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JP6897652B2 - Air conditioner - Google Patents
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JP6897652B2 - Air conditioner - Google Patents

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JP6897652B2
JP6897652B2 JP2018205760A JP2018205760A JP6897652B2 JP 6897652 B2 JP6897652 B2 JP 6897652B2 JP 2018205760 A JP2018205760 A JP 2018205760A JP 2018205760 A JP2018205760 A JP 2018205760A JP 6897652 B2 JP6897652 B2 JP 6897652B2
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rotation speed
outdoor fan
outdoor
dehumidification operation
heat exchanger
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JP2020070983A (en
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伊藤 裕
裕 伊藤
顕 木下
顕 木下
純也 米田
純也 米田
智彦 堤
智彦 堤
久瑠美 加藤
久瑠美 加藤
均 川島
均 川島
貴裕 仲田
貴裕 仲田
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Daikin Industries Ltd
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Description

本開示は、空気調和機に関する。 The present disclosure relates to an air conditioner.

従来、空気調和機としては、特開2004−108618号公報(特許文献1)に開示されているように、顕熱能力の大きな第1除湿運転と、この第1除湿運転よりも顕熱能力が小さい第2除湿運転と、この第2除湿運転よりも顕熱能力が小さい第3除湿運転とを行うものがある。 Conventionally, as an air conditioner, as disclosed in Japanese Patent Application Laid-Open No. 2004-108618 (Patent Document 1), the first dehumidifying operation having a large sensible heat capacity and the sensible heat capacity are higher than those of the first dehumidifying operation. There is a small second dehumidifying operation and a third dehumidifying operation having a sensible heat capacity smaller than that of the second dehumidifying operation.

特開2004−108618号公報Japanese Unexamined Patent Publication No. 2004-108618

上記従来の空気調和機の第3除湿運転では、室内の熱負荷に関して対応可能な範囲が狭いという問題があった。 In the third dehumidifying operation of the conventional air conditioner, there is a problem that the range that can be dealt with with respect to the heat load in the room is narrow.

本開示の課題は、第3除湿運転で室内を除湿するとき、室内の熱負荷に関して対応可能な範囲を広げることができる空気調和機を提供することにある。 An object of the present disclosure is to provide an air conditioner capable of expanding the range that can be dealt with with respect to the heat load in the room when dehumidifying the room in the third dehumidifying operation.

本開示の空気調和機は、
圧縮機、室外熱交換器、膨張機構および室内熱交換器が環状に接続され、冷媒が循環する冷媒回路と、
上記室外熱交換器に空気を送る室外ファンと、
制御部と
を備え、
上記室内熱交換器は制御弁を有し、
上記制御部は、
上記室内熱交換器の実質的に全部を蒸発域にする第1除湿運転と、
上記室内熱交換器の一部を蒸発域にする一方、上記室内熱交換器の残りの部分を過熱域にする第2除湿運転と、
上記室内熱交換器において上記制御弁よりも上流側の部分を凝縮域とする一方、上記室内熱交換器において上記制御弁よりも下流側の部分を蒸発域とする第3除湿運転と
を行うと共に、
上記第3除湿運転時における上記室外ファンの回転数の制御範囲が、上記第2除湿運転時における上記室外ファンの回転数の制御範囲よりも低い回転数を含むように広くなるように、上記室外ファンを制御する。
The air conditioner of the present disclosure is
A refrigerant circuit in which a compressor, an outdoor heat exchanger, an expansion mechanism, and an indoor heat exchanger are connected in a ring shape and a refrigerant circulates.
An outdoor fan that sends air to the above outdoor heat exchanger,
Equipped with a control unit
The indoor heat exchanger has a control valve and
The control unit
The first dehumidification operation that makes substantially all of the indoor heat exchanger an evaporation area, and
A second dehumidification operation in which a part of the indoor heat exchanger is set to an evaporation region and the remaining part of the indoor heat exchanger is set to a superheat zone.
In the indoor heat exchanger, the portion on the upstream side of the control valve is set as the condensation region, while in the indoor heat exchanger, the portion on the downstream side of the control valve is set as the evaporation region, and the third dehumidifying operation is performed. ,
The outdoor fan so that the control range of the rotation speed of the outdoor fan during the third dehumidification operation is widened to include a rotation speed lower than the control range of the rotation speed of the outdoor fan during the second dehumidification operation. Control the fan.

上記構成によれば、上記制御部が室外ファンを制御することにより、第3除湿運転時における室外ファンの回転数の制御範囲を、第2除湿運転時における室外ファンの回転数の制御範囲よりも広げることができる。したがって、上記第3除湿運転で室内を除湿するとき、室内の熱負荷に関して対応可能な範囲を広げることができる。 According to the above configuration, by controlling the outdoor fan by the control unit, the control range of the rotation speed of the outdoor fan during the third dehumidification operation is set to be larger than the control range of the rotation speed of the outdoor fan during the second dehumidification operation. Can be expanded. Therefore, when the room is dehumidified by the third dehumidifying operation, the range that can be dealt with with respect to the heat load in the room can be expanded.

一態様の空気調和機では、
上記制御部は、上記第3除湿運転時における上記室外ファンの回転数の上限値が、上記第2除湿運転時における上記室外ファンの回転数の上限値よりも高くなるように、上記室外ファンを制御する。
In one aspect of the air conditioner,
The control unit sets the outdoor fan so that the upper limit of the rotation speed of the outdoor fan during the third dehumidification operation is higher than the upper limit of the rotation speed of the outdoor fan during the second dehumidification operation. Control.

上記態様によれば、上記制御部が室外ファンを制御することにより、第3除湿運転時における室外ファンの回転数の上限値が、第2除湿運転時における室外ファンの回転数の上限値よりも高くなる。したがって、上記第3除湿運転で室内を除湿するとき、除湿効率を上げることができる。 According to the above aspect, the control unit controls the outdoor fan so that the upper limit of the rotation speed of the outdoor fan during the third dehumidification operation is higher than the upper limit of the rotation speed of the outdoor fan during the second dehumidification operation. It gets higher. Therefore, when the room is dehumidified by the third dehumidifying operation, the dehumidifying efficiency can be increased.

一態様の空気調和機では、
上記制御部は、上記第3除湿運転時における上記室外ファンの回転数の下限値が、上記第2除湿運転時における上記室外ファンの回転数の下限値よりも低くなるように、上記室外ファンを制御する。
In one aspect of the air conditioner,
The control unit sets the outdoor fan so that the lower limit of the rotation speed of the outdoor fan during the third dehumidification operation is lower than the lower limit of the rotation speed of the outdoor fan during the second dehumidification operation. Control.

上記態様によれば、上記制御部が室外ファンを制御することにより、第3除湿運転時における室外ファンの回転数の下限値が、第2除湿運転時における室外ファンの回転数の下限値よりも低くなる。したがって、上記第3除湿運転で室内を除湿するとき、いわゆるチョーク現象が冷媒回路で生じ難くなる。 According to the above aspect, by controlling the outdoor fan by the control unit, the lower limit of the rotation speed of the outdoor fan during the third dehumidification operation is larger than the lower limit of the rotation speed of the outdoor fan during the second dehumidification operation. It gets lower. Therefore, when the room is dehumidified by the third dehumidifying operation, the so-called choke phenomenon is less likely to occur in the refrigerant circuit.

一態様の空気調和機は、
外気温度を検出する室外温度センサを備え、
上記制御部は、上記第3除湿運転中、上記室外ファンの回転数が所定回転数以下になったとき、上記室外ファンの回転数が上記所定回転数以下になる直前に上記室外温度センサが検出した外気温度を用いて、上記室外ファンの回転数を調整する。
One aspect of the air conditioner is
Equipped with an outdoor temperature sensor that detects the outside air temperature
During the third dehumidifying operation, the control unit detects when the rotation speed of the outdoor fan becomes the predetermined rotation speed or less, and immediately before the rotation speed of the outdoor fan becomes the predetermined rotation speed or less, the outdoor temperature sensor detects it. The rotation speed of the outdoor fan is adjusted by using the outside air temperature.

上記態様によれば、上記第3除湿運転中、室外ファンの回転数が所定回転数以下になると、室外ファンの回転数が所定回転数以下になる直前に室外温度センサが検出した外気温度を用いて、室外ファンの回転数を調整することにより、室外ファンの回転数の調整の信頼性を高める。 According to the above aspect, when the rotation speed of the outdoor fan becomes the predetermined rotation speed or less during the third dehumidification operation, the outside air temperature detected by the outdoor temperature sensor immediately before the rotation speed of the outdoor fan becomes the predetermined rotation speed or less is used. By adjusting the rotation speed of the outdoor fan, the reliability of adjusting the rotation speed of the outdoor fan is improved.

一態様の空気調和機では、
上記制御部は、上記第3除湿運転中、上記室外ファンの回転数が上記所定回転数以下となってから、所定時間経過したとき、上記室外ファンの回転数を上記所定回転数よりも上げて、上記室外温度センサに外気温度を検出させる。
In one aspect of the air conditioner,
During the third dehumidifying operation, the control unit raises the rotation speed of the outdoor fan to be higher than the predetermined rotation speed when a predetermined time elapses after the rotation speed of the outdoor fan becomes equal to or lower than the predetermined rotation speed. , Let the outdoor temperature sensor detect the outside air temperature.

上記態様によれば、上記第3除湿運転中、上記室外ファンの回転数が所定回転数以下となってから、所定時間経過したとき、室外ファンの回転数を所定回転数よりも上げて、室外温度センサに外気温度を検出させることにより、室外温度センサが検出する室外温度と実際の室外温度との差を低減することができる。 According to the above aspect, during the third dehumidifying operation, when a predetermined time elapses after the rotation speed of the outdoor fan becomes equal to or less than the predetermined rotation speed, the rotation speed of the outdoor fan is increased above the predetermined rotation speed to the outside. By causing the temperature sensor to detect the outside air temperature, it is possible to reduce the difference between the outdoor temperature detected by the outdoor temperature sensor and the actual outdoor temperature.

本開示の第1実施形態の空気調和機の冷媒回路の回路図である。It is a circuit diagram of the refrigerant circuit of the air conditioner of 1st Embodiment of this disclosure. 上記空気調和機の制御ブロック図である。It is a control block diagram of the said air conditioner. 上記空気調和機の冷房除湿運転を説明するための模式図である。It is a schematic diagram for demonstrating the cooling dehumidification operation of the said air conditioner. 上記空気調和機の過絞り除湿運転を説明するための模式図である。It is a schematic diagram for demonstrating the over-throttle dehumidification operation of the said air conditioner. 上記空気調和機の再熱除湿運転を説明するための模式図である。It is a schematic diagram for demonstrating the reheat dehumidification operation of the said air conditioner. 上記空気調和機の冷房除湿運転、過絞り除湿運転および再熱除湿運転に関するモリエル線図である。It is a Moriel diagram regarding the cooling dehumidification operation, the over-throttle dehumidification operation, and the reheat dehumidification operation of the air conditioner. 上記空気調和機の冷房除湿運転、過絞り除湿運転および再熱除湿運転の運転条件を比較するための表である。It is a table for comparing the operation conditions of the cooling dehumidification operation, the over-throttle dehumidification operation, and the reheat dehumidification operation of the air conditioner. 本開示の第2実施形態の空気調和機の制御ブロック図である。It is a control block diagram of the air conditioner of the 2nd Embodiment of this disclosure. 本開示の第3実施形態の空気調和機の制御ブロック図である。It is a control block diagram of the air conditioner of the 3rd Embodiment of this disclosure.

以下、本開示の空気調和機を、図示の実施の形態により詳細に説明する。 Hereinafter, the air conditioner of the present disclosure will be described in detail by the illustrated embodiment.

〔第1実施形態〕
図1は、本開示の第1実施形態の空気調和機が備える冷媒回路RCの回路図である。
[First Embodiment]
FIG. 1 is a circuit diagram of a refrigerant circuit RC included in the air conditioner according to the first embodiment of the present disclosure.

上記空気調和機は、空調対象である室内に設置される室内機1と、室外に設置される室外機2とを備える。 The air conditioner includes an indoor unit 1 installed indoors to be air-conditioned and an outdoor unit 2 installed outdoors.

室内機1は、例えば、室内の壁面に取り付けられる壁掛け式の室内ユニットである。この室内機1は、室内熱交換器11と、この室内熱交換器11に空気を送る室内ファン12と、室内熱交換器11の温度を検出する室内熱交換器温度センサ51と、室内温度を検出する室内温度センサ52と、室内湿度を検出する室内湿度センサ53とを有する。 The indoor unit 1 is, for example, a wall-mounted indoor unit mounted on a wall surface of the room. The indoor unit 1 measures the indoor heat exchanger 11, the indoor fan 12 that sends air to the indoor heat exchanger 11, the indoor heat exchanger temperature sensor 51 that detects the temperature of the indoor heat exchanger 11, and the indoor temperature. It has an indoor temperature sensor 52 for detecting and an indoor humidity sensor 53 for detecting indoor humidity.

室内熱交換器11は、室内ファン12による空気流に関して、室内ファン12よりも上流側に位置している。この室内熱交換器11は、室内ファン12からの空気と冷媒との熱交換を行うために、本体熱交換部11aと、補助熱交換部11bと、制御弁の一例としての電磁弁13とを有する。 The indoor heat exchanger 11 is located on the upstream side of the indoor fan 12 with respect to the air flow by the indoor fan 12. The indoor heat exchanger 11 includes a main body heat exchange unit 11a, an auxiliary heat exchange unit 11b, and an electromagnetic valve 13 as an example of a control valve in order to exchange heat between the air from the indoor fan 12 and the refrigerant. Have.

本体熱交換部11aは、室内ユーザ側に位置する正面部11a−1と、室内ユーザ側とは反対側に位置する背面部11a−2とから成っている。また、正面部11a−1は、冷媒配管L1,L2および電磁弁13を介して背面部11a−2に流体的に接続されている。これにより、膨張弁24から本体熱交換部11aへ流れる冷媒は、正面部11a−1を流れた後、背面部11a−2に流入することが可能となっている。 The main body heat exchange portion 11a includes a front portion 11a-1 located on the indoor user side and a back portion 11a-2 located on the side opposite to the indoor user side. Further, the front portion 11a-1 is fluidly connected to the back portion 11a-2 via the refrigerant pipes L1 and L2 and the solenoid valve 13. As a result, the refrigerant flowing from the expansion valve 24 to the main body heat exchange portion 11a can flow into the back portion 11a-2 after flowing through the front portion 11a-1.

補助熱交換部11bは、本体熱交換部11aの正面部11a−1に関して本体熱交換部11aの背面部11a−2側とは反対側に設けられている。すなわち、補助熱交換部11bは、本体熱交換部11aの正面部11a−1よりも、室内ユーザ側に位置する。この補助熱交換部11bは、本体熱交換部11aよりも、容積が小さい。また、補助熱交換部11bは、冷媒配管L11を介して本体熱交換部11aの正面部11a−1に流体的に接続されている。これにより、膨張弁24側からの冷媒は、補助熱交換部11bを介して、本体熱交換部11aに供給される。このように、補助熱交換部11bは、冷媒配管L3と冷媒配管L11との間の冷媒パスを有するものと言える。 The auxiliary heat exchange portion 11b is provided on the side opposite to the back surface portion 11a-2 side of the main body heat exchange portion 11a with respect to the front portion 11a-1 of the main body heat exchange portion 11a. That is, the auxiliary heat exchange unit 11b is located closer to the indoor user than the front portion 11a-1 of the main body heat exchange unit 11a. The volume of the auxiliary heat exchange unit 11b is smaller than that of the main body heat exchange unit 11a. Further, the auxiliary heat exchange portion 11b is fluidly connected to the front portion 11a-1 of the main body heat exchange portion 11a via the refrigerant pipe L11. As a result, the refrigerant from the expansion valve 24 side is supplied to the main body heat exchange unit 11a via the auxiliary heat exchange unit 11b. As described above, it can be said that the auxiliary heat exchange unit 11b has a refrigerant path between the refrigerant pipe L3 and the refrigerant pipe L11.

室内ファン12としては、例えば、クロスフローファンが採用される。このクロスフローファンは、室内熱交換器11で温度などが調整された空気を室内に向けて吹き出す。 As the indoor fan 12, for example, a cross flow fan is adopted. This cross-flow fan blows out air whose temperature and the like are adjusted by the indoor heat exchanger 11 toward the room.

電磁弁13は、電磁弁13は、室内熱交換器11の冷媒パスの中間部に設けられている。より詳しく説明すると、本体熱交換部11aの正面部11a−1側と本体熱交換部11aの正面部11a−1側との間に差圧を設定するための弁である。電磁弁13は、大開度および小開度の2位置のみを取ることが可能なオンオフ弁であり、必要時(例えば、後述する再熱除湿運転時)にオンされ、大開度の位置から小開度の位置に切り替えられる。 The solenoid valve 13 is provided in the middle portion of the refrigerant path of the indoor heat exchanger 11. More specifically, it is a valve for setting a differential pressure between the front portion 11a-1 side of the main body heat exchange portion 11a and the front portion 11a-1 side of the main body heat exchange portion 11a. The solenoid valve 13 is an on / off valve that can take only two positions, a large opening and a small opening, and is turned on when necessary (for example, during reheat dehumidification operation described later) and slightly opened from the position of the large opening. It can be switched to the degree position.

室外機2は、圧縮機21と、四路切換弁22と、室外熱交換器23と、膨張機構の一例としての膨張弁24と、アキュムレータ25と、室外熱交換器23に空気を送る室外ファン26とを有する。さらに、室外機2は、室外熱交換器23の温度を検出する室外熱交換器温度センサ56と、外気温度を検出する外気温度センサ57と、膨張弁24で減圧された冷媒の温度(蒸発温度)を検出する冷媒温度センサ58とを有する。なお、冷媒温度センサ58は、第1冷媒温度センサの一例である。 The outdoor unit 2 includes a compressor 21, a four-way switching valve 22, an outdoor heat exchanger 23, an expansion valve 24 as an example of an expansion mechanism, an accumulator 25, and an outdoor fan that sends air to the outdoor heat exchanger 23. It has 26 and. Further, the outdoor unit 2 includes an outdoor heat exchanger temperature sensor 56 that detects the temperature of the outdoor heat exchanger 23, an outside air temperature sensor 57 that detects the outside air temperature, and the temperature (evaporation temperature) of the refrigerant decompressed by the expansion valve 24. ) Is detected by the refrigerant temperature sensor 58. The refrigerant temperature sensor 58 is an example of the first refrigerant temperature sensor.

室外熱交換器23は、室外ファン26による空気流に関して、室外ファン26よりも下流側に位置している。室外熱交換器23内を流れる冷媒は、室内ファン12からの空気と熱交換する。 The outdoor heat exchanger 23 is located on the downstream side of the outdoor fan 26 with respect to the air flow by the outdoor fan 26. The refrigerant flowing in the outdoor heat exchanger 23 exchanges heat with the air from the indoor fan 12.

膨張弁24は、互いに異なる3以上の開度に調整可能な例えば電動弁であって、制御部の一例としての制御装置100(図2に示す)からの信号に応じて開度が変化する。 The expansion valve 24 is, for example, an electric valve that can be adjusted to three or more opening degrees different from each other, and the opening degree changes according to a signal from a control device 100 (shown in FIG. 2) as an example of the control unit.

また、上記空気調和機の冷媒回路RCは、室内熱交換器11、圧縮機21、四路切換弁22、室外熱交換器23、膨張弁24、アキュムレータ25および冷媒配管L3〜L9から成っている。より詳しく説明すると、室内熱交換器11、圧縮機21、四路切換弁22、室外熱交換器23、膨張弁24およびアキュムレータ25が、冷媒配管L3〜L9によって流体的に接続される。これにより、環状の冷媒回路RCが構成されている。このような冷媒回路RCにおいて、圧縮機21の駆動時、冷媒が循環する。 The refrigerant circuit RC of the air conditioner includes an indoor heat exchanger 11, a compressor 21, a four-way switching valve 22, an outdoor heat exchanger 23, an expansion valve 24, an accumulator 25, and refrigerant pipes L3 to L9. .. More specifically, the indoor heat exchanger 11, the compressor 21, the four-way switching valve 22, the outdoor heat exchanger 23, the expansion valve 24, and the accumulator 25 are fluidly connected by the refrigerant pipes L3 to L9. As a result, the annular refrigerant circuit RC is configured. In such a refrigerant circuit RC, the refrigerant circulates when the compressor 21 is driven.

外気温度センサ57は、室外ファン26による空気流に関して、室外熱交換器23よりも上流側に位置している。すなわち、室内ファン12の駆動時、室外熱交換器23と熱交換する前の室外空気が外気温度センサ57を経由するようになっている。 The outside air temperature sensor 57 is located upstream of the outdoor heat exchanger 23 with respect to the air flow by the outdoor fan 26. That is, when the indoor fan 12 is driven, the outdoor air before heat exchange with the outdoor heat exchanger 23 passes through the outside air temperature sensor 57.

また、図示しないが、上記空気調和機は、リモートコントローラ(以下、「リモコン」と言う。)を備える。ユーザは、リモコンを操作して、自動運転、冷房運転、暖房運転、除湿運転などを開始させたり、停止させたりすることができる。 Although not shown, the air conditioner includes a remote controller (hereinafter, referred to as "remote controller"). The user can operate the remote controller to start or stop the automatic operation, the cooling operation, the heating operation, the dehumidifying operation, and the like.

図2は、上記空気調和機の制御ブロック図である。 FIG. 2 is a control block diagram of the air conditioner.

上記空気調和機は、冷媒回路RCを制御する制御装置100を備える。より詳しく説明すると、制御装置100は、マイクロコンピュータ、入出力回路などから成っている。この制御装置100が、室内熱交換器温度センサ51、室内温度センサ52、室内湿度センサ53、室外熱交換器温度センサ56、外気温度センサ57、冷媒温度センサ58などからの信号に基づいて、圧縮機21、四路切換弁22、膨張弁24、室外ファン26、室内ファン12、電磁弁13などを制御する。なお、制御装置100は制御部の一例である。 The air conditioner includes a control device 100 that controls the refrigerant circuit RC. More specifically, the control device 100 includes a microprocessor, an input / output circuit, and the like. The control device 100 compresses based on signals from the indoor heat exchanger temperature sensor 51, the indoor temperature sensor 52, the indoor humidity sensor 53, the outdoor heat exchanger temperature sensor 56, the outside air temperature sensor 57, the refrigerant temperature sensor 58, and the like. It controls the machine 21, the four-way switching valve 22, the expansion valve 24, the outdoor fan 26, the indoor fan 12, the electromagnetic valve 13, and the like. The control device 100 is an example of a control unit.

また、制御装置100は、冷房除湿運転を行う冷房除湿運転制御部100aと、過絞り除湿運転を行う過絞り除湿運転制御部100bと、再熱除湿運転を行う再熱除湿運転制御部100cとを有する。この冷房除湿運転制御部100a、過絞り除湿運転制御部100bおよび再熱除湿運転制御部100cは、それぞれ、ソフトウェアにより構成されている。なお、上記冷房除湿運転は、第1除湿運転の一例である。また、上記過絞り除湿運転は、第2除湿運転の一例である。また、上記再熱除湿運転は、第3除湿運転の一例である。 Further, the control device 100 includes a cooling dehumidification operation control unit 100a that performs a cooling dehumidification operation, an overthrottle dehumidification operation control unit 100b that performs an overslot dehumidification operation, and a reheat dehumidification operation control unit 100c that performs a reheat dehumidification operation. Have. The cooling dehumidification operation control unit 100a, the over-throttle dehumidification operation control unit 100b, and the reheat dehumidification operation control unit 100c are each composed of software. The cooling dehumidification operation is an example of the first dehumidification operation. The over-squeezing dehumidifying operation is an example of the second dehumidifying operation. The reheat dehumidification operation is an example of the third dehumidification operation.

[冷房除湿運転]
上記冷房除湿運転は、図1に示すように、四路切換弁22を実線の切換え位置に切り換えると共に、圧縮機21を起動することで、開始される。この冷房除湿運転中、圧縮機21から吐出された高温高圧の冷媒が四路切換弁22を介して室外熱交換器23に流入する。そして、室外熱交換器23で凝縮した冷媒は、膨張弁24で減圧された後、室内熱交換器11の補助熱交換部11bと、室内熱交換器11の本体熱交換部11aとに、この順で流入する。この本体熱交換部11aおよび補助熱交換部11bで蒸発した冷媒が四路切換弁22およびアキュムレータ25を介して圧縮機21の吸入側に戻る。このように、冷媒が冷媒回路RCを循環するとき、冷房除湿運転制御部100aが、圧縮機21の周波数と膨張弁24の開度とを調整すると共に、電磁弁13をオフにすることで、図3に示すように、室内熱交換器11の実質的に全部を蒸発域(図3において斜線のハッチングを付した領域)とする。これにより、上記冷房除湿運転は、室内温度を変化させるための能力である顕熱能力が高くなる。
[Cooling and dehumidifying operation]
As shown in FIG. 1, the cooling / dehumidifying operation is started by switching the four-way switching valve 22 to the solid line switching position and activating the compressor 21. During this cooling / dehumidifying operation, the high-temperature and high-pressure refrigerant discharged from the compressor 21 flows into the outdoor heat exchanger 23 via the four-way switching valve 22. Then, the refrigerant condensed by the outdoor heat exchanger 23 is decompressed by the expansion valve 24, and then the auxiliary heat exchange portion 11b of the indoor heat exchanger 11 and the main body heat exchange portion 11a of the indoor heat exchanger 11 are subjected to this. Inflow in order. The refrigerant evaporated in the main body heat exchange section 11a and the auxiliary heat exchange section 11b returns to the suction side of the compressor 21 via the four-way switching valve 22 and the accumulator 25. In this way, when the refrigerant circulates in the refrigerant circuit RC, the cooling / dehumidifying operation control unit 100a adjusts the frequency of the compressor 21 and the opening degree of the expansion valve 24, and turns off the solenoid valve 13. As shown in FIG. 3, substantially the entire indoor heat exchanger 11 is defined as an evaporation region (the region shaded in FIG. 3). As a result, the cooling / dehumidifying operation has a high sensible heat capacity, which is the ability to change the room temperature.

ここで、室内熱交換器11の実質的に全部を蒸発域にするとは、室内熱交換器11の全部を蒸発域にするときだけでなく、室内熱交換器11において一部を除いた部分だけを蒸発域にするときも含む。この一部(例えば、室内熱交換器11の全容積の1/3以下の部分)だけが蒸発域とならないときとしては、例えば、室内環境などによって、室内熱交換器11の冷媒出口近傍の部分が過熱域となるときなどがある。 Here, to make substantially all of the indoor heat exchanger 11 an evaporation region is not only when the entire indoor heat exchanger 11 is made into an evaporation region, but also only a part of the indoor heat exchanger 11 excluding a part. Including when making the evaporation area. When only a part of this (for example, a part of 1/3 or less of the total volume of the indoor heat exchanger 11) does not become an evaporation region, for example, a part near the refrigerant outlet of the indoor heat exchanger 11 depending on the indoor environment or the like. Is sometimes overheated.

[過絞り除湿運転]
上記過絞り除湿運転は、上記冷房除湿運転のときと同じ方向に冷媒を流す。このとき、過絞り除湿運転制御部100bが、圧縮機21の周波数と膨張弁24の開度とを調整すると共に、電磁弁13をオフにすることで、図4に示すように、補助熱交換部11bを蒸発域(斜線のハッチングを付した領域)にする一方、本体熱交換部11aの正面部11a−1および背面部11a−2を過熱域(点のハッチングを付した領域)にする。これにより、上記過絞り除湿運転は、冷房除湿運転によりも顕熱能力が低くなるので、室内の熱負荷が高くも低くもないとき、室温の低下を抑制しつつ、室内の除湿を行える。
[Over-throttle dehumidification operation]
In the over-squeezing dehumidifying operation, the refrigerant flows in the same direction as in the cooling / dehumidifying operation. At this time, the over-throttle dehumidification operation control unit 100b adjusts the frequency of the compressor 21 and the opening degree of the expansion valve 24 and turns off the solenoid valve 13 to exchange auxiliary heat as shown in FIG. The portion 11b is set as an evaporation region (region with hatched diagonal lines), while the front portion 11a-1 and the back portion 11a-2 of the main body heat exchange portion 11a are set as an overheating region (region with hatched points). As a result, the sensible heat capacity of the over-squeezing dehumidifying operation is lower than that of the cooling dehumidifying operation. Therefore, when the heat load in the room is neither high nor low, it is possible to dehumidify the room while suppressing a decrease in room temperature.

また、過絞り除湿運転制御部100bは、過絞り除湿運転中、蒸発域が所定容積(例えば、室内熱交換器11の全容積の2/3)以下となるように、圧縮機21および膨張弁24を制御する。 Further, the over-throttle dehumidification operation control unit 100b has a compressor 21 and an expansion valve so that the evaporation area becomes a predetermined volume (for example, 2/3 of the total volume of the indoor heat exchanger 11) during the over-throttle dehumidification operation. 24 is controlled.

[再熱除湿運転]
上記再熱除湿運転は、上記冷房除湿運転のときと同じ方向に冷媒を流す。このとき、再熱除湿運転制御部100cが、圧縮機21の周波数と膨張弁24の開度とを調整すると共に、電磁弁13をオンにすることで、図5に示すように、補助熱交換部11bと本体熱交換部11aの正面部11a−1とを凝縮域(格子のハッチングを付した領域)にする一方、本体熱交換部11aの背面部11a−2を蒸発域(斜線のハッチングを付した領域)にする。これにより、上記再熱除湿運転は、過絞り除湿運転よりも顕熱能力が低くなるので、室内の熱負荷が低いとき、室温の低下を抑制しつつ、室内の除湿を行える。
[Reheat dehumidification operation]
In the reheat dehumidification operation, the refrigerant flows in the same direction as in the cooling dehumidification operation. At this time, the reheat dehumidification operation control unit 100c adjusts the frequency of the compressor 21 and the opening degree of the expansion valve 24, and turns on the electromagnetic valve 13 to exchange auxiliary heat as shown in FIG. While the portion 11b and the front portion 11a-1 of the main body heat exchange portion 11a are set as a condensation region (region with lattice hatching), the back portion 11a-2 of the main body heat exchange portion 11a is set as an evaporation region (hatched diagonal line). (Attached area). As a result, the reheat dehumidification operation has a lower sensible heat capacity than the over-squeeze dehumidification operation. Therefore, when the heat load in the room is low, the room can be dehumidified while suppressing the decrease in room temperature.

また、上記再熱除湿運転では、電磁弁13は、小開度の位置に切り替えられる。すなわち、上記再熱除湿運転における電磁弁13の開度は、空気流量が10L/min未満に相当する開度である。上記再熱除湿運転における電磁弁13の開度は、空気流量が5L/minに相当する開度であれば好ましい。さらに、上記再熱除湿運転における電磁弁13の開度は、空気流量が3.5L/minに相当する開度であれば好ましい。ここで、「上記再熱除湿運転における電磁弁13の開度が、空気流量が10L/min未満に相当する開度である」とは、上記開度において冷媒回路RCを流れる空気流量が10L/min未満であることをいうのではなく、電磁弁13の流量特性から求められる上記開度における空気流量が10L/min未満であることをいう。 Further, in the reheat dehumidification operation, the solenoid valve 13 is switched to a position having a small opening degree. That is, the opening degree of the solenoid valve 13 in the reheat dehumidification operation is an opening degree corresponding to an air flow rate of less than 10 L / min. The opening degree of the solenoid valve 13 in the reheat dehumidification operation is preferably an opening degree corresponding to an air flow rate of 5 L / min. Further, the opening degree of the solenoid valve 13 in the reheat dehumidification operation is preferably an opening degree corresponding to an air flow rate of 3.5 L / min. Here, "the opening degree of the solenoid valve 13 in the reheat dehumidification operation is an opening degree corresponding to an air flow rate of less than 10 L / min" means that the air flow rate flowing through the refrigerant circuit RC at the above opening degree is 10 L / min. It does not mean that it is less than min, but that the air flow rate at the opening degree obtained from the flow rate characteristics of the solenoid valve 13 is less than 10 L / min.

上記冷房除湿運転、過絞り除湿運転または再熱除湿運転は、リモコンの除湿運転のボタンの押下に応じて開始するようになっている。より詳しく説明すると、上記除湿運転のボタが押下されると、例えば顕熱比に基づいて、冷房除湿運転、過絞り除湿運転および再熱除湿運転のうちの一つの除湿運転が自動的に選択されて開始する。その後、上記顕熱比の変化に応じて、他の除湿運転に自動的に切り替わる。なお、上記顕熱比とは、全熱(=顕熱+潜熱)に対する顕熱の比を指す。 The cooling dehumidifying operation, the over-squeezing dehumidifying operation, or the reheat dehumidifying operation is started in response to pressing the button of the dehumidifying operation of the remote controller. More specifically, when the dehumidification operation button is pressed, one of the cooling dehumidification operation, the over-squeeze dehumidification operation, and the reheat dehumidification operation is automatically selected based on, for example, the sensible heat ratio. To start. After that, it automatically switches to another dehumidifying operation according to the change in the sensible heat ratio. The sensible heat ratio refers to the ratio of sensible heat to total heat (= sensible heat + latent heat).

図6は、上記空気調和機の冷房除湿運転時、過絞り除湿運転時および再熱除湿運転時のモリエル線図である。 FIG. 6 is a Moriel diagram during the cooling dehumidifying operation, the over-squeezing dehumidifying operation, and the reheat dehumidifying operation of the air conditioner.

過絞り除湿運転制御部100bの制御は、過絞り除湿運転の蒸発温度は、冷房除湿運転の蒸発温度よりも低くなるように行われる。このとき、膨張弁24の開度は、通常、冷房除湿運転中の膨張弁24の開度よりも小さくなる。 The control of the over-throttle dehumidification operation control unit 100b is performed so that the evaporation temperature of the over-throttle dehumidification operation is lower than the evaporation temperature of the cooling dehumidification operation. At this time, the opening degree of the expansion valve 24 is usually smaller than the opening degree of the expansion valve 24 during the cooling / dehumidifying operation.

再熱除湿運転制御部100cの制御は、再熱除湿運転の蒸発温度が過絞り除湿運転の蒸発温度よりも低くなるように行われる。このとき、膨張弁24の開度は、過絞り除湿運転中における膨張弁24の最大開度よりも大きい開度に固定される。 The reheat dehumidification operation control unit 100c is controlled so that the evaporation temperature of the reheat dehumidification operation is lower than the evaporation temperature of the over-throttle dehumidification operation. At this time, the opening degree of the expansion valve 24 is fixed to an opening degree larger than the maximum opening degree of the expansion valve 24 during the over-throttle dehumidification operation.

図7は、上記空気調和機の冷房除湿運転、過絞り除湿運転および再熱除湿運転の運転条件を比較するための表を示す。 FIG. 7 shows a table for comparing the operating conditions of the cooling dehumidifying operation, the over-throttle dehumidifying operation, and the reheat dehumidifying operation of the air conditioner.

再熱除湿運転制御部100cは、再熱除湿運転時における室外ファン26の回転数の制御範囲が、過絞り除湿運転時における室外ファン26の回転数の制御範囲よりも広くなるように、室外ファン26を制御する。このとき、過絞り除湿運転時における室外ファン26の回転数の上限値は例えば730rpmに設定される一方、再熱除湿運転時における室外ファン26の回転数の上限値は例えば540rmpに設定される。また、過絞り除湿運転時における室外ファン26の回転数の下限値は例えば150rpmに設定される一方、再熱除湿運転時における室外ファン26の回転数の下限値は例えば300rpmに設定される。 The reheat dehumidification operation control unit 100c is an outdoor fan so that the control range of the rotation speed of the outdoor fan 26 during the reheat dehumidification operation is wider than the control range of the rotation speed of the outdoor fan 26 during the over-throttle dehumidification operation. 26 is controlled. At this time, the upper limit of the rotation speed of the outdoor fan 26 during the over-throttle dehumidification operation is set to, for example, 730 rpm, while the upper limit of the rotation speed of the outdoor fan 26 during the reheat dehumidification operation is set to, for example, 540 rpm. To. Furthermore, while the rotational speed of the lower limit of the outdoor fan 26 during operation over the diaphragm dehumidification is set to, for example, 15 0 rpm, the lower limit rotation speed of the outdoor fan 26 during reheat dehumidification operation is set to, for example, 30 0 rpm ..

また、膨張弁24の開度は、パルス信号によって調整される。このパルス信号のパルス数は、膨張弁24の開度と比例する。すなわち、上記パルス数が増えにつれて、膨張弁24の開度は大きくなる。 Further, the opening degree of the expansion valve 24 is adjusted by a pulse signal. The number of pulses of this pulse signal is proportional to the opening degree of the expansion valve 24. That is, as the number of pulses increases, the opening degree of the expansion valve 24 increases.

上記構成の空気調和機では、リモコンの除湿運転のボタンが押下された後、再熱除湿運転が開始すると、再熱除湿運転制御部100cが室外ファン26を制御する。これにより、再熱除湿運転時における室外ファン26の回転数の制御範囲を、過絞り除湿運転時における室外ファン26の回転数の制御範囲よりも広げることができる。したがって、上記再熱除湿運転で室内を除湿するとき、室内の熱負荷に関して対応可能な範囲を広げることができる。 In the air conditioner having the above configuration, when the reheat dehumidification operation is started after the dehumidification operation button on the remote controller is pressed, the reheat dehumidification operation control unit 100c controls the outdoor fan 26. As a result, the control range of the rotation speed of the outdoor fan 26 during the reheat dehumidification operation can be expanded beyond the control range of the rotation speed of the outdoor fan 26 during the over-throttle dehumidification operation. Therefore, when the room is dehumidified by the reheat dehumidification operation, the range that can be dealt with with respect to the heat load in the room can be expanded.

また、上記再熱除湿運転時における室外ファン26の回転数の上限値は、過絞り除湿運転時における室外ファン26の回転数の上限値よりも高い。これにより、上記過絞り除湿運転時における冷媒の蒸発温度よりも、再熱除湿運転時における冷媒の蒸発温度を下げることができる。したがって、上記再熱除湿運転で室内を除湿するとき、除湿効率を上げることができる。 Further, the upper limit of the rotation speed of the outdoor fan 26 during the reheat dehumidification operation is higher than the upper limit of the rotation speed of the outdoor fan 26 during the over-throttle dehumidification operation. As a result, the evaporation temperature of the refrigerant during the reheat dehumidification operation can be lowered from the evaporation temperature of the refrigerant during the over-throttle dehumidification operation. Therefore, when the room is dehumidified by the reheat dehumidification operation, the dehumidification efficiency can be improved.

また、上記再熱除湿運転時における室外ファン26の回転数の下限値は、過絞り除湿運転時における室外ファン26の回転数の下限値よりも低い。これにより、上記再熱除湿運転時、室外熱交換器23と室内熱交換器11との間における冷媒の圧力が過度に低下するのを抑制することができる。したがって、上記再熱除湿運転で室内を除湿するとき、チョーク現象の発生を抑制することができる。 Further, the lower limit of the rotation speed of the outdoor fan 26 during the reheat dehumidification operation is lower than the lower limit of the rotation speed of the outdoor fan 26 during the over-throttle dehumidification operation. As a result, it is possible to prevent the pressure of the refrigerant between the outdoor heat exchanger 23 and the indoor heat exchanger 11 from being excessively lowered during the reheat dehumidification operation. Therefore, when the room is dehumidified by the reheat dehumidification operation, the occurrence of the choke phenomenon can be suppressed.

上記第1実施形態では、リモコンの除湿運転のボタンが押下されると、冷房除湿運転、過絞り除湿運転および再熱除湿運転のうちの一つの除湿運転が適宜選択されて行われていたが、リモコンの自動運転のボタンが押下されても、冷房除湿運転、過絞り除湿運転および再熱除湿運転のうちの一つの除湿運転が適宜選択されて行われるようにしてもよい。ここで、上記自動運転は、室内温度、室外温度などに基づいて、冷房運転、除湿運転、暖房運転などから一つが自動的に選択されて開始した後、自動的に他の空調運転に切り替わるものである。すなわち、例えば、上記自動運転の除湿運転において過絞り除湿運転が自動的に開始してもよい。また、上記自動運転の除湿運転では、冷房除湿運転、過絞り除湿運転および再熱除湿運転は、例えば顕熱比の変化に応じて、自動的に互いに切り替わるようにしてもよい。 In the first embodiment, when the dehumidifying operation button on the remote control is pressed, one of the cooling dehumidifying operation, the over-squeezing dehumidifying operation, and the reheat dehumidifying operation is appropriately selected and performed. Even if the automatic operation button on the remote control is pressed, one of the cooling dehumidifying operation, the over-squeezing dehumidifying operation, and the reheat dehumidifying operation may be appropriately selected and performed. Here, in the above automatic operation, one is automatically selected from the cooling operation, the dehumidifying operation, the heating operation, etc. based on the indoor temperature, the outdoor temperature, etc., and then automatically switched to the other air conditioning operation. Is. That is, for example, the over-squeezing dehumidifying operation may be automatically started in the dehumidifying operation of the automatic operation. Further, in the dehumidification operation of the automatic operation, the cooling dehumidification operation, the over-squeeze dehumidification operation, and the reheat dehumidification operation may be automatically switched to each other in response to a change in the sensible heat ratio, for example.

上記第1実施形態では、室内熱交換器11は、本体熱交換部11aと補助熱交換部11bを有していたが、本体熱交換部11aを有する一方、補助熱交換部11bを有さないようにしてもよい。このようにする場合、過絞り除湿運転時、本体熱交換部11aの一部だけが蒸発域となるようにすればよい。 In the first embodiment, the indoor heat exchanger 11 has a main body heat exchange unit 11a and an auxiliary heat exchange unit 11b, but has a main body heat exchange unit 11a but does not have an auxiliary heat exchange unit 11b. You may do so. In this case, during the over-throttle dehumidification operation, only a part of the main body heat exchange unit 11a may be in the evaporation region.

上記第1実施形態では、本体熱交換部11aの正面部11a−1側と本体熱交換部11aの正面部11a−1側との間に、電磁弁13を設けていたが、互いに異なる3以上の開度に調整可能な電動弁を制御弁の一例として設けてもよい。 In the first embodiment, the solenoid valve 13 is provided between the front portion 11a-1 side of the main body heat exchange portion 11a and the front portion 11a-1 side of the main body heat exchange portion 11a, but three or more different from each other. An electric valve that can be adjusted to the opening degree of the above may be provided as an example of the control valve.

上記第1実施形態において、制御装置100は、室内機1側の室内制御部(図示せず)と、室外機2側の室外制御部(図示せず)とで構成されてもよいし、上記室内制御部のみで構成されるようにしてもよいし、上記室外制御部のみで構成されてもよい。別の言い方をすれば、制御装置100は、一部が室内機1に搭載され、かつ、残りの他の部分が室外機2に搭載されるようにしてもよいし、全部が室内機1に搭載されるようにしてもよいし、全部が室外機2に搭載されるようにしてもよい。 In the first embodiment, the control device 100 may be composed of an indoor control unit (not shown) on the indoor unit 1 side and an outdoor control unit (not shown) on the outdoor unit 2 side. It may be composed only of the indoor control unit, or may be composed only of the outdoor control unit. In other words, the control device 100 may be partially mounted on the indoor unit 1 and the remaining other portion mounted on the outdoor unit 2, or the entire control device 100 may be mounted on the indoor unit 1. It may be mounted, or all of them may be mounted on the outdoor unit 2.

上記第1実施形態では、冷房除湿運転制御部100a、過絞り除湿運転制御部100bおよび再熱除湿運転制御部100cは、それぞれ、ソフトウェアにより構成されていたが、冷房除湿運転制御部100a、過絞り除湿運転制御部100bおよび再熱除湿運転制御部100cのうちの少なくとも一つが、ハードウェアにより構成されるようにしてもよい。 In the first embodiment, the cooling dehumidifying operation control unit 100a, the over-squeezing dehumidifying operation control unit 100b, and the reheat dehumidifying operation control unit 100c are respectively composed of software, but the cooling dehumidifying operation control unit 100a and the over-squeezing At least one of the dehumidifying operation control unit 100b and the reheat dehumidifying operation control unit 100c may be configured by hardware.

上記第1実施形態において、再熱除湿運転制御部100cは、室外ファン26の回転数が最大回転数になってから、再熱除湿運転が終わるように、室外ファン26を制御してもよい。すなわち、再熱除湿運転が終わる直前に、室外ファン26の回転数が最大回転数になってもよい。これにより、上記再熱除湿運転後、電磁弁13のオフが容易となる。 In the first embodiment, the reheat dehumidification operation control unit 100c may control the outdoor fan 26 so that the reheat dehumidification operation ends after the rotation speed of the outdoor fan 26 reaches the maximum rotation speed. That is, the rotation speed of the outdoor fan 26 may reach the maximum rotation speed immediately before the end of the reheat dehumidification operation. As a result, the solenoid valve 13 can be easily turned off after the reheat dehumidification operation.

〔第2実施形態〕
図8は、本開示の第2実施形態の空気調和機の制御ブロック図である。なお、図8において、図1の構成部と同一構成部は、図2の構成部の参照番号と同一参照番号を付している。
[Second Embodiment]
FIG. 8 is a control block diagram of the air conditioner according to the second embodiment of the present disclosure. In addition, in FIG. 8, the same component as the component of FIG. 1 is assigned the same reference number as the reference number of the component of FIG.

上記空気調和機は、マイクロコンピュータ、入出力回路などから成る制御装置200を備える。この制御装置200は、冷房除湿運転制御部100aおよび過絞り除湿制御部100bの他に、上記第1実施形態の再熱除湿運転制御部100cとは異なる再熱除湿運転制御部200cと、外気温度センサ57によって検出された外気温度を所定時間間隔(例えば0.5秒間隔)で記憶する記憶部200dとを有する。なお、制御装置200は制御部の一例である。 The air conditioner includes a control device 200 including a microcomputer, an input / output circuit, and the like. In addition to the cooling dehumidification operation control unit 100a and the over-throttle dehumidification control unit 100b, the control device 200 includes a reheat dehumidification operation control unit 200c different from the reheat dehumidification operation control unit 100c of the first embodiment, and an outside air temperature. It has a storage unit 200d that stores the outside air temperature detected by the sensor 57 at predetermined time intervals (for example, 0.5 second intervals). The control device 200 is an example of a control unit.

再熱除湿運転制御部200cは、再熱除湿運転中、室外ファン26の回転数(例えば150rpm)が所定回転数以下になったとき、室外ファン26の回転数が所定回転数以下になる直前に外気温度センサ57が検出した外気温度を用いて、室外ファン26の回転数を調整する。より詳しく説明すると、再熱除湿運転が開始されると、記憶部200dに記憶された外気温度の中から、室外ファン26の回転数が所定回転数以下になる直前に、外気温度センサ57によって検出された外気温度を選択する。この選択された外気温度と、予め作成されたテーブルとを用いて、室外ファン26の回転数が調整される。 During the reheat dehumidifying operation, the reheat dehumidifying operation control unit 200c receives when the rotation speed of the outdoor fan 26 (for example, 150 rpm) becomes less than or equal to the predetermined rotation speed, immediately before the rotation speed of the outdoor fan 26 becomes less than or equal to the predetermined rotation speed. The rotation speed of the outdoor fan 26 is adjusted using the outside air temperature detected by the outside air temperature sensor 57. More specifically, when the reheat dehumidification operation is started, it is detected by the outside air temperature sensor 57 from the outside air temperature stored in the storage unit 200d just before the rotation speed of the outdoor fan 26 becomes equal to or less than the predetermined rotation speed. Select the outside air temperature. The rotation speed of the outdoor fan 26 is adjusted using the selected outside air temperature and the table created in advance.

上記構成の空気調和機では、再熱除湿運転中、室外ファン26の回転数が所定回転数以下になると、室外ファン26の回転数が所定回転数以下になる直前に外気温度センサ57が検出した外気温度を用いて、室外ファン26の回転数を調整することにより、その調整の信頼性が高まる。 In the air conditioner having the above configuration, when the rotation speed of the outdoor fan 26 becomes the predetermined rotation speed or less during the reheat dehumidification operation, the outside air temperature sensor 57 detects the rotation speed of the outdoor fan 26 immediately before the predetermined rotation speed or less. By adjusting the rotation speed of the outdoor fan 26 using the outside air temperature, the reliability of the adjustment is enhanced.

上記再熱除湿運転中、室外ファン26の回転数が所定回転数以下になると、外気温度センサ57へ流れる室外空気の量が減るため、外気温度センサ57によって検出される室外温度が実際の室外温度から大きく外れる可能性がある。したがって、仮に、室外ファン26の回転数が所定回転数以下になった後に、外気温度センサ57によって検出された外気温度を用いて、室外ファン26の回転数を調整したなら、室外ファン26の回転数の調整が不適切なものになる恐れがある。 During the reheat dehumidifying operation, when the rotation speed of the outdoor fan 26 becomes equal to or less than the predetermined rotation speed, the amount of outdoor air flowing to the outside air temperature sensor 57 decreases, so that the outdoor temperature detected by the outside air temperature sensor 57 is the actual outdoor temperature. It may deviate significantly from. Therefore, if the rotation speed of the outdoor fan 26 is adjusted to be adjusted by using the outside air temperature detected by the outside air temperature sensor 57 after the rotation speed of the outdoor fan 26 becomes equal to or less than the predetermined rotation speed, the rotation speed of the outdoor fan 26 is adjusted. The number adjustment may be inappropriate.

上記第2実施形態では、外気温度センサ57によって検出された外気温度は、制御装置200内の記憶部200dに記憶されていたが、制御装置200外に設けられた記憶装置(例えば、フラッシュメモリなど)に記憶されるようにしてもよい。 In the second embodiment, the outside air temperature detected by the outside air temperature sensor 57 is stored in the storage unit 200d inside the control device 200, but a storage device provided outside the control device 200 (for example, a flash memory or the like). ) May be stored.

〔第3実施形態〕
図9は、本開示の第3実施形態の空気調和機の制御ブロック図である。なお、図9において、図1の構成部と同一構成部は、図2の構成部の参照番号と同一参照番号を付している。
[Third Embodiment]
FIG. 9 is a control block diagram of the air conditioner according to the third embodiment of the present disclosure. In addition, in FIG. 9, the same component as the component of FIG. 1 has the same reference number as the reference number of the component of FIG.

上記空気調和機は、マイクロコンピュータ、入出力回路などから成る制御装置300を備える。この制御装置300は、冷房除湿運転制御100aおよび過絞り除湿制御部100bの他に、上記第1実施形態の再熱除湿運転制御部100cとは異なる再熱除湿運転制御部300cを有する。なお、制御装置300は、制御部の一例である。 The air conditioner includes a control device 300 including a microcomputer, an input / output circuit, and the like. This control device 300 has a reheat dehumidification operation control unit 300c different from the reheat dehumidification operation control unit 100c of the first embodiment, in addition to the cooling dehumidification operation control 100a and the over-throttle dehumidification control unit 100b. The control device 300 is an example of a control unit.

再熱除湿運転制御部300cは、再熱除湿運転中、室外ファン26の回転数が(例えば150rpm)が所定回転数以下になってから、所定時間(例えば1時間または2時間)経過したとき、室外ファン26の回転数を上記所定回転数よりも上げて、外気温度センサ57に外気温度を検出させる。そして、室外ファン26の回転数が上記所定回転数よりも上がった後、外気温度センサ57によって検出された外気温度と、予め作成されたテーブルとを用いて、室外ファン26の回転数が調整される。 When the rotation speed of the outdoor fan 26 (for example, 150 rpm) becomes equal to or less than the predetermined rotation speed during the reheat dehumidification operation, the reheat dehumidification operation control unit 300c elapses for a predetermined time (for example, 1 hour or 2 hours). The rotation speed of the outdoor fan 26 is increased above the predetermined rotation speed, and the outside air temperature sensor 57 detects the outside air temperature. Then, after the rotation speed of the outdoor fan 26 rises above the predetermined rotation speed, the rotation speed of the outdoor fan 26 is adjusted using the outside air temperature detected by the outside air temperature sensor 57 and the table created in advance. To.

上記構成の空気調和機では、再熱除湿運転中、室外ファン26の回転数が所定回転数以下になったとしても、所定時間後、室外ファン26の回転数が上記所定回転数よりも上がることにより、外気温度センサ57へ流れる室外空気の量が増える。その結果、外気温度センサ57によって検出される外気温度と、実際の外気温度との差を低減することができる。したがって、室外ファン26の回転数の調整が不適切になる恐れが減る。 In the air conditioner having the above configuration, even if the rotation speed of the outdoor fan 26 becomes lower than the predetermined rotation speed during the reheat dehumidification operation, the rotation speed of the outdoor fan 26 becomes higher than the predetermined rotation speed after a predetermined time. As a result, the amount of outdoor air flowing to the outside air temperature sensor 57 increases. As a result, the difference between the outside air temperature detected by the outside air temperature sensor 57 and the actual outside air temperature can be reduced. Therefore, the possibility that the rotation speed of the outdoor fan 26 is improperly adjusted is reduced.

本開示の具体的な実施形態について説明したが、本開示は上記第1〜第3実施形態およびその変形例に限定されるものではなく、本開示の範囲内で種々変更して実施することができる。例えば、上記第1実施形態の変形例に第2実施形態または第3実施形態を適用したものを、本開示の一実施形態としてもよい。 Although the specific embodiments of the present disclosure have been described, the present disclosure is not limited to the first to third embodiments and modifications thereof, and various modifications may be made within the scope of the present disclosure. it can. For example, an embodiment of the present disclosure may be obtained by applying the second embodiment or the third embodiment to the modified example of the first embodiment.

1 室内機
2 室外機
11 室内熱交換器
11a 本体熱交換部
11a−1 正面部
11a−2 背面部
11b 補助熱交換部
13 電磁弁
12 室内ファン
21 圧縮機
22 四路切換弁
23 室外熱交換器
24 膨張弁
25 アキュムレータ
26 室外ファン
51 室内熱交換器温度センサ
52 室内温度センサ
53 室内湿度センサ
56 室外熱交換器温度センサ
57 外気温度センサ
58 冷媒温度センサ
100,200,300 制御装置
100a 冷房除湿運転制御部
100b 過絞り除湿運転制御部
100c,200c,300c 再熱除湿運転制御部
200d 記憶部
RC 冷媒回路
1 Indoor unit 2 Outdoor unit 11 Indoor heat exchanger 11a Main body heat exchange part 11a-1 Front part 11a-2 Back part 11b Auxiliary heat exchange part 13 Electromagnetic valve 12 Indoor fan 21 Compressor 22 Four-way switching valve 23 Outdoor heat exchanger 24 Expansion valve 25 Accumulator 26 Outdoor fan 51 Indoor heat exchanger temperature sensor 52 Indoor temperature sensor 53 Indoor humidity sensor 56 Outdoor heat exchanger temperature sensor 57 Outside air temperature sensor 58 Coolant temperature sensor 100, 200, 300 Control device 100a Cooling and dehumidifying operation control Unit 100b Over-throttle dehumidification operation control unit 100c, 200c, 300c Reheat dehumidification operation control unit 200d Storage unit RC refrigerant circuit

Claims (5)

圧縮機(21)、室外熱交換器(23)、膨張機構(24)および室内熱交換器(11)が環状に接続され、冷媒が循環する冷媒回路(RC)と、
上記室外熱交換器(23)に空気を送る室外ファン(26)と、
制御部(100,200,300)と
を備え、
上記室内熱交換器(11)は制御弁(13)を有し、
上記制御部(100,200,300)は、
上記室内熱交換器(11)の実質的に全部を蒸発域にする第1除湿運転と、
上記室内熱交換器(11)の一部を蒸発域にする一方、上記室内熱交換器(11)の残りの部分を過熱域にする第2除湿運転と、
上記室内熱交換器(11)において上記制御弁(13)よりも上流側の部分を凝縮域とする一方、上記室内熱交換器(11)において上記制御弁(13)よりも下流側の部分を蒸発域とする第3除湿運転と
を行うと共に、
上記第3除湿運転時における上記室外ファン(26)の回転数の制御範囲が、上記第2除湿運転時における上記室外ファン(26)の回転数の制御範囲よりも低い回転数を含むように広くなるように、上記室外ファン(26)を制御することを特徴とする空気調和機。
A refrigerant circuit (RC) in which a compressor (21), an outdoor heat exchanger (23), an expansion mechanism (24) and an indoor heat exchanger (11) are connected in a ring shape and a refrigerant circulates.
An outdoor fan (26) that sends air to the outdoor heat exchanger (23),
Equipped with control units (100, 200, 300)
The indoor heat exchanger (11) has a control valve (13).
The control unit (100, 200, 300)
The first dehumidification operation that makes substantially all of the indoor heat exchanger (11) an evaporation region, and
A second dehumidifying operation in which a part of the indoor heat exchanger (11) is set to an evaporation region and the remaining part of the indoor heat exchanger (11) is set to a superheat region.
In the indoor heat exchanger (11), the portion on the upstream side of the control valve (13) is set as the condensation region, while in the indoor heat exchanger (11), the portion on the downstream side of the control valve (13) is defined. In addition to performing the third dehumidification operation, which is the evaporation area,
The control range of the rotation speed of the outdoor fan (26) during the third dehumidification operation is wide so as to include a rotation speed lower than the control range of the rotation speed of the outdoor fan (26) during the second dehumidification operation. An air conditioner characterized by controlling the outdoor fan (26) so as to be.
請求項1に記載の空気調和機において、
上記制御部(100,200,300)は、上記第3除湿運転時における上記室外ファン(26)の回転数の上限値が、上記第2除湿運転時における上記室外ファン(26)の回転数の上限値よりも高くなるように、上記室外ファン(26)を制御することを特徴とする空気調和機。
In the air conditioner according to claim 1,
In the control unit (100, 200, 300), the upper limit of the rotation speed of the outdoor fan (26) during the third dehumidification operation is the rotation speed of the outdoor fan (26) during the second dehumidification operation. An air conditioner characterized in that the outdoor fan (26) is controlled so as to be higher than the upper limit value.
請求項1または2に記載の空気調和機において、
上記制御部(100,200,300)は、上記第3除湿運転時における上記室外ファン(26)の回転数の下限値が、上記第2除湿運転時における上記室外ファン(26)の回転数の下限値よりも低くなるように、上記室外ファン(26)を制御することを特徴とする空気調和機。
In the air conditioner according to claim 1 or 2.
In the control unit (100, 200, 300), the lower limit of the rotation speed of the outdoor fan (26) during the third dehumidification operation is the rotation speed of the outdoor fan (26) during the second dehumidification operation. An air conditioner characterized in that the outdoor fan (26) is controlled so as to be lower than the lower limit value.
請求項1から3までのいずれか一項に記載の空気調和機において、
外気温度を検出する室外温度センサ(57)を備え、
上記制御部(200)は、上記第3除湿運転中、上記室外ファン(26)の回転数が所定回転数以下になったとき、上記室外ファン(26)の回転数が上記所定回転数以下になる直前に上記室外温度センサ(57)が検出した外気温度を用いて、上記室外ファン(26)の回転数を調整することを特徴とする空気調和機。
In the air conditioner according to any one of claims 1 to 3, the air conditioner
Equipped with an outdoor temperature sensor (57) that detects the outside air temperature,
When the rotation speed of the outdoor fan (26) becomes equal to or less than the predetermined rotation speed during the third dehumidifying operation, the control unit (200) reduces the rotation speed of the outdoor fan (26) to the predetermined rotation speed or less. An air conditioner characterized in that the rotation speed of the outdoor fan (26) is adjusted by using the outside air temperature detected by the outdoor temperature sensor (57) immediately before the operation.
請求項4に記載の空気調和機において、
上記制御部(300)は、上記第3除湿運転中、上記室外ファン(26)の回転数が上記所定回転数以下となってから、所定時間経過したとき、上記室外ファン(26)の回転数を上記所定回転数よりも上げて、上記室外温度センサ(57)に外気温度を検出させることを特徴とする空気調和機。
In the air conditioner according to claim 4,
During the third dehumidifying operation, the control unit (300) has a rotation speed of the outdoor fan (26) when a predetermined time elapses after the rotation speed of the outdoor fan (26) becomes equal to or less than the predetermined rotation speed. An air conditioner characterized by having the outdoor temperature sensor (57) detect the outside air temperature by increasing the number of revolutions above the predetermined number of revolutions.
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