JP2013108672A - Air conditioner with crankcase heater - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner capable of securely supplying electric power to a CH earlier by a certain time before compressor activation by predicting the ON/OFF timing of the CH from an actual user's use condition of the air conditioner.SOLUTION: The air conditioner is equipped with a crankcase heater 40 added to a compressor 10 which can be heated by supplying electric power to the crankcase heater 40 for a period of time when the compressor 10 is stopped. The air conditioner includes a control unit 41 which always supplies electric power to the crankcase heater 40 during a stop of the compressor 10 in a preset operation period, calculates the total heating ON/OFF time of the air conditioner, calculates an OFF allowed time of the crankcase heater 40 based on the total ON/OFF heating time, and predicts an ON timing of the crankcase heater 40 to perform ON/OFF control over the crankcase heater 40 after the set operation period.

Description

  The present invention relates to an air conditioner including a crankcase heater for heating a compressor.

  If the air conditioner is stopped for a long time, the refrigerant becomes liquid and accumulates in the compressor. If the compressor is started in this state, the compressor may be damaged by liquid compression. For this reason, especially in an air conditioner for cold regions, a crankcase heater (hereinafter abbreviated as CH) is attached to the compressor, and the CH is energized to heat the compressor before the air conditioner is operated. As a result, liquid compression due to accumulation of liquid refrigerant is prevented. The CH may be energized a certain time before starting the compressor, but since the user does not know when to use the air conditioner, the CH is always energized while the compressor is stopped. ing. For this reason, the energization time with respect to CH becomes longer than necessary, and there is a problem that standby power increases.

  Therefore, in order to suppress the power consumption of CH, Patent Document 1 provides (1) a timer for detecting a predetermined time after the compressor is stopped, and turns on CH after that time. (2) A timer for detecting a predetermined time is provided, and CH is turned on at that time. (3) A timer for detecting a predetermined time, a calendar detecting means for detecting the month and day, and an energization amount control means are provided to turn on CH at the predetermined time and control the energization amount by the date. (4) A timer for detecting a predetermined time, an area setting unit, and an energization amount control unit are provided to turn on CH at a predetermined time and control the energization amount according to the area. (5) A timer for detecting a predetermined time, a calendar detection unit, and a CH control unit for controlling energization to the CH based on the calendar detection unit are provided, and the energization time is determined by the date. (6) A timer for detecting a predetermined time, an area setting means, and CH control means for controlling energization to the CH based on the area setting means are provided, and the energization time is determined according to the area. Something like that is presented.

JP 2002-277070 A

In the above-mentioned Patent Document 1, a timer for detecting a predetermined time is provided, and when this timer detects the predetermined time, the CH is energized through the CH energizing means. However, it is unclear how the predetermined time detected by the timer is determined. In general, the time for using the air conditioner, that is, the time for starting the compressor, varies depending on the user, and it is difficult to uniformly determine the predetermined time detected by the timer.
Therefore, in order to prevent the liquid compression by energizing the CH a certain time before the compressor is started, the CH ON / OFF timing is determined reflecting the actual use of the air conditioner by the user. There was no other.

  The present invention has been made in view of such circumstances, and predicts the ON / OFF timing of the CH from the actual use of the air conditioner of the user, and reliably confirms the CH before a certain time before the compressor is started. An object of the present invention is to provide an air conditioner that can be energized.

In order to solve the above-described problems, the air conditioner of the present invention employs the following means.
That is, in the air conditioner according to the present invention, a crankcase heater is attached to the compressor, and the compressor can be heated by energizing the crankcase heater while the compressor is stopped. In the air conditioner, during the preset operation period, the compressor always energizes the crankcase heater during the stop period, and totals the heating ON / OFF time by the air conditioner, and the setting After the operation period has elapsed, a control unit that calculates the crankcase heater OFF possible time based on the result of the calculation, predicts the ON timing of the crankcase heater, and controls the crankcase heater ON / OFF. It is characterized by having.

  According to the present invention, during the preset operation period, the compressor is always energized to the crankcase heater based on a predetermined specification during the stop period, and heating ON / OFF by the air conditioner is performed. The time is totaled, and after the set operation period has elapsed, the crankcase heater OFF time is calculated based on the total result, and the crankcase heater ON / OFF control is performed by predicting the crankcase heater ON timing. Since the control unit is provided, a time during which the crankcase heater can be turned off can be calculated while the compressor is stopped by the control unit, and the crankcase heater can be turned off during that time. Also, by calculating the crankcase heater OFF possible time and predicting the crankcase heater ON timing, the crankcase heater is turned ON to heat the compressor a certain time before the compressor is actually started. Is possible. Therefore, it is not necessary to always energize the crankcase heater during the stop period of the compressor, and standby power can be saved.

  Furthermore, the air conditioner of the present invention is the above-described air conditioner, wherein the control unit predicts the ON timing of the crankcase heater and controls the crankcase heater to be turned on and off; The compressor includes switching means capable of switching to any of a normal operation mode in which the crankcase heater is always energized based on a predetermined specification during the stop period.

  According to the present invention, the control unit predicts the ON timing of the crankcase heater, and controls the operation reduction mode in which the crankcase heater is turned ON / OFF, and the specifications determined in advance while the compressor is stopped. When the air conditioner is used in an irregular state, it has a switching means that can be switched to either the normal operation mode in which the crankcase heater is always energized. Is switched from the operation reduction mode to the normal operation mode, and the crankcase heater can be controlled in the normal operation mode in which the crankcase heater is always energized during the stop period of the compressor. Therefore, according to the actual condition of use of the air conditioner, it can be selectively switched to one of the control modes and operated, and standby power can be saved while ensuring a liquid compression preventing function by the crankcase heater. .

  Furthermore, the air conditioner of the present invention is characterized in that in the above air conditioner, the switching means can be switched from the remote control side.

  According to the present invention, since the switching means can be switched from the remote control side, according to the actual use of the air conditioner, the ON / OFF control mode of the crankcase heater can be changed by an operation from the remote control as necessary. It is possible to switch to either the operation reduction mode or the normal operation mode. Therefore, the control mode of the crankcase heater can be easily switched by the remote controller so as to conform to the actual use condition of the air conditioner by the user.

  According to the present invention, while the compressor is stopped, the time during which the crankcase heater can be turned off is calculated, and during that time, the crankcase heater can be turned off and the crankcase heater can be turned off. By predicting the ON timing of the crankcase heater, it becomes possible to heat the compressor by turning on the crankcase heater a certain time before actually starting the compressor. During this time, it is not always necessary to energize the crankcase heater, and standby power can be saved.

It is a schematic block diagram of the multi air conditioner which concerns on one Embodiment of this invention. It is a block diagram around the compressor provided with the crankcase heater of the multi air conditioner shown in FIG. It is a control flowchart figure of the crankcase heater shown in FIG. It is an example of the heating ON time totaling table used for control of the crankcase heater shown in FIG. It is an example of the calculation example of ON / OFF data totalization of the air conditioner used for control of the crankcase heater shown in FIG. 3, and the crankable heater OFF possible time. It is an example of the ON / OFF timing chart of the multi air conditioner and crankcase heater shown in FIG.

Hereinafter, an embodiment of the present invention will be described with reference to FIGS.
FIG. 1 shows a schematic configuration diagram of a multi-air conditioner according to an embodiment of the present invention, and FIG. 2 shows a configuration diagram around a compressor including the crankcase heater.
A multi-type air conditioner (hereinafter sometimes simply referred to as an air conditioner) 1 is a gas-side pipe through which a plurality of indoor units 3A and 3B are led out from the outdoor unit 2 with respect to one outdoor unit 2. 4 and the liquid side pipe 5 are connected in parallel to each other via a branching device 6.

  The outdoor unit 2 heats an inverter-driven compressor 10 that compresses refrigerant, an oil separator 11 that separates lubricating oil from refrigerant gas, a four-way switching valve 12 that switches the circulation direction of refrigerant, and refrigerant and outside air. The outdoor heat exchanger 13 to be exchanged, the supercooling coil 14 configured integrally with the outdoor heat exchanger 13, the outdoor expansion valve (EEVH) 15, the receiver 16 storing the liquid refrigerant, and the liquid refrigerant A subcooling heat exchanger 17 that provides supercooling, a supercooling expansion valve (EEVSC) 18 that controls the amount of refrigerant that is diverted to the subcooling heat exchanger 17, and a liquid component from the refrigerant gas that is drawn into the compressor 10. And an accumulator 19 for sucking only the gas component to the compressor 10 side, a gas side operation valve 20, and a liquid side operation valve 21.

  Each said apparatus by the side of the outdoor unit 2 is connected as is well-known via the refrigerant | coolant piping 22, and comprises the outdoor side refrigerant circuit 23. FIG. The outdoor unit 2 is provided with an outdoor fan 24 that ventilates the outdoor air to the outdoor heat exchanger 13, and the oil separator 11 is interposed between the oil separator 11 and the suction pipe of the compressor 10. An oil return circuit 25 is provided for returning the lubricating oil separated from the discharged refrigerant gas to the compressor 10 by a predetermined amount.

  The gas side pipe 4 and the liquid side pipe 5 are refrigerant pipes connected to the gas side operation valve 20 and the liquid side operation valve 21 of the outdoor unit 2, and are connected to the outdoor unit 2 and to it during installation on site. The pipe length is set according to the distance between the plurality of indoor units 3A and 3B. An appropriate number of branching devices 6 are provided in the middle of the gas side piping 4 and the liquid side piping 5, and an appropriate number of indoor units 3 </ b> A and 3 </ b> B are connected via the branching devices 6. Thereby, one sealed refrigeration cycle (refrigerant circuit) 7 is configured.

  The indoor units 3A and 3B include an indoor heat exchanger 30 that exchanges heat between indoor air and refrigerant for indoor air conditioning, an indoor expansion valve (EEVC) 31, and an indoor air that circulates indoor air to the indoor heat exchanger 30. The fan 32 is provided, and is connected to the branching device 6 via the indoor branch gas side pipes 4A and 4B and the branch liquid side pipes 5A and 5B.

In the air conditioner 1 described above, the cooling operation is performed as follows.
The high-temperature and high-pressure refrigerant gas compressed and discharged by the compressor 10 is separated from the lubricating oil contained in the refrigerant by the oil separator 11. Thereafter, the refrigerant gas is circulated to the outdoor heat exchanger 13 side by the four-way switching valve 12, and heat is exchanged with the outdoor air blown by the outdoor fan 24 in the outdoor heat exchanger 13 to be condensed and liquefied. The liquid refrigerant is further cooled by the supercooling coil 14, passes through the outdoor expansion valve 15, and is temporarily stored in the receiver 16.

  The liquid refrigerant whose circulation amount is adjusted by the receiver 16 is diverted from the liquid refrigerant pipe in the process of flowing through the liquid refrigerant pipe side through the supercooling heat exchanger 17 and is insulated by the supercooling expansion valve (EEVSC) 18. Heat exchange is performed with a part of the expanded refrigerant to provide a degree of supercooling. The liquid refrigerant is led out from the outdoor unit 2 to the liquid side pipe 5 through the liquid side operation valve 21. Furthermore, the liquid refrigerant led out to the liquid side pipe 5 is diverted to the branch liquid side pipes 5A and 5B of the indoor units 3A and 3B via the branching unit 6.

  The liquid refrigerant divided into the branch liquid side pipes 5A and 5B flows into the indoor units 3A and 3B, is adiabatically expanded by the indoor side expansion valve (EEVC) 31, and becomes a gas-liquid two-phase flow. 30. In the indoor heat exchanger 30, the indoor air circulated by the indoor fan 32 and the refrigerant are heat-exchanged, and the indoor air is cooled and supplied to the indoor cooling. On the other hand, the refrigerant is gasified, reaches the branching device 6 through the branch gas side pipes 4A and 4B, and is merged with the refrigerant gas from the other indoor units in the gas side pipe 4.

  The refrigerant gas merged in the gas side pipe 4 returns to the outdoor unit 2 again, merges with the refrigerant gas from the supercooling heat exchanger 17 through the gas side operation valve 20 and the four-way switching valve 12, and then accumulator 19. To be introduced. In the accumulator 19, the liquid component contained in the refrigerant gas is separated, and only the gas component is sucked into the compressor 10. This refrigerant is compressed again in the compressor 10, and the cooling operation is performed by repeating the above cycle.

On the other hand, the heating operation is performed as follows.
The high-temperature and high-pressure refrigerant gas compressed and discharged by the compressor 10 is separated from the lubricating oil contained in the refrigerant by the oil separator 11 and then the gas-side operation valve 20 side through the four-way switching valve 12. It is circulated in. The refrigerant circulated to the gas-side operation valve 20 side is led out from the outdoor unit 2 through the gas-side pipe 4, and passes through the branching unit 6 and the indoor-side branching gas-side pipes 4A and 4B to be a plurality of indoor units 3A and 3B. To be introduced.

  The high-temperature and high-pressure refrigerant gas introduced into the indoor units 3A and 3B is heat-exchanged with the indoor air circulated through the indoor fan 32 in the indoor heat exchanger 30, and the indoor air is heated and used for indoor heating. The The liquid refrigerant condensed in the indoor heat exchanger 30 reaches the branching device 6 through the indoor expansion valve (EEVC) 31 and the branch liquid side pipes 5A and 5B, and is merged with the refrigerant from other indoor units. It returns to the outdoor unit 2 side through the liquid side pipe 5. During heating, in the indoor units 3A and 3B, the room temperature is adjusted so that the refrigerant outlet temperature (hereinafter referred to as heat exchange outlet temperature) or the refrigerant subcooling degree of the indoor heat exchanger 30 functioning as a condenser becomes a target value. The opening degree of the inner expansion valve (EEVC) 31 is controlled.

  The refrigerant that has returned to the outdoor unit 2 side reaches the supercooling heat exchanger 17 via the liquid side operation valve 21, and is given supercooling as in the case of cooling, and then flows into the receiver 16 and temporarily stored. Thus, the circulation amount is adjusted. The liquid refrigerant is supplied to the outdoor expansion valve (EEVH) 15 and subjected to adiabatic expansion, and then flows into the outdoor heat exchanger 13 through the supercooling coil 14.

  In the outdoor heat exchanger 13, heat is exchanged between the outside air blown through the outdoor fan 24 and the refrigerant, and the refrigerant absorbs heat from the outside air and is evaporated and gasified. The refrigerant is introduced from the outdoor heat exchanger 13 through the four-way switching valve 12 to the refrigerant gas from the supercooling heat exchanger 17 and then introduced into the accumulator 19. In the accumulator 19, the liquid component contained in the refrigerant gas is separated, and only the gas component is sucked into the compressor 10 and compressed again in the compressor 10. The heating operation is performed by repeating the above cycle.

  Further, in the air conditioner 1, the compressor 10 is provided with a crankcase heater (hereinafter abbreviated as CH) 40 on the outer periphery of the hermetic housing 10A as shown in FIG. In the CH 40, during the period when the compressor 10 is stopped, the refrigerant accumulates in the compressor 10 in a liquid state, and the compressor 10 sucks the liquid refrigerant when the compressor 10 starts up, causing liquid compression, and the compressor 10 is damaged. This is provided to prevent the liquid refrigerant from flowing out and the liquid refrigerant is removed from the compressor 10 by energizing the CH 40 and heating the compressor 10 before operating the air conditioner 1. It is.

  The CH 40 is configured to be ON / OFF controlled via the control unit 41. The control unit 41 includes a normal operation mode control unit 42 that constantly controls energization based on a predetermined specification for the CH 40 during the stop period of the compressor 10, and predicts the ON timing of the CH 40 to turn on the CH 40. Is provided with an operation reduction mode control unit 43 that performs ON / OFF control, and a switching means 44 that can selectively switch the control mode to either the normal operation mode or the operation reduction mode. It is configured so that it can be switched from. Further, the detection value from the outside air temperature sensor 46 is input to the control unit 41.

  The normal operation mode control unit 42 always energizes the CH 40 while the compressor 10 is in the stop period and heats the compressor 10 by turning on the CH 40 when the CH 40 ON condition described in the spec is set. Is. In this case, when the compressor 10 is started, the CH 40 is turned off during the start-up, and when the compressor 10 is stopped, the CH 40 is always turned on during the stop period. Such an operation mode is a known mode that has been conventionally applied as an operation mode of CH40, and is not particularly new.

  On the other hand, the operation reduction mode control unit 43 predicts the timing for turning on CH40 from the time zone in which the user uses the air conditioner 1 (starts up the compressor 10), and controls CH40 to turn on and off CH40. It is intended to reduce the operation time and save standby power. Specifically, during the preset operation period, during the stop period, the compressor 10 is always energized based on the predetermined specifications for the CH 40 as in the normal operation mode, and the air conditioner 1 After the set operation period has elapsed, the CH40 OFF possible time is calculated based on the totaled result, the CH40 ON timing is predicted, and the CH40 ON / OFF is calculated. By controlling, the compressor 10 can be heated by turning on CH40 before the compressor 10 is actually started.

Below, the control flow by this driving | running reduction mode control part 43 is demonstrated in detail with reference to FIG. 3 thru | or FIG.
As described above, the CH 40 is controlled in either the normal operation mode or the operation reduction mode. When the operation reduction mode is selected, the CH 40 is operated as follows.
For example, in the first four weeks (preliminary operation period), the heating ON / OFF status of the air conditioner 1 is totaled, so the initial value of A to Gtw is set to 1, and CH 40 is set to the normal operation mode. Here, A to Gtw indicate that A to G are days of the week (Sun to Sat), t is time (0 to 24h), and w is a week. Further, the ON / OFF determination of CH40 determines that heating is not used in the current time zone unless heating is turned on at least four weeks before the current day in the current time zone. It is turned off.

  In the control flow, first, when the CH40 ON time reduction mode is started, in step S1, “t = + 1” is processed every time one hour (1h) elapses. Then, when t becomes “t ≧ 24”, “t = 1” is set, and each time, A → B → C →... G → A. After the processing in step S1 ends, the process proceeds to step S2, and when the week changes from G to A, the processing is performed as “w = + 1”, and when “w ≧ 4” is satisfied, “w = 1”. And so on. Then, it progresses to step S3 and calculates | requires heating operation condition total value "SUM_A-Gt" for every day and every time. The heating operation status total value “SUM_A to Gt” for each day of the week and time is calculated by “SUM_A to Gt = A to Gt1 + A to Gt2 + A to Gt3 + A to Gt4”.

  When the heating operation status total value “SUM_A to Gt” is calculated, the process proceeds to step S4, where it is determined whether “heating is OFF”. If it determines with NO, it will progress to step S5 and heating ON time will be totaled. This heating ON time is counted as “A to Gtw” for each day of the week and every hour. For example, if it is AM3 on the second Sunday, “A to Gtw = A0302”. In “A0302” in this case, since heating is ON, “A to Gtw” is processed as “1”, and the process returns to step S1. On the other hand, if “YES” is determined in the step S5, the process proceeds to a step S6 so that the heating OFF time is similarly counted, and “A to Gtw” is processed as “0”.

  When the process in step S6 ends, the process proceeds to step S7, where it is determined whether CH40 is in “operation reduction mode”. However, since the first four weeks (preliminary operation period) are controlled in the normal operation mode for the ON / OFF data aggregation period of the air conditioner 1, it is determined as NO, and the process proceeds to step S8. While the compressor 10 is ON, CH40 is OFF, while the compressor 10 is OFF, CH40 is basically ON, and CH40 is ON in the normal operation mode based on the ON condition of CH40 described in the specification. / OFF is determined, and energization control is performed. Note that the conditions for turning on the CH 40 described in the specification include, for example, the value detected by the outside air temperature sensor 46 and the previous operation mode. It is.

  By the operations in steps S1 to S6 described above, as shown in FIG. 4, a heating ON time totaling table is created and the timing at which CH40 can be turned off is totaled. FIG. 5 shows an example of the ON time reduction operation of the CH 40 based on the ON / OFF total data of the air conditioner 1 during this period. As an example, the ON / OFF data total result of the air conditioner 1 on a certain Sunday is shown. An example of calculating the CH40 OFF possible time is shown.

  During the first four weeks (set operation period), the heating ON / OFF status is totaled as described above. After the period has elapsed, the CH40 OFF possible time is calculated based on the totaling result, and the CH40 ON timing is calculated. Thus, the CH can be controlled ON / OFF. In the control flow shown in FIG. 3, in step S7, it is determined whether CH40 is “operation reduction mode”. If NO, the process proceeds to step S8, and CH40 is determined to be ON / OFF in the normal operation mode. Will be controlled.

  If YES is determined in the step S7, the process proceeds to a step S9 so as to determine whether “SUM_A to Gt = 0 & SUM_A to G (t + 1) = 0”. If NO is determined here, the process proceeds to step S8 described above, and CH40 is turned ON or OFF in the normal operation mode, and then returns to step S1. If YES is determined, the process proceeds to step S10 and CH40 is turned OFF. After that, the process returns to step S1. As described above, the CH 40 calculates a time during which the compressor 10 can be turned off while the compressor 10 is stopped, and is turned off during that time, so that standby power can be reduced.

  In the specific example shown in FIG. 5, when the operation reduction mode is selected, in addition to the ON / OFF control in the normal operation mode, depending on the operation reduction mode, t = 2 to t = 6, That is, CH40 is turned off from AM1 to AM6. Therefore, according to the present embodiment, the CH40 OFF possible time is calculated, the CH40 ON timing is predicted, and the CH40 is ON / OFF controlled, so that the CH40 is always ON during the stop period of the compressor 10. Without doing so, for example, as shown in the timing chart of FIG. 6, the compressor 10 can be heated by turning on CH40 a certain time before the compressor 10 is actually started.

  On the other hand, the air conditioner 1 may be used irregularly by a user. For this reason, it is not necessarily practical to fix the ON / OFF control of the CH 40 only in the operation reduction mode from the viewpoint of the actual use of the air conditioner 1. In view of this point, in the present embodiment, the switching unit 44 is provided in the control unit 41 of the CH 40, and the control mode of the CH 40 is changed from the remote controller 45 to the operation reduction mode or the normal operation via the switching unit 44 as described above. It can be switched to one of the modes.

Thus, according to the present embodiment, the following operational effects are obtained.
In the air conditioner 1, energization control can be performed on the CH 40 attached to the compressor 10 through either the normal operation mode control unit 42 or the operation reduction mode control unit 43. And when control by the normal operation mode control part 42 is selected via the switching means 44, it is always energized based on a predetermined specification with respect to CH40 except the period when the compressor 10 is driven. Therefore, it is possible to prevent liquid refrigerant from accumulating in the stopped compressor 10 and reliably prevent liquid compression when the compressor 10 is started.

  On the other hand, when the control by the operation reduction mode control unit 43 is selected, the heating ON / OFF time by the air conditioner 1 is totaled, and after the set operation period has elapsed, the CH40 OFF possible time is calculated based on the total result. Since it is possible to control ON / OFF of the CH 40 by predicting the ON timing of the CH 40, the time during which the CH 40 can be turned OFF during the period when the compressor 10 is stopped is calculated, and during that time, the CH 40 is turned OFF. Can do. Also, by calculating the CH40 OFF possible time and predicting the CH40 ON timing, it becomes possible to turn on CH40 and heat the compressor 10 a certain time before actually starting the compressor 10. . Thereby, it is not necessary to always energize the CH 40 during the stop period of the compressor 10, and standby power can be saved.

  Further, since it is possible to select either the control in the normal operation mode or the control in the operation reduction mode by the switching means 44, the switching means 44 is used when the air conditioner 1 is used in an irregular state. The control mode of the CH 40 is switched from the operation reduction mode to the normal operation mode via the compressor, and the CH 40 is controlled in the normal operation mode in which the CH 10 is always energized based on a predetermined specification during the stop period. Can do. Therefore, according to the actual condition of use of the air conditioner 1, it is possible to selectively switch to any one of the control modes and operate, and it is possible to save standby power while ensuring the liquid compression preventing function by the CH40.

  Further, since the switching means 44 can be switched from the remote controller 45 side, the ON / OFF control mode of the CH 40 can be changed to the driving reduction mode or the normal operation by the operation from the remote controller 45 as necessary according to the actual use of the air conditioner 1. It can be switched to one of the operation modes. Therefore, the control mode of the CH 40 can be easily switched by the remote controller 45 so as to match the actual usage of the air conditioner 1 by the user.

In addition, this invention is not limited to the invention concerning the said embodiment, In the range which does not deviate from the summary, it can change suitably. For example, in the above-described embodiment, an example in which the present invention is applied to the multi-air conditioner 1 has been described. However, the present invention can be similarly applied to a single-type air conditioner in which one indoor unit is connected to the outdoor unit 2. Not too long.
Moreover, although the setting operation | movement period for totaling the heating ON / OFF time by the air conditioner 1 was demonstrated as an example for 4 weeks, this period is set suitably and is not limited to 4 weeks. .

1 Air conditioner (air conditioner)
10 Compressor 40 Crankcase heater (CH)
41 control unit 42 normal operation mode control unit 43 operation reduction mode control unit 44 switching means 45 remote control

Claims (3)

In an air conditioner in which a compressor is provided with a crankcase heater, and the compressor can be heated by energizing the crankcase heater while the compressor is stopped.
In the preset operation period, the compressor always energizes the crankcase heater during the stop period, and totals the heating ON / OFF time by the air conditioner, and after the set operation period has elapsed Is provided with a control unit that calculates an OFF possible time of the crankcase heater based on the counting result, predicts the ON timing of the crankcase heater, and controls the crankcase heater ON / OFF. A featured air conditioner.   The control unit predicts the ON timing of the crankcase heater and performs an operation reduction mode in which the crankcase heater is ON / OFF controlled, and a normal operation in which the crankcase heater is always energized during the stop period of the compressor. The air conditioner according to claim 1, further comprising switching means that can be switched to any of the modes. The air conditioner according to claim 2, wherein the switching means can be switched from the remote control side.

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