accordance with the operation.
The constant “a1” is set to a1 <0 so that the end condition temperature Tend of the defrosting operation becomes higher as the outside air temperature To before the start of the defrosting operation becomes lower.
The constant “b1” is set to a value of b1 <0 so that the end condition temperature Tend of the defrosting operation becomes higher as the outdoor heat exchange temperature Te before the start of the defrosting operation is lower.
The constant “c1” is set to a value of c1> 0 so that the defrosting operation end condition temperature Tend increases as the set value of the rotational speed N of the indoor fan 4 (the set wind speed of the indoor fan 4) increases. Is set.

  An upper limit value and a lower limit value are set in advance for the end condition temperature Tend of the defrosting operation. When the value calculated by Equation 2 described above exceeds the upper limit value, the arithmetic control unit 21 sets the defrosting operation end condition temperature Tend to the upper limit value. Moreover, when the value calculated by the above-described Expression 2 is lower than the lower limit value, the arithmetic control unit 21 sets the defrosting operation end condition temperature Tend to the lower limit value. The relationship between the outdoor air temperature To in the defrosting operation of the second embodiment and the end condition temperature Tend of the defrosting operation is the same as the outdoor heat exchange temperature Te and the room in the pattern (see FIG. 4) in the defrosting operation of the first embodiment. The pattern varies according to the set value of the rotational speed N of the fan 4.

  In the second embodiment, in step S135, the calculation control means 21 uses the defrosting operation end condition temperature Tend calculated based on the above-described equation 2 to determine the outdoor heat exchange temperature Te at that time. It is determined whether or not the defrosting operation end condition temperature Tend or higher.

  In the second embodiment, the end condition temperature Tend of the defrosting operation can be set to a more appropriate temperature than the first embodiment. Therefore, the second embodiment can obtain the following effects.

  For example, when the outdoor air temperature To before the start of the defrosting operation is relatively low, or when the outdoor heat exchange temperature Te before the start of the defrosting operation is relatively low, the set value (the indoor fan 4) of the rotational speed N of the indoor fan 4 The case where the set wind speed (4) is relatively fast is predicted to be a case where the amount of frost formation in the outdoor heat exchanger 7 is relatively large. In the second embodiment, when the frosting amount of the outdoor heat exchanger 7 is large, the defrosting operation end condition temperature Tend is set to a temperature higher than that of the first embodiment, whereby the frost of the outdoor heat exchanger 7 is reduced. Can be surely melted.

  On the contrary, when the outside air temperature To before the start of the defrosting operation is not so low, or when the heat exchange temperature Te before the start of the defrosting operation is not so low, the set value of the rotational speed N of the indoor fan 4 ( The case where the set wind speed of the indoor fan 4 is not so fast is predicted to be a case where the amount of frost formation in the outdoor heat exchanger 7 is small. In the second embodiment, when the amount of frost formation in the outdoor heat exchanger 7 is small, the defrosting operation end condition temperature Tend is set to a temperature lower than that in the first embodiment, whereby the frost of the outdoor heat exchanger 7 is reduced. The defrosting time can be shortened while melting reliably.

As described above, according to the second embodiment, the defrosting operation can be suitably performed as in the first embodiment, and as a result, the frost in the outdoor heat exchanger 7 can be reliably melted.
Moreover, according to the second embodiment, the end condition temperature Tend of the defrosting operation can be set to a more appropriate temperature than in the first embodiment.

[Embodiment 3]
In addition to suitably performing the defrosting operation, the third embodiment also has a technical idea of providing an air conditioner that shortens the defrosting time depending on the operation state during the heating operation.

Embodiment 1 described above is characterized in that, when performing the defrosting operation, the end condition temperature Tend of the defrosting operation is changed according to the outside air temperature To before the start of the defrosting operation.
In contrast, in the third embodiment, when performing the defrosting operation, the start of the defrosting operation is performed according to the outside air temperature To before the start of the defrosting operation and the set value of the rotation speed N of the indoor fan 4. The condition temperature Tst is changed.

  Hereinafter, with reference to FIG. 6, it demonstrates per the process sequence of the defrost driving | operation of this Embodiment 3. FIG. FIG. 6 is a flowchart illustrating a processing procedure of the defrosting operation according to the third embodiment. Here, the processing procedure different from that of the first embodiment will be mainly described, and detailed description of the processing procedure similar to that of the first embodiment will be omitted.

  As shown in FIG. 6, the processing procedure of the defrosting operation of the third embodiment is compared with the processing procedure of the defrosting operation of the first embodiment (see FIG. 3), instead of the processing of step S110, step S110a, The difference is that the process of S111 is executed and the process of step S120 is deleted. The processing procedure of the defrosting operation of the third embodiment is also different in that the defrosting operation end condition temperature Tend used in the process of step S135 is set in advance to a desired value.

In step S110a, the following processing is executed.
That is, in step S110a, when it is determined in step S105 that the defrosting operation prohibition time has elapsed (in the case of “Yes”), the arithmetic control unit 21 is measured in advance from the RAM 23. The outdoor heat exchange temperature Te, the outdoor air temperature To, and the set value of the rotational speed N of the indoor fan 4 are read. Here, the outdoor heat exchange temperature Te and the outside air temperature To are temperatures before the start of the defrosting operation. The “set value of the rotational speed N of the indoor fan 4” means the set wind speed of the indoor fan 4.

In step S111, the following processing is executed.
That is, in step S111, the arithmetic control unit 21 calculates the defrosting operation start condition temperature Tst based on the following Equation 3.
Tst = a2 · To + b2 · N + c2 (3)

In Equation 3 above, a2, b2, and c2 are arbitrary constants set according to the operation.
The constant “a2” is set to a2> 0 such that the lower the outside air temperature To before the start of the defrosting operation is, the lower the start condition temperature Tst of the defrosting operation is.
The constant “b2” is set to a value of b2 <0 so that the defrosting operation start condition temperature Tst becomes lower as the set value of the rotational speed N of the indoor fan 4 (the set wind speed of the indoor fan 4) is faster. Is set.

  Here, FIG. 7 shows the relationship between the set value of the rotational speed N of the indoor fan 4 (the set wind speed of the indoor fan 4) in the defrosting operation of the third embodiment and the start condition temperature Tst of the defrosting operation. FIG. 7 is a diagram showing the relationship between the set value of the rotational speed N of the indoor fan 4 of the third embodiment (the set wind speed of the indoor fan 4) and the start condition temperature Tst of the defrosting operation using the outside air temperature To as a parameter. is there.

  In FIG. 7, the solid lines of temperatures To1, To2, and To3 represent different outside air temperatures To that are the defrosting operation start conditions, and have a relationship of To1> To2> To3. Although the outside air temperature To actually changes continuously, the processing procedure of the defrosting operation is the same. The defrosting operation is started when the outdoor heat exchange temperature Te falls below the solid line corresponding to each start condition shown in FIG.

  As shown in FIG. 7, the arithmetic control unit 21 removes the defrosting operation starting condition temperature Tst so that the set value of the rotational speed N of the indoor fan 4 (the set wind speed of the indoor fan 4) increases. The start condition temperature Tst for the frost operation is set. In other words, the arithmetic control unit 21 performs the defrosting operation so that the defrosting operation start condition temperature Tst increases as the set value of the rotational speed N of the indoor fan 4 (the set wind speed of the indoor fan 4) decreases. A start condition temperature Tst is set.

The reason why the start condition temperature Tst of the defrosting operation is set as described above is as follows.
For example, when the outdoor air temperature To is the same temperature, even if the amount of frost adhering to the outdoor heat exchanger 7 is the same, the set value of the rotational speed N of the indoor fan 4 (the set wind speed of the indoor fan 4). ) Becomes faster, the lower the evaporation temperature of the refrigerant. Conversely, the lower the set value of the rotational speed N of the indoor fan 4 (the set wind speed of the indoor fan 4), the higher the evaporation temperature of the refrigerant.
Therefore, if the air conditioner 100 does not perform the defrosting operation at a lower outdoor heat exchange temperature Te as the set value of the rotational speed N of the indoor fan 4 (the set air speed of the indoor fan 4) becomes faster, the amount of frost formation The defrosting operation is started while there is little. The air conditioner 100 sets the defrosting operation start temperature Tst as described above so as not to cause unnecessary increase in power consumption and unpleasant feeling due to a decrease in room temperature. Further, if the air conditioner 100 does not perform the defrosting operation at a higher outdoor heat exchange temperature Te as the set value of the rotational speed N of the indoor fan 4 (the set air speed of the indoor fan 4) becomes slower, the amount of frost formation is increased. Becomes excessive, and it takes a long time to defrost. The air conditioner 100 sets the defrosting operation start condition temperature Tst as described above so as not to cause an unnecessary increase in power consumption due to this and an uncomfortable feeling due to a decrease in indoor temperature.

The prior art described in Patent Document 2 has the following problems.
For example, in the inverter model, while the temperature difference between the set temperature of the remote controller and the room temperature is large, the compressor performs a defrosting operation at a high rotation speed. Thereafter, when the temperature difference between the set temperature of the remote controller and the room temperature becomes small, the rotational speed of the compressor decreases. The prior art described in Patent Document 2 changes the temperature used as a threshold value for determining the start of the defrosting operation (starting temperature of the defrosting operation) based on the rotation speed of the compressor. However, the rotational speed of the compressor varies greatly. Therefore, the conventional technique described in Patent Document 2 has a problem that it is difficult to determine the start of the defrosting operation and it is difficult to control the start of the defrosting operation.

  On the other hand, the air conditioner 100 according to the third embodiment is defrosted because the set value of the rotational speed N of the indoor fan 4 (the set wind speed of the indoor fan 4) is stable at the wind speed set by the remote controller. There is an advantage that it is easy to determine the start of operation and it is easy to control the start of the defrosting operation.

  Returning to FIG. 6, in the third embodiment, in step S <b> 115, the calculation control means 21 removes the outdoor heat exchange temperature Te using the defrosting operation start condition temperature Tst calculated based on Equation 3 described above. It is determined whether the temperature is equal to or lower than the start condition temperature Tst of the frost operation.

  When it is determined in step S115 that the outdoor heat exchange temperature Te is not lower than the defrosting operation start condition temperature Tst (in the case of “No”), the arithmetic control unit 21 periodically performs the determination process in step S115. Repeat. When it is determined in step S115 that the outdoor heat exchange temperature Te is equal to or lower than the defrosting operation start condition temperature Tst (in the case of “Yes”), the arithmetic control unit 21 determines that the air conditioner 100 Each device is controlled to start the defrosting operation of the outdoor unit 102 (step S125).

  In the third embodiment, in step S135, the calculation control means 21 uses the defrosting operation end condition temperature Tend preset to a desired value, and the outdoor heat exchange temperature Te at that time is defrosted. It is determined whether the temperature is equal to or higher than the operation end condition temperature Tend.

  Such Embodiment 3 can start the defrosting operation at a suitable timing. Therefore, the defrosting operation can be suitably performed, and as a result, the frost of the outdoor heat exchanger 7 can be surely melted.

  As described above, according to the third embodiment, the defrosting operation can be suitably performed, and as a result, the frost of the outdoor heat exchanger 7 can be reliably melted.

[Embodiment 4]
In addition to suitably performing the defrosting operation, the fourth embodiment also has a technical idea of providing an air conditioner that shortens the defrosting time depending on the operation state during the heating operation.

  In the fourth embodiment, when the rotational speed of the compressor 1 is increased to a set value Nset (see FIG. 8) or more during the defrosting operation, the opening degree of the expansion valve that is the decompression means 6 is opened in the direction from the initial value. It is characterized by expansion.

  Hereinafter, the processing procedure of the defrosting operation of the fourth embodiment will be described with reference to FIG. FIG. 8 is a diagram illustrating the relationship between the rotational speed of the compressor 1 of the fourth embodiment and the opening of the expansion valve (decompression unit). Here, the decompression means 6 will be described as being configured by an expansion valve. FIG. 8 shows the relationship between the defrosting time and the rotational speed of the compressor 1 on the upper side, and shows the relationship between the defrosting time and the opening of the expansion valve 6 on the lower side.

  In FIG. 8, an alternate long and short dash line Lold indicates the opening degree of the expansion valve in the air conditioner of the comparative example corresponding to the related art. On the other hand, the solid line Lnew indicates the opening degree of the expansion valve 6 in the air conditioner 100 of the fourth embodiment.

  Further, in FIG. 8, the set value Nset indicates the value of the rotational speed of the compressor 1 that serves as a guide between the first half period and the second half period in the defrosting operation. Here, the period from the start of the defrosting operation until the rotation speed of the compressor 1 reaches the set value Nset is defined as the first half period of the defrosting operation, and the rotation speed of the compressor 1 becomes equal to or higher than the set value Nset. The subsequent period will be described as the latter half of the defrosting operation.

  Hereinafter, in order to explain the operation of the air conditioner 100 of the fourth embodiment in an easy-to-understand manner, first, the operation of the air conditioner of the comparative example will be described, and then the operation of the air conditioner 100 of the fourth embodiment will be described. explain.

First, the operation of the air conditioner of the comparative example will be described.
When the air conditioner of the comparative example starts the defrosting operation, the rotational speed of the compressor is increased stepwise. In the whole period of the defrosting operation, the air conditioner of the comparative example maintains the opening degree of the expansion valve (see the alternate long and short dash line Lold) at a constant value. In the air conditioner of such a comparative example, the opening degree of the expansion valve is set to a value larger than the opening degree of the expansion valve 6 in the air conditioner 100 of the fourth embodiment in the first half of the defrosting operation. ing. Moreover, the air conditioner of the comparative example sets the opening degree of the expansion valve to a value smaller than the opening degree of the expansion valve 6 in the air conditioner 100 of the fourth embodiment in the latter half of the defrosting operation. Yes.

Next, operation | movement of the air conditioner 100 of this Embodiment 4 is demonstrated.
The air conditioner 100 of the fourth embodiment increases the rotational speed of the compressor 1 stepwise when the defrosting operation is started. And the air conditioner 100 of this Embodiment 4 has expanded the opening degree of the expansion valve 6 according to the rotational speed of the compressor 1. FIG. In the air conditioner 100 of the fourth embodiment, the opening degree of the expansion valve 6 is set to a value smaller than the opening degree of the expansion valve 6 in the air conditioner of the comparative example in the first half of the defrosting operation. doing. Moreover, the air conditioner 100 of this Embodiment 4 sets the opening degree of the expansion valve 6 to a larger value than the opening degree of the expansion valve 6 in the air conditioner of a comparative example in the second half period of the defrosting operation. ing.

  Hereinafter, the advantages of the air conditioner 100 of the fourth embodiment will be described in comparison with the disadvantages of the air conditioner of the comparative example.

In the first half of the defrosting operation, it is desired to increase the outdoor heat exchange temperature Te quickly in a short time to obtain sufficient defrosting performance.
As described above, in the air conditioner of the comparative example, the opening degree of the expansion valve is set to a value larger than the opening degree of the expansion valve 6 in the air conditioner 100 of the fourth embodiment in the first half of the defrosting operation. It is set. Therefore, in the air conditioner of the comparative example, the internal pressure becomes lower than that of the air conditioner 100 of the fourth embodiment in the first half of the defrosting operation, and as a result, the discharge gas discharged from the compressor The temperature rise is low. Therefore, the air conditioner of the comparative example has a disadvantage that it cannot obtain sufficient defrosting performance during the first half of the defrosting operation, and as a result, the defrosting time is prolonged.
On the other hand, as described above, in the air conditioner 100 of the fourth embodiment, during the first half of the defrosting operation, the opening degree of the expansion valve 6 is set to be larger than the opening degree of the expansion valve 6 in the air conditioner of the comparative example. Also set to a small value. Therefore, in the air conditioner 100 of the fourth embodiment, in the first half of the defrosting operation, the internal pressure becomes higher than that of the air conditioner of the comparative example, and as a result, the discharged gas discharged from the compressor 1 The temperature rises at a high level. Therefore, the air conditioner 100 of the fourth embodiment has an advantage that it can obtain sufficient defrosting performance in the first half of the defrosting operation, and as a result, the defrosting time can be shortened. .

Moreover, the air conditioner of the comparative example sets the opening degree of the expansion valve to a value smaller than the opening degree of the expansion valve 6 in the air conditioner 100 of the fourth embodiment in the latter half of the defrosting operation. Yes. Therefore, in the air conditioner of the comparative example, the internal pressure becomes higher than that of the air conditioner 100 of the fourth embodiment in the latter half of the defrosting operation, and as a result, the discharge gas discharged from the compressor The temperature rises to a high level. Such an air conditioner of the comparative example excessively increases the temperature of the discharge gas during the latter half of the defrosting operation. Therefore, the air conditioner of the comparative example has a disadvantage in that noise (refrigerant sound) increases and energy loss increases during the latter half of the defrosting operation.
On the other hand, as described above, in the air conditioner 100 of the fourth embodiment, during the latter half of the defrosting operation, the opening degree of the expansion valve 6 is set to be larger than the opening degree of the expansion valve 6 in the air conditioner of the comparative example. Is also set to a large value. Therefore, in the air conditioner 100 of the fourth embodiment, the internal pressure becomes lower than that of the air conditioner of the comparative example in the second half of the defrosting operation, and as a result, the discharged gas discharged from the compressor 1 The temperature rise is low. Such an air conditioner 100 according to the fourth embodiment can suppress the temperature of the discharge gas from being excessively raised during the latter half of the defrosting operation. Therefore, the air conditioner 100 of the fourth embodiment has an advantage that it is possible to suppress an increase in noise (refrigerant sound) and an increase in energy loss during the latter half of the defrosting operation.

  Such an air conditioner 100 of the fourth embodiment can suitably perform the defrosting operation, and as a result, can reliably melt the frost of the outdoor heat exchanger 7.

  In the example shown in FIG. 8, the opening degree of the expansion valve 6 is changed in two stages. However, the opening degree of the expansion valve 6 may be changed in multiple stages or gradually depending on the rotational speed of the compressor 1.

As described above, according to the fourth embodiment, the defrosting operation can be suitably performed, and as a result, the frost of the outdoor heat exchanger 7 can be reliably melted.
Moreover, according to the second embodiment, sufficient defrosting performance can be obtained in the first half of the defrosting operation, and as a result, the defrosting time can be shortened. Moreover, increase in noise (refrigerant sound) and increase in energy loss can be suppressed during the latter half of the defrosting operation.

[Embodiment 5]
The fifth embodiment drives the outdoor fan 8 during the defrosting operation when the defrosting operation is performed and the outside air temperature To before the start of the defrosting operation is lower than the set value. It is characterized by that.
Alternatively, in the fifth embodiment, when the defrosting operation is performed and the outside air temperature To before the start of the defrosting operation is lower than the set value, the heating operation is performed after the defrosting operation is finished. It is characterized in that the outdoor fan 8 is driven within a period until the start.

  Hereinafter, with reference to FIG.9 and FIG.10, it demonstrates per the process sequence of the defrost operation of this Embodiment 5. FIG. 9 and 10 are diagrams showing the relationship between the rotational speed of the compressor 1 and the rotational speed of the outdoor fan 8 according to the fifth embodiment.

  The air conditioner 100 stops the outdoor fan 8 in order to melt frost early during the defrosting operation. Thereby, the air conditioner 100 raises the temperature of the outdoor heat exchanger 7. However, if the temperature of the outdoor heat exchanger 7 rises too much, a large amount of steam is generated from the outdoor heat exchanger 7, so that the steam becomes conspicuous and is not preferable in terms of appearance.

Therefore, the fifth embodiment controls the temperature rise of the outdoor heat exchanger 7 so that a large amount of steam is not generated. 9 and 10 show an example of the control.
For example, in the control example shown in FIG. 9, the air conditioner 100 stops the outdoor fan 8 at the start of the defrosting operation, and the outdoor fan during the defrosting operation (for example, the latter half of the defrosting operation). 8 is driven.
Further, in the control example shown in FIG. 10, the air conditioner 100 stops the outdoor fan 8 at the start of the defrosting operation, and ends the defrosting operation before starting the heating operation ( The outdoor fan 8 is driven within the pressure balance time).
These controls are performed when the defrosting operation is performed and when the outside air temperature To before the start of the defrosting operation is lower than the set value.

Such Embodiment 5 can reduce the amount of steam generated from the outdoor heat exchanger 7 while suitably performing the defrosting operation, and can make the steam inconspicuous.
The control example shown in FIG. 9 can shorten the period (pressure balance time) from the end of the defrosting operation to the start of the heating operation, compared to the control example shown in FIG. It is preferable to the control example shown.

  As described above, according to the fifth embodiment, it is possible to reduce the amount of steam generated from the outdoor heat exchanger 7 while suitably performing the defrosting operation.

  The present invention is not limited to the above-described embodiment, and various changes and modifications can be made without departing from the gist of the present invention.

The present invention is not limited to the above-described embodiment, and includes various modifications. For example, the above-described embodiment has been described in detail for easy understanding of the present invention, and is not necessarily limited to one having all the configurations described. In addition, a part of the configuration of the embodiment can be replaced with another configuration, and another configuration can be added to the configuration of the embodiment. Moreover, it is possible to add / delete / replace other configurations for a part of each configuration.
Hereinafter, an example of a modification will be described.

[Modification 1]
For example, in Embodiment 1 described above, the air conditioner 100 changes the end condition temperature Tend of the defrosting operation according to the outside air temperature To. However, for example, as shown in FIG. 11, the air conditioner 100 changes the set time of the defrosting operation (that is, the time from the start of the defrosting operation to the end) according to the outside air temperature To. It may be. FIG. 11 is a flowchart illustrating a processing procedure of the defrosting operation according to the first modification.

  As shown in FIG. 11, the processing procedure of the defrosting operation according to the first modification is compared with the processing procedure of the defrosting operation according to the first embodiment (see FIG. 3), instead of the processing of step S120. It is different in that the process is executed.

In step S320, the following processing is executed.
That is, in step S320, the arithmetic control unit 21 calculates the set time Hend of the defrosting operation based on the following formula 4.
Hend = a3 · To + b3 (4)

In Equation 4 above, a3 and b3 are arbitrary constants set according to the operation.
The constant “a3” is set to a3 <0 so that the set time Hend of the defrosting operation becomes longer as the outside air temperature To before the start of the defrosting operation is lower.

  An upper limit value and a lower limit value are set in advance for the set time Hend of the defrosting operation. When the value calculated by the above-described equation 4 exceeds the upper limit value, the arithmetic control unit 21 sets the set time Hend of the defrosting operation to the upper limit value. Moreover, when the value calculated by the above-described Expression 4 is lower than the lower limit value, the arithmetic control unit 21 sets the set time Hend of the defrosting operation to the lower limit value.

  In FIG. 12, the relationship between the external temperature To in the defrost operation of this modification 1 and the setting time Hend of a defrost operation is shown. FIG. 12 is a diagram illustrating a relationship between the outside air temperature To and the set time Hend of the defrosting operation according to the first modification.

As shown in FIG. 12, when the outside air temperature To before the start of the defrosting operation is equal to or higher than the temperature T2 and equal to or lower than the temperature T1 (however, T2 <T1), the arithmetic control unit 21 performs the defrosting operation. The set time Hend is set to a value calculated based on Equation 4 described above. As a result, the set time Hend for the defrosting operation is set to a value at which the outside air temperature To gradually decreases from the temperature T2 to the temperature T1.
On the other hand, when the setting time Hend of the defrosting operation is lower than the temperature T2, the arithmetic control unit 21 sets the setting time Hend of the defrosting operation to the upper limit value. Thereby, the air conditioner 100 can suppress that the defrosting operation is continued for a relatively long time, and as a result, the start of the heating operation is delayed.
Further, when the set time Hend for the defrosting operation is higher than the temperature T1, the arithmetic control unit 21 sets the set time Hend for the defrosting operation to the lower limit value. Thereby, the air conditioner 100 can melt the frost of the outdoor heat exchanger 7 reliably.

  Such a modification 1 can perform a defrost operation suitably similarly to Embodiment 1, As a result, the frost of the outdoor heat exchanger 7 can be melt | dissolved reliably.

[Modification 2]
For example, in Embodiment 2 described above, the air conditioner 100 sets the outdoor heat exchange temperature Te before the start of the defrosting operation, the outdoor air temperature To before the start of the defrosting operation, and the rotational speed N of the indoor fan 4. The end condition temperature Tend of the defrosting operation is changed according to the value. However, as shown in FIG. 13, for example, the air conditioner 100 includes the outdoor heat exchange temperature Te before the start of the defrosting operation, the outdoor air temperature To before the start of the defrosting operation, and the rotational speed N of the indoor fan 4. You may make it perform the process which changes the setting time (namely, time until it complete | finishes after starting a defrost operation) according to a setting value. FIG. 13 is a flowchart showing a processing procedure of the defrosting operation according to the second modification.

  As shown in FIG. 13, the processing procedure of the defrosting operation of the second modification example is different from the processing procedure of the defrosting operation of the second embodiment (see FIG. 5) in place of the processing of step S120a. It is different in that the process is executed.

In step S320a, the following processing is executed.
That is, in step S320a, the arithmetic control unit 21 calculates the set time Hend for the defrosting operation based on the following formula 5.
Hend = a4 · To + b4 · Te + c4 · N + d4 (5)

In Equation 5, a4, b4, c4, and d4 are arbitrary constants set according to the operation.
The constant “a4” is set to a4 <0 so that the set time Hend of the defrosting operation becomes longer as the outside air temperature To before the start of the defrosting operation is lower.
The constant “b4” is set to a value of b4 <0 so that the setting time Hend of the defrosting operation becomes longer as the outdoor heat exchange temperature Te before the start of the defrosting operation is lower.
The constant “c4” is set to a value of c4> 0 so that the set value Hend of the defrosting operation becomes longer as the set value of the rotational speed N of the indoor fan 4 (the set wind speed of the indoor fan 4) is faster. Has been.

  An upper limit value and a lower limit value are set in advance for the set time Hend of the defrosting operation. When the value calculated by the above-described equation 4 exceeds the upper limit value, the arithmetic control unit 21 sets the set time Hend of the defrosting operation to the upper limit value. Moreover, when the value calculated by the above-described Expression 4 is lower than the lower limit value, the arithmetic control unit 21 sets the set time Hend of the defrosting operation to the lower limit value.

  Such a modification 2 can perform a defrost operation suitably similarly to Embodiment 2, As a result, the frost of the outdoor heat exchanger 7 can be melt | dissolved reliably.

[Additional notes]
Below, the supplementary matter regarding this invention is demonstrated.
(1) In the outdoor unit 102, for example, as shown in FIG. 14, the temperature of the upper part and the temperature of the lower part tend to be different. FIG. 14 is a diagram illustrating an example of the temperature distribution of the outdoor unit 102. The outdoor unit 102 accommodates the outdoor heat exchanger 7 therein, and a base portion 31 is attached to a lower portion thereof. The temperature of each part of the outdoor unit 102 tends to be higher in the upper part than in the lower part due to the influence of heat released from the outdoor heat exchanger 7.

  In such an outdoor unit 102, the temperature of the refrigerant flowing in the lower part of the outdoor heat exchanger 7 tends to remain low during the defrosting operation. The temperature of the refrigerant flowing in the lower part of the outdoor heat exchanger 7 tends to remain low during the defrosting operation. Therefore, the outdoor unit 102 tends to make it difficult for the frost of the base portion 31 to melt.

  However, in the present invention, for example, in the above-described first and second embodiments, the air conditioner 100 changes the defrosting operation end condition temperature Tend according to the outside air temperature To. Further, in the first modification and the second modification, the set time Hend of the defrosting operation is changed according to the outside air temperature To. Therefore, in the present invention, the outdoor unit 102 can continue the defrosting operation even after the temperature of the refrigerant flowing through the lower portion of the outdoor heat exchanger 7 has sufficiently increased. Therefore, the outdoor unit 102 can sufficiently melt the frost of the base portion 31. Such an embodiment of the present invention can be suitably applied to an air conditioner used particularly in a cold region.

  (2) In the third embodiment described above, the defrosting operation start condition temperature Tst is changed according to the outside air temperature To. Such Embodiment 3 can start operation time on appropriate conditions, and can shorten the defrosting time per time. In the third embodiment, instead of the outside air temperature To, the defrosting operation start condition temperature Tst is set according to the current of the outdoor fan 8, the current of the compressor 1, the discharge temperature of the refrigerant from the compressor 1, and the like. It may be changed. This is because when the amount of frost formation in the outdoor heat exchanger 7 increases, the current of the outdoor fan 8 increases, the current of the compressor 1 increases, or the discharge temperature of the refrigerant increases. This is because the above factor can be used to control the defrosting operation.

  (3) In Embodiment 4 described above, the rotational speed of the compressor 1 is increased in the latter half of the defrosting operation than in the first half of the defrosting operation. Such Embodiment 4 can transmit higher-temperature heat to the base part 31 in the second half of the defrosting operation for melting the frost of the base part 31 (see FIG. 14).

  (4) In the fifth embodiment described above, the outdoor fan 8 is driven in the latter half of the defrosting operation or in the period from the end of the defrosting operation to the start of the heating operation. Thereby, Embodiment 5 can reduce the quantity of the vapor | steam which generate | occur | produces from the outdoor heat exchanger 7 in the second half of a defrost operation, and can make a vapor | steam inconspicuous.

  (5) For example, as shown in FIG. 15, the outdoor unit 102 is preferably provided with a plurality of drain holes 32 and 33 in the base portion 31. FIG. 15 is a diagram illustrating an example of the drain holes 32 and 33 provided in the outdoor unit 102. Such an outdoor unit 102 can shorten the defrosting time as the area of the base portion 31 to which frost adheres decreases. The drainage hole 32 is a hole provided near the center of one side of the outdoor heat exchanger 7 having a substantially L shape. The drain hole 33 is a hole provided in the vicinity of the end of one side of the outdoor heat exchanger 7.

  (6) Of the base portion 31 of the outdoor unit 102, the vicinity of one end of the outdoor heat exchanger 7 is a position where frost is hardly melted. Therefore, the outdoor unit 102 is preferably provided with a drain hole at a position like the drain hole 33 shown in FIG. Thereby, the outdoor unit 102 can suppress that frost remains without melting.

  (7) As shown in FIG. 15, the outdoor unit 102 tends to have a lower temperature at the lower portion (that is, the portion closer to the base portion 31). For this reason, the refrigerant flowing in the lower part of the outdoor heat exchanger 7 is affected by the heat from the base portion 31 and tends not to increase in temperature. Therefore, it is preferable that the outdoor heat exchanger 7 be hardly affected by the heat from the base portion 31. Therefore, the outdoor heat exchanger 7 preferably has a configuration in which a spacer 34 is provided between the outdoor heat exchanger 7 and the base portion 31, for example, as shown in FIG. Alternatively, the outdoor heat exchanger 7 may be configured such that a pipe is not provided at the lowest stage of the outdoor heat exchanger 7. Alternatively, even if the outdoor heat exchanger 7 is provided with a pipe at the lowermost stage of the outdoor heat exchanger 7, it may be configured such that no refrigerant flows through the pipe.

DESCRIPTION OF SYMBOLS 1 Compressor 2 Four-way valve 3 Indoor heat exchanger 4 Indoor fan 5 Indoor air temperature sensor 6 Decompression means 7 Outdoor heat exchanger 8 Outdoor fan 9 Outdoor heat exchanger temperature sensor 10 Outdoor air temperature sensor 20 Controller 21 Computation control means (control means)
22 ROM
23 RAM
24 EEPROM
25 Sensors 26 Actuators 27 Remote control 100 Air conditioner 101 Indoor unit 102 Outdoor unit

Claims (6)

A compressor for compressing the refrigerant;
An outdoor heat exchanger for exchanging heat between the refrigerant and the outdoor air;
An indoor heat exchanger for exchanging heat between the refrigerant and room air;
Decompression means for decompressing the refrigerant;
An outside temperature sensor for measuring the outside temperature;
Control means,
When the defrosting operation is performed, the control means uses the defrosting operation end condition temperature used as a defrosting operation end threshold value according to the outside air temperature measured by the outside air temperature sensor, or the defrosting operation. An air conditioner characterized in that the set time of the defrosting operation from the start to the end is changed. In the air conditioner according to claim 1,
Furthermore, an outdoor heat exchanger temperature sensor that measures the temperature of the outdoor heat exchanger;
An indoor fan that sends room air to the indoor heat exchanger,
The control means depends on the temperature of the outdoor heat exchanger measured by the outdoor heat exchanger temperature sensor before the start of the defrosting operation and the set value of the rotation speed of the indoor fan in addition to the outside air temperature. Then, an end condition temperature of the defrosting operation or a set time of the defrosting operation is changed. A compressor for compressing the refrigerant;
An outdoor heat exchanger for exchanging heat between the refrigerant and the outdoor air;
An indoor heat exchanger for exchanging heat between the refrigerant and room air;
Decompression means for decompressing the refrigerant;
An outside temperature sensor for measuring the outside temperature;
An indoor fan for sending room air to the indoor heat exchanger;
Control means,
When the defrosting operation is performed, the control means is a removal unit used as a threshold value for determining the start of the defrosting operation according to the outside air temperature measured by the outside air temperature sensor and the set value of the rotation speed of the indoor fan. An air conditioner characterized by changing a start condition temperature of frost operation. A compressor for compressing the refrigerant;
An outdoor heat exchanger for exchanging heat between the refrigerant and the outdoor air;
An indoor heat exchanger for exchanging heat between the refrigerant and room air;
An expansion valve as decompression means for decompressing the refrigerant;
Control means,
The air conditioner characterized in that the control means expands the opening of the expansion valve from an initial value in a direction to open when the rotational speed of the compressor increases to a set value or more during the defrosting operation. The air conditioner according to claim 4,
The air conditioner characterized in that the rotation speed of the compressor is faster in the second half than in the first half of the defrosting operation. A compressor for compressing the refrigerant;
An outdoor heat exchanger for exchanging heat between the refrigerant and the outdoor air;
An indoor heat exchanger for exchanging heat between the refrigerant and room air;
Decompression means for decompressing the refrigerant;
An outside temperature sensor for measuring the outside temperature;
An outdoor fan that sends outdoor air to the outdoor heat exchanger;
Control means,
Whether the control means drives the outdoor fan during the defrosting operation when the defrosting operation is performed and the outside temperature measured by the outside temperature sensor is lower than a set value. Alternatively, the outdoor fan is driven within a period from the end of the defrosting operation to the start of the heating operation.

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