JP2011012820A - Air conditioning device - Google Patents

Abstract

Disclosed is an air conditioner that discharges drain water generated even after air conditioning operation is stopped from a drain pan and can save energy.
In an air conditioner having a refrigeration cycle in which a compressor, a condenser, a decompressor, and an evaporator are sequentially connected and performing an air conditioning operation, drain water dripped from the evaporator is removed. A drain pan 13 to be stored and a drain pump 14 for discharging drain water in the drain pan 13 are provided. The drain pump 14 is stopped when the air conditioning operation is stopped, and a predetermined time elapses from the stop of the air conditioning operation. It will be activated for a certain time later.
[Selection] Figure 2

Description

  The present invention relates to an air conditioner that accumulates drain water generated in an evaporator in a drain pan and discharges it with a drain pump.

In general, an air conditioner that includes a refrigeration cycle in which a compressor, a condenser, a decompressor, and an evaporator are sequentially connected and performs an air conditioning operation such as a cooling operation is known.
In this type of air conditioner, drain water generated by an evaporator is stored in a drain pan, and the drain water in the drain pan is discharged by a drain pump. During the cooling operation, drain water is generated in the evaporator for a while after the cooling operation is stopped, and the drain water is dripped from the evaporator into the drain pan. If the drain water is left in the drain pan for a long period of time, dust in the room may adhere to it, and sludge-like “loose” may be generated on the surface of the drain pan due to the action of bacteria. In order to prevent the occurrence of such “sloping”, the water level in the drain pan is monitored by the float switch even after the air conditioning operation is stopped, and when the float switch is operated, the drain pump is operated for a certain period of time. The drain water is also discharged (for example, refer to “Patent Document 1”).
JP-A-4-139347

However, in the air conditioning apparatus described in Patent Document 1, when the drain water level in the drain pan does not reach the operating water level of the float switch, the operation of the drain pump is started until the next air conditioning operation is started. There was a problem that it was not done. That is, even when the drain water is dripped onto the drain pan after the air conditioning operation is stopped, it is assumed that the drain water in the drain pan is not discharged if the drain water level is lower than the operating water level of the float switch. On the other hand, when the drain water above the operating level of the float switch is dropped after the air conditioning operation is stopped, in the air conditioning apparatus described in Patent Document 1, the drain water level in the drain pan reaches the operating level of the float switch. Each time the drain pump is activated, power is consumed. Furthermore, when the temperature of the evaporator returns to room temperature after the air conditioning operation is stopped, the generation of drain water is stopped. Even after the generation of drain water stops, it is not preferable to constantly monitor the water level in the drain pan with the float switch because it consumes standby power.
The subject of this invention is providing the air conditioning apparatus which can aim at energy saving while discharging drain water produced | generated after an air-conditioning operation stop from a drain pan.

In order to solve the above-mentioned problems, a first aspect of the present invention is an air conditioning apparatus that includes a refrigeration cycle in which a compressor, a condenser, a decompressor, and an evaporator are sequentially connected, and performs an air conditioning operation. A drain pan for storing drain water dripping from the vessel, and a drain pump for discharging the drain water in the drain pan. The drain pump is stopped together with the stop of the air conditioning operation. Provided is an air conditioner characterized in that the air conditioner is operated for a predetermined time after a predetermined time has elapsed.
According to the above configuration, the drain water is condensed in the evaporator until the surface temperature of the evaporator exceeds the dew point temperature even after the air conditioning operation is stopped, and the drain water is dripped from the evaporator to the drain pan. Since the drain pump is stopped together with the stop of the air conditioning operation, the drain water dripped from the evaporator after the stop of the air conditioning operation is accumulated in the drain pan. The drain pump operates for a certain time after a predetermined time has elapsed since the stop of the air conditioning operation. Accordingly, the drain water accumulated in the drain pan between the stop of the air conditioning operation and the elapse of a predetermined time is discharged by the drain pump. For this reason, even when the water level of the drain water in the drain pan is low, the drain water accumulated after the stop of the air-conditioning operation can be discharged from the drain pan. In addition, the drain pump is temporarily stopped together with the stop of the air conditioning operation, and after that, when a predetermined time elapses, the drain pump is operated only for a certain time, so that the drain pump is operated every time when the water level in the drain pan reaches the predetermined water level. The energy saving can be achieved as compared with the case where the drain pump is continuously operated after the air conditioning operation is stopped until the dripping of the drain water from the evaporator stops. Further, since drain water accumulated during a predetermined time after the air-conditioning operation is stopped is discharged, it is possible to prevent the drain pump from being operated in a light load state. In addition, for example, after the air conditioning operation is stopped, the predetermined time is set to be equal to or longer than the time until the dripping of the drain water stops based on the time until the dripping of the drain water stops from the evaporator. Thus, the entire amount of drain water dripped from the evaporator after the air conditioning operation is stopped can be reliably discharged from the drain pan.
However, the fixed time is preferably a time during which all drain water stored in the drain pan by the drain pump can be discharged. Such a certain period of time can be set based on the maximum amount of drain water dripped from the evaporator after the air conditioning operation is stopped by conducting an experiment or the like in advance. Moreover, it is preferable that the capacity | capacitance of a drain pan is a capacity | capacitance which can store the largest amount of drain water dripped from an evaporator for the predetermined time preset after the air conditioning operation | movement stop.

In the second aspect of the present invention, the predetermined time is preset based on a time required for the dripping of drain water from the evaporator to the drain pan to stop after the air conditioning operation is stopped. It is characterized by.
According to the above configuration, after the air conditioning operation is stopped, the drain pump is operated for a predetermined time after a predetermined time set based on the time required for the dripping of the drain water from the evaporator to the drain pan to stop. Therefore, the drain water dripped from the evaporator after the air conditioning operation is stopped can be reliably discharged from the drain pan. Moreover, after drain water is discharged from the drain pan, it is possible to prevent the drain water from dripping from the evaporator to the drain pan.

According to a third aspect of the present invention, the evaporator is accommodated in an indoor unit, and the predetermined time is determined in advance based on a time required for the surface temperature of the evaporator to return to room temperature after the air conditioning operation is stopped. It is characterized by being set.
According to the above configuration, after the air conditioning operation is stopped, the drain pump is operated for a certain time after a predetermined time set in advance based on the time required for the surface temperature of the evaporator to return to room temperature. The drain water dripped from the evaporator after stopping the harmonious operation can be reliably discharged from the drain pan. Moreover, after drain water is discharged from the drain pan, it is possible to prevent the drain water from dripping from the evaporator to the drain pan.

The fourth aspect of the present invention is characterized in that the predetermined time is changed according to a model of the air conditioner.
According to the above configuration, depending on the model of the air conditioner, the size of the evaporator, the arrangement of components in the indoor unit etc. in which the evaporator is accommodated, and the like differ from the evaporator after the operation of the air conditioner is stopped. Even when the amount of drain water dripped on the drain pan changes, the predetermined time can be set to an appropriate time according to the time when dripping of the drain water stops according to the model of each air conditioner.

According to a fifth aspect of the present invention, there is provided an air conditioner including a refrigeration cycle in which a compressor, a condenser, a decompressor, and an evaporator are sequentially connected, and performing the cooling operation by accommodating the evaporator in an indoor unit. A drain pan for accumulating drain water generated in the evaporator, a drain pump for discharging drain water in the drain pan, an evaporator temperature sensor for detecting the surface temperature of the evaporator, and an indoor unit in which the indoor unit is installed When the cooling operation is stopped, the indoor air temperature sensor that detects the temperature of the air, the drain pump is stopped together with the cooling operation is stopped, and the evaporator temperature sensor detected after the cooling operation is stopped When the surface temperature of the evaporator and the indoor air temperature detected by the indoor air temperature sensor become the same temperature, it operates for a certain period of time. To provide an air conditioning apparatus characterized by comprising a control unit for controlling the urchin the drain pump.
According to the above configuration, since the drain pump is also stopped when the cooling operation is stopped, the drain water dripped from the evaporator after the cooling operation is stopped is accumulated in the drain pan. When the surface temperature of the evaporator and the temperature of the air in the room where the indoor unit is installed become the same temperature, condensation of the drain water in the evaporator stops and dripping of the drain water also stops. The drain water accumulated from the stop of the cooling operation until the surface temperature of the evaporator reaches the same temperature as the room air is discharged by a drain pump. For this reason, even when the water level of the drain water in the drain pan is low, the drain water accumulated after the cooling operation is stopped can be discharged from the drain pan. Also, the drain pump is stopped once with the stop of the cooling operation, and then operates for a certain time when a predetermined time elapses, so that the drain pump operates every time the water level in the drain pan reaches a predetermined water level, Energy saving can be achieved as compared with the case where the drain pump is continuously operated after the stop of the air conditioning operation until the dripping of the drain water stops.

  According to the present invention, drain water generated even after the air conditioning operation is stopped can be discharged from the drain pan, and energy saving can be achieved.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First embodiment]
In FIG. 1, the structure of the air conditioning apparatus 100 of 1st embodiment of this invention is shown. As shown in FIG. 1, an air conditioner 100 according to the present embodiment is a built-in type air conditioner 100 in which an indoor unit 10 is arranged in a ceiling back space 20 of a building, and includes a compressor 31, a condenser 32, A refrigeration cycle in which the decompressor 33 and the evaporator 11 are sequentially connected via the refrigerant pipe 34 is provided, and a cooling operation (air conditioning operation) for cooling the room is performed.
The outdoor unit 30 is installed outdoors and accommodates the compressor 31, the condenser 32, and the decompressor 33 that constitute the refrigeration cycle. The indoor unit 10 includes a blower 12 in a substantially box-shaped housing 10 </ b> A, the evaporator 11 as an indoor heat exchanger located on the leeward side of the blower 12, and drain water dripped from the evaporator 11. A drain pan 13 for collecting water, a drain pump 14 for discharging drain water in the drain pan 13, a water level detection sensor 15 for detecting the water level of the drain water in the drain pan 13, and the like. The indoor unit 10 is provided with a control unit 40 that controls the operation of the drain pump 14.

  The casing 10 </ b> A of the indoor unit 10 is provided with a discharge port 16 for discharging conditioned air. The discharge port 16 includes a cylindrical flange member 17 for attaching a duct (not shown). It has been. Further, a suction port 18 for sucking room air is provided below the blower 12 on the lower surface of the housing 10 </ b> A of the indoor unit 10. In the indoor unit 10, an opening 22 for accommodating the indoor unit 10 is formed in the ceiling plate 21. A decorative panel 23 covers the lower surface of the indoor unit 10 in the opening 22 formed in the ceiling plate 21 and is provided along the surface of the ceiling plate 21. The decorative panel 23 is provided with a suction grill 24 below the suction port 18 formed in the housing 10 </ b> A of the indoor unit 10 so as to cover the suction port 18.

  In the air conditioner 100 configured as described above, the indoor air is sucked into the indoor unit 10 through the suction grille 24 and the suction port 18 as shown by the solid arrows A, B, and C by the operation of the blower 12. Rarely, the air is sent to the evaporator 11. Then, conditioned air cooled by heat exchange with the refrigerant in the evaporator 11 is discharged through the discharge port 16. At this time, the drain water condensed in the evaporator 11 is dropped into the drain pan 13 and stored in the drain pan 13. The drain water stored in the drain pan 13 is discharged by the drain pump 14. The drain pump 14 includes a motor 14A and a main body 14B. A suction port 14C is provided at the lower end of the main body 14B of the drain pump 14, and a drain pipe 19 is connected to a side surface of the main body 14B. As shown by the dotted line in FIG. 1, the drain pipe 19 once extends upward and then is pulled out almost horizontally, and passes through the wall of the housing 10 </ b> A of the indoor unit 10 and is connected to the drain water discharge port 10 </ b> B. The water level detection sensor 15 includes a float 15A that rises according to a change in the water level, and a support cylinder 15B that supports the float 15A. The water level detection sensor 15 is connected to the control unit 40. When the water level in the drain pan 13 reaches a predetermined water level, the water level detection sensor 15 detects this and outputs a water level detection signal to the control unit 40. When a detection signal indicating that the water level in the drain pan 13 has reached a predetermined water level is input from the water level detection sensor 15 to the control unit 40 during the cooling operation, the control unit 40 operates the drain pump 14 to The drain water accumulated in 13 is discharged outside the indoor unit 10 through the drain pipe 19.

The control unit 40 includes a CPU, RAM, ROM, and the like (not shown). In addition, the control unit 40 includes an infrared receiving unit that receives an infrared signal transmitted from a remote controller (not shown). In the control unit 40, the CPU receives a cooling operation start instruction, a cooling operation stop instruction, etc. from the remote control device based on the infrared signal received by the infrared receiving unit, and reads the control program stored in the ROM according to this instruction, By developing and executing in the RAM, the cooling operation of the air conditioner 100 and the drain water discharge processing after the cooling stop are controlled by computer control.
Here, with reference to FIG. 2, the drain water discharge process after the cooling operation stop in the air-conditioning apparatus 100 of the first embodiment will be described.
When an infrared signal indicating a cooling operation stop instruction is input from the remote control device to the infrared receiving unit of the control unit 40 (step S1; Y), the control unit 40 performs a cooling operation stop process and operates the drain pump 14. Is also stopped (step S2). Here, the control unit 40 stops the driving of the compressor 31 and the blower 12 and stops the supply of electric power to the water level detection sensor 15 during the cooling operation stop process.

Next, the control unit 40 uses the built-in timing means to start timing from the cooling operation stop time and waits until a “predetermined time” stored in advance in the ROM or the like has elapsed (step S3). .
Here, in the present embodiment, this “predetermined time” is set to “30 minutes”. The “predetermined time” is set based on the time required for dripping of drain water from the evaporator 11 to the drain pan 13 in the air conditioner 100 after the cooling operation is stopped. When setting the “predetermined time”, for example, in an artificial weather room or the like, the cooling operation is performed in advance under various temperature and humidity conditions, and the time actually taken until the dripping of drain water stops from the evaporator 11 is set. It is preferable to measure and set based on the maximum time required until dripping of drain water from the evaporator 11 is stopped based on a plurality of measurement results. Further, it is preferable that the entire drain water dripped from the evaporator 11 after the cooling operation is stopped is discharged from the drain pan 13. Therefore, from the viewpoint, the “predetermined time” is preferably a time longer than the maximum time actually required until dripping of the drain water from the evaporator 11 stops.
However, if the drain water is left in the drain pan 13 for a long time, there is a concern about the occurrence of “sloping”. Therefore, it is preferable to drain the drain water in the drain pan 13 from the drain pan 13 without taking time after dripping of the drain water stops. Further, it is more preferable that the drain water in the drain pan 13 is discharged from the drain pan 13 immediately after the dripping of the drain water is stopped. From this point of view, the “predetermined time” is more preferably the maximum time required for dripping of drain water from the evaporator 11 to stop, and it is not preferable to set the time longer than necessary.
The “predetermined time” may be set based on the time required for the surface temperature of the evaporator 11 to return to room temperature. This is because when the surface temperature of the evaporator 11 returns to room temperature, the air around the evaporator 11 does not condense on the surface of the evaporator 11 and the generation of drain water stops. In this case, the temperature change of the surface temperature of the evaporator 11 with respect to the temperature and humidity change in the indoor unit 10 is measured under various temperature and humidity conditions in an artificial weather chamber or the like, and after the cooling operation is stopped, the surface of the evaporator 11 is measured. It is preferable that the time is longer than the maximum time required for the temperature to return to room temperature. Also in this case, since it is preferable to drain the drain water in the drain pan 13 from the drain pan 13 without taking time after dripping of the drain water stops, the “predetermined time” is the surface temperature of the evaporator 11. Is preferably the maximum time required to return to room temperature, and it is not preferable to set the time longer than necessary.
The “predetermined time” may be set based on the time required for the surface temperature of the evaporator 11 to exceed the dew point. This is because when the surface temperature of the evaporator 11 exceeds the dew point, the condensation of drain water in the evaporator 11 stops.

In step S3, when the time counted by the time measuring means reaches a predetermined time, the control unit 40 next operates the drain pump 14 (step S4). Here, the operation time of the drain pump 14 is set to a predetermined time. Here, in the first embodiment, this “certain time” is set to “3 minutes”. This fixed time is set in advance so as to be a time during which all drain water stored in the drain pan 13 can be discharged by the drain pump 14. Specifically, it can be set based on the maximum amount of drain water dropped from the evaporator 11 after the cooling operation is stopped by conducting an experiment or the like in advance. However, in the present embodiment, the drain pan 13 has a capacity capable of storing the maximum amount of drain water dripped from the evaporator 11 after the cooling operation is stopped.
When the fixed time has elapsed since the drain pump 14 was operated (step S5; Y), the control unit 40 stops the operation of the drain pump 14 (step S6).

That is, as shown in FIG. 3 (a), when the cooling operation at the time of T ₁ is stopped, the surface temperature of the evaporator 11 is gradually increased with stopping of the cooling operation, the temperature returned to room temperature. On the other hand, as shown in FIG. 3 (c), at time of _{T 1} to the cooling operation is stopped, the operation of the drain pump 14 is stopped, the predetermined time _(T 2 -T ₁₎ time point _{T 2} of the after The drain pump 14 is operated for a certain time (T ₃ -T ₂ ). At a time of T ₃ for a predetermined period of time by operating the drain pump 14 has elapsed, the drain pump 14 is stopped. However, Fig.3 (a) is the figure which showed the change of the surface temperature of the evaporator 11 with progress of time. 3B is a diagram showing a cooling operation state of the air conditioner 100, and FIG. 3C is a diagram showing an operation state of the drain pump 14. As shown in FIG.

  According to the air conditioning apparatus 100 of the first embodiment described above, since the drain pump 14 is also stopped when the cooling operation is stopped, the drain water dripped from the evaporator 11 after the cooling operation is stopped is supplied to the drain pan 13. Accumulate. The drain pump 14 operates for a certain time after a predetermined time has elapsed since the cooling operation was stopped. Accordingly, the drain water accumulated in the drain pan 13 before the predetermined time elapses after the cooling operation is stopped is discharged by the drain pump 14. For this reason, even when the water level of the drain water in the drain pan 13 is low, the drain water accumulated after the cooling operation is stopped can be discharged from the drain pan 13. Further, the drain pump 14 is temporarily stopped when the cooling operation is stopped. After that, when the predetermined time elapses, the drain pump 14 is operated for a predetermined time. In this case, after the cooling operation is stopped, energy can be saved as compared with the case where the drain pump 14 is continuously operated until dripping of the drain water from the evaporator 11 stops. Further, since the drain water accumulated for a predetermined time after the cooling operation is stopped, the drain pump 14 can be prevented from operating in a light load state.

  In the air conditioning apparatus 100 of the first embodiment, after the cooling operation is stopped, the time required for the dripping of drain water from the evaporator 11 to the drain pan 13 is stopped, or after the cooling operation is stopped, Since the drain pump 14 is operated for a predetermined time after a predetermined time set based on the time required for the surface temperature of the evaporator 11 to return to room temperature, the drain water dripped from the evaporator 11 after the cooling operation is stopped. Can be reliably discharged from the drain pan 13. Moreover, after drain water is discharged from the drain pan 13, it is possible to prevent the drain water from dripping from the evaporator 11 to the drain pan 13.

[Second Embodiment]
Next, a second embodiment of the air conditioner 200 according to the present invention will be described.
Since the air conditioning apparatus 200 of the second embodiment has substantially the same configuration as that of the air conditioning apparatus 100 of the first embodiment, the same reference numerals are assigned to the same configurations, and descriptions thereof are omitted.
The air conditioner 200 according to the second embodiment includes an evaporator temperature sensor 201 that detects the surface temperature of the evaporator 11, and an indoor air temperature sensor 202 that detects the temperature of the indoor air sucked into the indoor unit 10. It has. The evaporator temperature sensor 201 detects the surface temperature of the evaporator 11 on the windward side of the evaporator 11. On the other hand, the indoor air temperature sensor 202 is disposed in the vicinity of the suction port 18. An evaporator temperature detection signal and an indoor air temperature detection signal are output from the evaporator temperature sensor 201 and the indoor air temperature sensor 202 to the control unit 40, respectively.

Next, with reference to FIG. 4, the drain water discharge process after the cooling operation stop in the second embodiment will be described.
When an infrared signal indicating a cooling operation stop instruction is input from the remote control device to the infrared receiving unit of the control unit 40 (step S11; Y), the control unit 40 performs a cooling operation stop process and operates the drain pump 14. Is also stopped (step S12). Here, the control unit 40 stops the driving of the compressor 31 and the blower 12 and stops the supply of electric power to the water level detection sensor 15 during the cooling operation stop process.
Next, the controller 40 determines the surface temperature of the evaporator 11 based on the evaporator temperature detection signal input from the evaporator temperature sensor 201 and the indoor air temperature detection signal input from the indoor air temperature sensor 202. It is determined whether or not the temperature of the indoor air in which the indoor unit 10 is installed is the same (step S13). And when it determines with the surface temperature of the evaporator 11 being the same temperature as the temperature of indoor air (step S13; Y), the control part 40 operates the drain pump 14 (step S14), and until a fixed time passes. Wait (step S15). However, this fixed time is a time set in advance so that the drain water stored in the drain pan 13 by the drain pump 14 can be completely discharged, as in the first embodiment. Also in the embodiment, specifically, “3 minutes” is set.
And if the said fixed time passes after operating the drain pump 14 (step S15; Y), the control part 40 will stop the operation | movement of the drain pump 14 (step S16).
However, in step S13, when the difference between the surface temperature of the evaporator 11 and the temperature of the indoor air is less than 1 ° C., it is determined that the surface temperature of the evaporator 11 and the temperature of the indoor air are the same. You may do it.

  According to the air conditioning apparatus 200 of the second embodiment described above, since the drain pump 14 is also stopped when the cooling operation is stopped, the drain water dropped from the evaporator 11 after the cooling operation is stopped is drain pan 13. It collects in. Even after the cooling operation is stopped, the drain water is condensed in the evaporator 11 until the surface temperature of the evaporator 11 exceeds the dew point temperature in the indoor unit 10, and the drain water is dropped from the evaporator 11 onto the drain pan 13. When the surface temperature of the evaporator 11 and the temperature of the indoor air in which the indoor unit 10 is installed become the same temperature, the condensation of the drain water in the evaporator 11 stops and the dripping of the drain water also stops. The drain water accumulated from the stop of the cooling operation until the surface temperature of the evaporator 11 becomes the same as the temperature of the indoor air is discharged by the drain pump 14. For this reason, even when the water level of the drain water in the drain pan 13 is low, the drain water accumulated after the cooling operation is stopped can be discharged from the drain pan 13. Further, the drain pump 14 is temporarily stopped when the cooling operation is stopped. After that, when the predetermined time elapses, the drain pump 14 is operated for a predetermined time. Therefore, the drain pump 14 is operated every time the water level in the drain pan 13 reaches the predetermined water level. In this case, it is possible to save energy as compared with the case where the drain pump 14 is continuously operated after the stop of the air conditioning operation until the dripping of the drain water stops.

The first embodiment and the second embodiment described above are one aspect of the present invention, and it is needless to say that the first embodiment and the second embodiment can be appropriately changed without departing from the gist of the present invention.
For example, the “predetermined time” described in the first embodiment can be appropriately changed according to the model of the air conditioner 100, the area where the air conditioner 100 is installed, the installation location, and the like. Of course. Depending on the model of the air conditioner 100, the size of the evaporator 11, the arrangement of each part in the indoor unit 10 in which the evaporator 11 is accommodated, and the like are different. Moreover, ambient environments, such as air temperature and humidity, differ according to the area and installation location where the air conditioning apparatus 100 was installed. For this reason, depending on the model of the air conditioner 100, the area where the air conditioner 100 is installed, the installation location, etc., the time required for the dripping of the drain pan 13 from the evaporator 11 to stop after the cooling operation is stopped, the evaporation The time required for the surface temperature of the vessel 11 to return to room temperature varies. Therefore, the “predetermined time” is an appropriate time according to the time when dripping of drain water stops depending on the model of the air conditioner 100, the area where the air conditioner 100 is installed, the installation location, and the like. Thus, it is possible to set an appropriate time according to the maximum time until dripping of drain water from the evaporator 11 to the drain pan 13 stops.
Moreover, although the above-mentioned “predetermined time” and “predetermined time” have been described as being stored in the ROM or the like in advance, the installer of the air conditioner 100 appropriately selects these “predetermined time” and “predetermined time” on site. ”May be changed.

It is sectional drawing which shows the indoor unit of the air conditioning apparatus of embodiment of this invention. It is a flowchart which shows the procedure of the drain water discharge process of 1st embodiment of this invention. It is a figure which shows the change (a) of the surface temperature of the evaporator at the time of drain water discharge | emission processing of 1st embodiment of this invention, a cooling operation state (b), and the operation state (c) of a drain pump. It is a flowchart which shows the procedure of the drain water discharge process of 2nd embodiment of this invention.

DESCRIPTION OF SYMBOLS 10 Indoor unit 11 Evaporator 13 Drain pan 14 Drain pump 30 Outdoor unit 31 Compressor 32 Condenser 33 Decompressor 40 Control part 100, 200 Air conditioning apparatus 201 Evaporator temperature sensor 202 Indoor air temperature sensor

Claims (5)

In an air conditioner that includes a refrigeration cycle in which a compressor, a condenser, a decompressor, and an evaporator are sequentially connected, and performs an air conditioning operation,
A drain pan for collecting drain water dripping from the evaporator;
A drain pump for discharging drain water in the drain pan;
With
The drain pump is stopped when the air-conditioning operation is stopped, and is operated for a predetermined time after a predetermined time elapses from the stop of the air-conditioning operation;
An air conditioner characterized by. The predetermined time is set in advance based on the time required for the dripping of drain water from the evaporator to the drain pan to stop after the air conditioning operation is stopped,
The air conditioning apparatus according to claim 1. The evaporator is housed in an indoor unit;
The predetermined time is preset based on the time required for the surface temperature of the evaporator to return to room temperature after the air conditioning operation is stopped,
The air conditioning apparatus according to claim 1. The predetermined time is changed according to the model of the air conditioner,
The air conditioning apparatus according to any one of claims 1 to 3, wherein: In an air conditioner comprising a refrigeration cycle in which a compressor, a condenser, a decompressor and an evaporator are sequentially connected, and performing cooling operation by accommodating the evaporator in an indoor unit,
A drain pan for storing drain water generated in the evaporator;
A drain pump for discharging drain water in the drain pan;
An evaporator temperature sensor for detecting a surface temperature of the evaporator;
An indoor air temperature sensor for detecting the temperature of the indoor air in which the indoor unit is installed;
When the cooling operation is stopped, the drain pump is stopped together with the cooling operation, and the surface temperature of the evaporator detected by the evaporator temperature sensor after the cooling operation is stopped, and the indoor air temperature sensor A controller that controls the drain pump to operate only for a predetermined time when the temperature of the indoor air detected by
An air conditioner comprising:

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