JPH085167A - Air conditioner - Google Patents

Air conditioner

Info

Publication number
JPH085167A
JPH085167A JP13458294A JP13458294A JPH085167A JP H085167 A JPH085167 A JP H085167A JP 13458294 A JP13458294 A JP 13458294A JP 13458294 A JP13458294 A JP 13458294A JP H085167 A JPH085167 A JP H085167A
Authority
JP
Japan
Prior art keywords
refrigerant
oil
heat exchanger
refrigerating machine
opening
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
JP13458294A
Other languages
Japanese (ja)
Other versions
JP3467837B2 (en
Inventor
Koichi Endo
浩一 遠藤
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Denso Corp
Original Assignee
NipponDenso Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by NipponDenso Co Ltd filed Critical NipponDenso Co Ltd
Priority to JP13458294A priority Critical patent/JP3467837B2/en
Publication of JPH085167A publication Critical patent/JPH085167A/en
Application granted granted Critical
Publication of JP3467837B2 publication Critical patent/JP3467837B2/en
Anticipated expiration legal-status Critical
Expired - Fee Related legal-status Critical Current

Links

Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B2700/00Sensing or detecting of parameters; Sensors therefor
    • F25B2700/21Temperatures
    • F25B2700/2105Oil temperatures

Landscapes

  • Compression-Type Refrigeration Machines With Reversible Cycles (AREA)

Abstract

PURPOSE:To prevent the capacity of an operating indoor heat exchanger from being deteriorated, and to improve an air conditioning feeling by decreasing the unbalance of a refrigerating cycle. CONSTITUTION:An oil circulating means provided in an outdoor unit 2 comprises an oil separator 26 for separating refrigerating machine oil from a refrigerant and a first oil circulating pipe 27 and a second oil circulating pipe 28 for returning the refrigerating machine oil to a refrigerant compressor 4 from the oil separator 26. The first oil circulating pipe 27 has an end opened to the bottom surface of the oil separator 26. The second oil circulating pipe 28 has an end opened to the side surface of the oil separator 26 higher than the opened position of the first oil circulating pipe 27. In the oil circulating pipes 27 and 28, temperature sensors 29 and 30 as oil quantity detecting means are respectively installed for detecting the quantity of refrigerating machine oil circulated through the circulating pipes 27 and 28 to the refrigerant compressor 4 from the oil separator 26.

Description

【発明の詳細な説明】Detailed Description of the Invention

【0001】[0001]

【産業上の利用分野】本発明は、一台の室外ユニットに
対して複数台の室内ユニットを備える多室形の空気調和
装置に関する。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-room type air conditioner having a plurality of indoor units with respect to one outdoor unit.

【0002】[0002]

【従来の技術】従来より、図6に示すように、一台の室
外ユニット100に対して複数台の室内ユニット200
が並列に分岐接続された多室形空気調和装置が知られて
いる。この多室形空気調和装置は、冷媒圧縮機110よ
り吐出された冷媒の循環方向を四方弁120により切り
替えることで、室内ユニット200の室内熱交換器21
0を冷媒蒸発器として使用する冷房運転、および冷媒凝
縮器として使用する暖房運転を行なうことができる。
2. Description of the Related Art Conventionally, as shown in FIG. 6, a plurality of indoor units 200 are provided for one outdoor unit 100.
There is known a multi-room type air conditioner in which are branched and connected in parallel. In this multi-room air conditioner, the indoor heat exchanger 21 of the indoor unit 200 is switched by switching the circulation direction of the refrigerant discharged from the refrigerant compressor 110 with the four-way valve 120.
A cooling operation in which 0 is used as a refrigerant evaporator and a heating operation in which 0 is used as a refrigerant condenser can be performed.

【0003】しかし、この空気調和装置では、運転を停
止する室内ユニット200がある場合に、以下の不具合
を生じる。例えば、一つの室内ユニット200の運転が
停止される場合を考えると、暖房運転時では、室内熱交
換器210がガス側配管300および四方弁120を介
して冷媒圧縮機110の冷媒吐出側と連通しているた
め、冷媒圧縮機110より吐出された高圧ガス冷媒が停
止中の室内熱交換器210内で凝縮滞留するとともに、
冷媒中に含まれる冷凍機油も冷媒と一緒に滞留する。
However, in this air conditioner, the following problems occur when there is an indoor unit 200 whose operation is stopped. For example, considering the case where the operation of one indoor unit 200 is stopped, during the heating operation, the indoor heat exchanger 210 communicates with the refrigerant discharge side of the refrigerant compressor 110 via the gas side pipe 300 and the four-way valve 120. Therefore, the high-pressure gas refrigerant discharged from the refrigerant compressor 110 is condensed and accumulated in the stopped indoor heat exchanger 210, and
Refrigerating machine oil contained in the refrigerant also stays together with the refrigerant.

【0004】冷房運転時では、液側配管400に設けら
れた電磁開閉弁220が閉じることで、液側配管400
中の液冷媒に冷凍機油が溶けて滞留する。また、電磁開
閉弁220の漏れによって室内熱交換器210へ液冷媒
が浸入する場合は、室内熱交換器210がガス側配管3
00および四方弁120を介して冷媒圧縮機110の冷
媒吸入側と連通しているため、冷媒はそのまま冷媒圧縮
機110に吸引されるが、電磁開閉弁220の漏れによ
る冷媒の流速は非常に小さいため、粘性の大きい冷凍機
油は冷媒圧縮機110に吸引されることなく、室内熱交
換器210のパイプ内壁に付着して滞留することにな
る。
During cooling operation, the liquid-side pipe 400 is closed by closing the electromagnetic on-off valve 220 provided in the liquid-side pipe 400.
Refrigerating machine oil melts and stays in the liquid refrigerant inside. When the liquid refrigerant enters the indoor heat exchanger 210 due to the leakage of the electromagnetic opening / closing valve 220, the indoor heat exchanger 210 is connected to the gas side pipe 3
00 and the four-way valve 120 communicate with the refrigerant suction side of the refrigerant compressor 110, the refrigerant is sucked into the refrigerant compressor 110 as it is, but the flow velocity of the refrigerant due to the leakage of the electromagnetic opening / closing valve 220 is very small. Therefore, the refrigerating machine oil having a large viscosity adheres to the inner wall of the pipe of the indoor heat exchanger 210 and is retained therein without being sucked by the refrigerant compressor 110.

【0005】このような冷媒の滞留によるガス欠運転、
および冷凍機油の滞留による冷媒圧縮機の潤滑不足を解
消するために、特開平5−77945号公報では、冷房
運転時に膨脹機構として作用する電動弁を設け、室内ユ
ニットの停止時間が一定時間経過した時に、前記電動弁
を所定時間だけ開弁する技術が開示されている。
Gas shortage operation due to such refrigerant retention,
In order to eliminate insufficient lubrication of the refrigerant compressor due to retention of refrigerating machine oil, in JP-A-5-77945, an electric valve that acts as an expansion mechanism during cooling operation is provided, and the stop time of the indoor unit has passed a certain time. At times, there is disclosed a technique of opening the motor-operated valve for a predetermined time.

【0006】[0006]

【発明が解決しようとする課題】ところが、上記公報に
開示された従来技術では、冷媒配管の長さ、および空気
調和装置の施行状態等により、停止中の室内熱交換器へ
の時間当たりの冷凍機油滞留量が変化する。また、上記
のような多室形空気調和装置では、冷凍サイクル中にオ
イルセパレータを設置するのが通例であり、このオイル
セパレータでの分離性能が、負荷条件により、あるいは
オイルセパレータ内の初期貯油量の違いにより変化する
ため、停止中の室内熱交換器への時間当たりの滞油量が
大きく異なる。
However, according to the prior art disclosed in the above publication, depending on the length of the refrigerant pipe, the operating condition of the air conditioner, and the like, the hourly refrigeration to the indoor heat exchanger being stopped Machine oil retention changes. Further, in the multi-room air conditioner as described above, it is customary to install an oil separator in the refrigeration cycle, and the separation performance of this oil separator depends on the load conditions or the initial oil storage amount in the oil separator. The amount of oil accumulated per unit time in the stopped indoor heat exchanger varies greatly depending on the difference.

【0007】このため、安全をみて短サイクル時間で電
動弁を開弁し、且つ開弁時間を長くする必要が生じるこ
とから、電動弁の開弁時に停止中の室内熱交換器に冷媒
が流れ込むことによる運転中の室内熱交換器の能力低下
が大きくなるとともに、電動弁の開閉に伴って冷凍サイ
クルのバランスが頻繁に崩れることにより、空調フィー
リングの悪化を招くという問題がある。本発明は、上記
事情に基づいて成されたもので、その目的は、運転中の
室内熱交換器の能力低下を抑えるとともに、冷凍サイク
ルのバランスの崩れを小さくして空調フィーリングを向
上させることのできる空気調和装置の提供にある。
For this reason, for safety, it is necessary to open the motor-operated valve in a short cycle time and lengthen the valve-opening time. Therefore, when the motor-operated valve is opened, the refrigerant flows into the indoor heat exchanger that is stopped. As a result, there is a problem that the capacity of the indoor heat exchanger during operation is greatly reduced, and the balance of the refrigeration cycle is frequently lost due to opening and closing of the motor-operated valve, resulting in deterioration of air conditioning feeling. The present invention has been made based on the above circumstances, and an object thereof is to suppress a decrease in the capacity of an indoor heat exchanger during operation and to reduce an imbalance of a refrigeration cycle to improve an air conditioning feeling. The purpose is to provide an air conditioner that can

【0008】[0008]

【課題を解決するための手段】本発明は、上記目的を達
成するために、以下の技術的手段を備える。請求項1で
は、一台または複数台の冷媒圧縮機に対して並列に分岐
接続された複数の室内熱交換器を有するとともに、個々
の前記室内熱交換器に通じる各冷媒配管にそれぞれ介在
されて、開状態の時に前記冷媒配管を開き、閉状態の時
に前記冷媒配管を閉じる複数の開閉手段を備えた冷凍サ
イクルと、この冷凍サイクルで前記冷媒圧縮機の冷媒吐
出側に介在されて、前記冷媒圧縮機より吐出された冷媒
に含まれる冷凍機油を冷媒より分離して、前記冷媒圧縮
機へ還流させるオイル還流手段と、このオイル還流手段
により前記冷媒圧縮機へ還流する冷凍機油量を検出する
油量検出手段と、この油量検出手段の検出値を設定値と
比較する比較判定手段と、前記冷媒圧縮機の運転時に、
複数の前記開閉手段のうち閉状態の前記開閉手段がある
か否かを判定する閉状態判定手段と、この閉状態判定手
段で閉状態の前記開閉手段があると判定された場合にお
いて、前記比較判定手段で前記油量検出手段の検出値が
前記設定値以下であると判定された場合は、閉状態の前
記開閉手段のうち少なくとも1つを開状態とする開制御
を行なう制御手段とを備える。
In order to achieve the above object, the present invention comprises the following technical means. In Claim 1, while having a plurality of indoor heat exchangers that are branched and connected in parallel to one or a plurality of refrigerant compressors, each of which is interposed in each refrigerant pipe leading to each of the indoor heat exchangers. , A refrigeration cycle provided with a plurality of opening / closing means for opening the refrigerant pipe in the open state and closing the refrigerant pipe in the closed state, and being interposed on the refrigerant discharge side of the refrigerant compressor in the refrigeration cycle, the refrigerant Refrigerating machine oil contained in the refrigerant discharged from the compressor is separated from the refrigerant, and an oil recirculation unit that recirculates to the refrigerant compressor, and an oil that detects the amount of refrigerating machine oil that recirculates to the refrigerant compressor by this oil recirculation unit. Amount detection means, comparison determination means for comparing the detection value of this oil amount detection means with a set value, and during operation of the refrigerant compressor,
The closed state determination means for determining whether there is the closed state opening / closing means among the plurality of opening / closing means, and the comparison in the case where the closed state determination means determines that there is the closed state opening / closing means When the determination unit determines that the detection value of the oil amount detection unit is less than or equal to the set value, the control unit performs an opening control for opening at least one of the opening / closing units in the closed state. .

【0009】また、前記制御手段は、前記開制御を実行
した後、前記比較判定手段で前記油量検出手段の検出値
が前記設定値より大きいと判定された場合は、前記開制
御によって開状態となった前記開閉手段を再び閉状態と
する閉制御を行なうことを特徴とする。
Further, the control means, after executing the opening control, when the comparison determination means determines that the detection value of the oil amount detection means is larger than the set value, the opening state is determined by the opening control. The closing control is performed so that the opening / closing means is closed again.

【0010】前記オイル還流手段は、冷媒と冷凍機油と
を分離して、その分離した冷凍機油を貯留するオイル分
離器と、一端が前記オイル分離器内に開口して他端が前
記冷媒圧縮機の冷媒吸入口に連絡されたオイル還流管と
を有し、前記油量検出手段は、前記オイル還流管を流れ
る冷凍機油の温度を検出する油温検出手段を有し、この
油温検出手段の検出値に基づいて前記オイル分離器より
前記冷媒圧縮機へ還流する冷凍機油量を検出することを
特徴とする。
The oil recirculation means separates the refrigerant and the refrigerating machine oil and stores the separated refrigerating machine oil, and one end is opened into the oil separator and the other end is the refrigerant compressor. And an oil recirculation pipe connected to the refrigerant suction port, and the oil amount detecting means has an oil temperature detecting means for detecting the temperature of the refrigerating machine oil flowing through the oil recirculating pipe. The amount of refrigerating machine oil flowing back from the oil separator to the refrigerant compressor is detected based on the detected value.

【0011】前記オイル還流管は、前記オイル分離器に
貯留された冷凍機油が所定量減少した時に、冷凍機油と
ともにガス冷媒が前記オイル分離器より流出するよう
に、前記一端が前記オイル分離器の底面より所定の高さ
位置に開口することを特徴とする。
The oil reflux pipe has one end of the oil separator so that the gas refrigerant flows out of the oil separator together with the refrigerating machine oil when the refrigerating machine oil stored in the oil separator decreases by a predetermined amount. It is characterized by opening at a predetermined height position from the bottom surface.

【0012】前記油量検出手段は、前記オイル分離器に
貯留された冷凍機油の液面を検出する液面検出手段を有
し、この液面検出手段の検出値に基づいて前記オイル分
離器より前記冷媒圧縮機へ還流する冷凍機油量を検出す
ることを特徴とする。
The oil amount detecting means has a liquid level detecting means for detecting the liquid level of the refrigerating machine oil stored in the oil separator, and the oil separator detects the liquid level based on the detection value of the liquid level detecting means. It is characterized in that the amount of refrigerating machine oil flowing back to the refrigerant compressor is detected.

【0013】前記室内熱交換器は、内部を流れる低温低
圧の冷媒との熱交換によって通過する空気を冷却する冷
房用熱交換器であることを特徴とする。また、前記室内
熱交換器は、内部を流れる高温高圧の冷媒との熱交換に
よって通過する空気を加熱する暖房用熱交換器であるこ
とを特徴とする。
The indoor heat exchanger is a cooling heat exchanger for cooling air passing therethrough by heat exchange with a low-temperature low-pressure refrigerant flowing inside. Further, the indoor heat exchanger is a heating heat exchanger that heats air passing therethrough by heat exchange with a high-temperature and high-pressure refrigerant flowing inside.

【0014】前記冷凍サイクルは、冷房運転と暖房運転
との切り替えに応じて前記冷媒圧縮機より吐出された冷
媒の循環方向を切り替える循環方向切替手段を有し、前
記室内熱交換器は、前記冷房運転の時に低温低圧の冷媒
が供給されて、その低温低圧の冷媒との熱交換によって
通過する空気を冷却する冷房用熱交換器として機能し、
前記暖房運転の時に高温高圧の冷媒が供給されて、その
高温高圧の冷媒との熱交換によって通過する空気を加熱
する暖房用熱交換器として機能することを特徴とする。
The refrigeration cycle has a circulation direction switching means for switching the circulation direction of the refrigerant discharged from the refrigerant compressor in response to switching between the cooling operation and the heating operation, and the indoor heat exchanger is the cooling apparatus. A low-temperature low-pressure refrigerant is supplied during operation, and functions as a cooling heat exchanger that cools passing air by heat exchange with the low-temperature low-pressure refrigerant.
A high-temperature and high-pressure refrigerant is supplied during the heating operation, and it functions as a heating heat exchanger that heats passing air by heat exchange with the high-temperature and high-pressure refrigerant.

【0015】前記開閉手段は、冷媒の流れ方向において
前記室内熱交換器の上流側に設置されたことを特徴とす
る。また、前記開閉手段は、弁開度に応じて通過する冷
媒流量を調節する流量調節機能を有し、この流量調節機
能によって冷房運転時に前記室内熱交換器へ供給される
冷媒を減圧膨脹することを特徴とする。
The opening / closing means is installed upstream of the indoor heat exchanger in the flow direction of the refrigerant. Further, the opening / closing means has a flow rate adjusting function for adjusting the flow rate of the refrigerant passing therethrough according to the valve opening degree, and by this flow rate adjusting function, the refrigerant supplied to the indoor heat exchanger during the cooling operation is decompressed and expanded. Is characterized by.

【0016】[0016]

【作用および発明の効果】上記構成より成る本発明の空
気調和装置は、冷媒圧縮機の運転時に閉状態(冷媒配管
を閉じた状態)の開閉手段があると判定された場合に、
冷媒圧縮機へ還流する冷凍機油量が設定値以下の場合
は、冷凍機油がサイクル内(特に停止中の室内熱交換器
内)に滞留していると判断して、閉状態の開閉手段を開
状態とする。これにより、停止中の室内熱交換器にも冷
媒が流れることにより、サイクル内に滞留していた冷凍
機油を冷媒圧縮機へ戻すことができる。この時、閉状態
の開閉手段が2つ以上ある場合は、閉状態の開閉手段を
すべて開状態としても良いが、少なくとも1つの開閉手
段を開状態としても良い。
According to the air conditioner of the present invention having the above-described structure, when it is determined that there is the opening / closing means in the closed state (the state in which the refrigerant pipe is closed) during the operation of the refrigerant compressor,
If the amount of refrigerating machine oil flowing back to the refrigerant compressor is less than the set value, it is judged that the refrigerating machine oil is staying in the cycle (especially in the indoor heat exchanger that is stopped), and the closed opening / closing means is opened. State. As a result, the refrigerant also flows through the stopped indoor heat exchanger, so that the refrigerating machine oil accumulated in the cycle can be returned to the refrigerant compressor. At this time, when there are two or more closed opening / closing means, all of the closed opening / closing means may be open, but at least one opening / closing means may be open.

【0017】また、閉状態の開閉手段を開状態とした
後、冷媒圧縮機へ還流する冷凍機油量が増加して油量検
出手段の検出値が設定値より大きくなった場合は、サイ
クル内に滞留する冷凍機油量が少ない、あるいは滞留し
ていないと判断して、開状態となった開閉手段を再び閉
状態とする。
Further, when the amount of the refrigerating machine oil flowing back to the refrigerant compressor increases and the detected value of the oil amount detecting means becomes larger than the set value after the closed opening / closing means is opened, the cycle When it is determined that the amount of refrigerating machine oil that remains is small or that it does not stay, the opening / closing means that has been opened is closed again.

【0018】このように、本発明では、冷媒圧縮機へ還
流する冷凍機油量に基づいて開閉手段の開閉制御を行な
うことにより、停止中の室内熱交換器に対応する開閉手
段を必要な時(冷凍機油が滞留していると判断した時)
だけ開状態とすることができる。従って、従来のよう
に、停止時間が一定時間経過した時に一律に電動弁を開
弁する場合と比較して、開閉手段を開状態とする頻度が
少なくなる。その結果、停止中の室内熱交換器に対応す
る開閉手段が開状態となることで生じる冷凍サイクルの
バランスの崩れを小さくすることができるため、空調フ
ィーリングの向上を図ることができる。
As described above, according to the present invention, the opening / closing control of the opening / closing means is performed based on the amount of the refrigerating machine oil flowing back to the refrigerant compressor, so that the opening / closing means corresponding to the stopped indoor heat exchanger is required ( (When it is determined that the refrigerator oil is accumulated)
Can only be opened. Therefore, as compared with the conventional case where the motor-operated valve is uniformly opened when the stop time elapses for a fixed time, the frequency of opening the opening / closing means is reduced. As a result, it is possible to reduce the unbalance of the refrigeration cycle caused by the opening / closing means corresponding to the indoor heat exchanger being stopped being opened, so that the air conditioning feeling can be improved.

【0019】また、冷媒圧縮機へ還流する冷凍機油量の
増加に伴って油量検出手段の検出値が設定値より大きく
なった場合に、開閉手段を再び閉状態とすることによ
り、開閉手段を開状態とする時間を必要最小限に留める
ことが可能となる。従って、停止中の室内熱交換器に冷
媒が流れることにより生じる運転中の室内熱交換器の能
力低下の程度を小さく抑えることができる。
Further, when the detected value of the oil amount detecting means becomes larger than the set value as the amount of refrigerating machine oil flowing back to the refrigerant compressor increases, the opening / closing means is closed again to open the opening / closing means. It is possible to keep the open time to the minimum necessary. Therefore, it is possible to suppress the degree of decrease in the capacity of the operating indoor heat exchanger caused by the flow of the refrigerant to the indoor heat exchanger that is stopped.

【0020】なお、本発明の空気調和装置は、室内熱交
換器を冷房用熱交換器として使用する冷房サイクル、室
内熱交換器を暖房用熱交換器として使用する暖房サイク
ル、あるいは、冷媒圧縮機より吐出された冷媒の循環方
向を切り替えることにより、冷房運転時に室内熱交換器
を冷房用熱交換器として使用し、暖房運転時に室内熱交
換器を暖房用熱交換器として使用するヒートポンプサイ
クルとして適用することができる。
The air conditioner of the present invention includes a cooling cycle in which the indoor heat exchanger is used as a cooling heat exchanger, a heating cycle in which the indoor heat exchanger is used as a heating heat exchanger, or a refrigerant compressor. By changing the circulation direction of the discharged refrigerant, it is used as a heat pump cycle that uses the indoor heat exchanger as a cooling heat exchanger during cooling operation and uses the indoor heat exchanger as a heating heat exchanger during heating operation. can do.

【0021】[0021]

【実施例】次に、本発明の空気調和装置の一実施例を図
1〜5に基づいて説明する。図1は空気調和装置の全体
模式図である。本実施例の空気調和装置1は、冷凍サイ
クルを構成する室外ユニット2と室内ユニット3とを備
え、一台の室外ユニット2に対して複数台(本実施例で
は2台)の室内ユニット3が設置されている。
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, an embodiment of the air conditioner of the present invention will be described with reference to FIGS. FIG. 1 is an overall schematic diagram of an air conditioner. The air conditioner 1 of the present embodiment includes an outdoor unit 2 and an indoor unit 3 that form a refrigeration cycle, and a plurality of (two in the present embodiment) indoor units 3 are provided for one outdoor unit 2. is set up.

【0022】室外ユニット2は、冷媒圧縮機4、オイル
還流手段(後述する)、四方弁5、室外熱交換器6、室
外絞り7、アキュムレータ8、およびこれらの各部品を
接続する冷媒配管(ガス側配管9と液側配管10)より
構成されている。室内ユニット3は、室内熱交換器1
1、室内絞り12、第1電磁弁13(本発明の開閉手
段)、第2電磁弁14(本発明の開閉手段)、第1逆止
弁15、第2逆止弁16、およびこれらの各部品を接続
する冷媒配管(ガス側配管17と液側配管18:共に本
発明の冷媒配管)より構成されている。
The outdoor unit 2 includes a refrigerant compressor 4, an oil recirculation means (which will be described later), a four-way valve 5, an outdoor heat exchanger 6, an outdoor throttle 7, an accumulator 8, and a refrigerant pipe (gas) for connecting these parts. It is composed of a side pipe 9 and a liquid side pipe 10). The indoor unit 3 is the indoor heat exchanger 1
1, indoor throttle 12, first solenoid valve 13 (opening / closing means of the present invention), second solenoid valve 14 (opening / closing means of the present invention), first check valve 15, second check valve 16, and each of these It is composed of a refrigerant pipe (gas side pipe 17 and liquid side pipe 18: both are refrigerant pipes of the present invention) for connecting components.

【0023】冷媒圧縮機4は、外部の駆動源(図示しな
い)によって回転駆動されることにより、吸入したガス
冷媒を圧縮して吐出する。オイル還流手段は、冷媒圧縮
機4より吐出された冷媒に含まれる冷凍機油を冷媒より
分離して冷媒圧縮機4へ還流させるものである。このオ
イル還流手段の構造および作用については後述する。
The refrigerant compressor 4 is rotationally driven by an external drive source (not shown) to compress and discharge the sucked gas refrigerant. The oil recirculation means separates refrigerating machine oil contained in the refrigerant discharged from the refrigerant compressor 4 from the refrigerant and recirculates it to the refrigerant compressor 4. The structure and operation of this oil recirculation means will be described later.

【0024】四方弁5は、ガス側配管9に介在されて、
冷媒圧縮機4より吐出された冷媒の循環方向を運転モー
ド(冷房モード、暖房モード)に応じて切り替えるもの
である。なお、図1に冷房運転時の冷媒の流れを実線矢
印Cで示し、暖房運転時の冷媒の流れを破線矢印Hで示
す。室外熱交換器6は、室外熱交換器6の前面に配され
た室外ファン19の送風を受けて外気と冷媒との熱交換
を行なうもので、冷房運転時には冷媒凝縮器として機能
し、暖房運転時には冷媒蒸発器として機能する。
The four-way valve 5 is interposed in the gas side pipe 9,
The circulation direction of the refrigerant discharged from the refrigerant compressor 4 is switched according to the operation mode (cooling mode, heating mode). In FIG. 1, the flow of the refrigerant during the cooling operation is indicated by a solid arrow C, and the flow of the refrigerant during the heating operation is indicated by a broken arrow H. The outdoor heat exchanger 6 exchanges heat between the outdoor air and the refrigerant by receiving the air blown from the outdoor fan 19 arranged in front of the outdoor heat exchanger 6, and functions as a refrigerant condenser during the cooling operation to perform the heating operation. Sometimes it functions as a refrigerant evaporator.

【0025】室外絞り7は、液側配管10に設けられ
て、冷房運転時に室外熱交換器6より流出する冷媒、お
よび暖房運転時に室外熱交換器6へ流入する冷媒を減圧
膨脹させるものであり、本実施例ではキャピラリチュー
ブを使用する。アキュムレータ8は、冷媒圧縮機4の冷
媒吸入側でガス側配管9に介在されて、冷媒圧縮機4へ
還流する冷媒を気液分離して液冷媒を貯留し、気相冷媒
のみを冷媒圧縮機4へ送り出すものである。
The outdoor throttle 7 is provided in the liquid side pipe 10 and expands the refrigerant flowing out of the outdoor heat exchanger 6 during the cooling operation and the refrigerant flowing into the outdoor heat exchanger 6 during the heating operation under reduced pressure. In this embodiment, a capillary tube is used. The accumulator 8 is interposed in the gas side pipe 9 on the refrigerant intake side of the refrigerant compressor 4, stores the liquid refrigerant by separating the refrigerant flowing back to the refrigerant compressor 4 into a liquid refrigerant, and stores only the gas phase refrigerant in the refrigerant compressor. It sends it to 4.

【0026】室内熱交換器11は、内部を流れる冷媒と
室内ファン20より送風された空気との熱交換を行なう
もので、冷房運転時には冷媒蒸発器として機能し、暖房
運転時には冷媒凝縮器として機能する。室内絞り12
は、液側配管18に設けられて、冷房運転時に室内熱交
換器11へ流入する冷媒、および暖房運転時に室内熱交
換器11より流出する冷媒を減圧膨脹させるものであ
り、本実施例ではキャピラリチューブを使用する。
The indoor heat exchanger 11 exchanges heat between the refrigerant flowing inside and the air blown from the indoor fan 20, and functions as a refrigerant evaporator during cooling operation and as a refrigerant condenser during heating operation. To do. Indoor diaphragm 12
Is provided in the liquid side pipe 18 for decompressing and expanding the refrigerant flowing into the indoor heat exchanger 11 during the cooling operation and the refrigerant flowing out of the indoor heat exchanger 11 during the heating operation. In the present embodiment, Use a tube.

【0027】第1電磁弁13は、液側配管18に介在さ
れて、通電を受けて(ON)開弁する(本発明で言う開
状態)ことで液側配管18を開き、通電が停止されて
(OFF)閉弁する(本発明で言う閉状態)ことで液側
配管18を閉じる。なお、この第1電磁弁13と室内熱
交換器11との間に室内絞り12が設けられている。第
2電磁弁14は、ガス側配管17に介在されて、第1電
磁弁13と同様に、通電を受けて開弁することでガス側
配管17を開き、通電が停止されて閉弁することでガス
側配管17を閉じる。なお、第1電磁弁13および第2
電磁弁14は、それぞれ制御装置21(図3参照)によ
って通電制御される。
The first solenoid valve 13 is interposed in the liquid side pipe 18 and is opened (ON) by receiving energization (open state in the present invention) to open the liquid side pipe 18 and stop energization. (OFF) to close the valve (closed state in the present invention) to close the liquid side pipe 18. An indoor throttle 12 is provided between the first electromagnetic valve 13 and the indoor heat exchanger 11. The second solenoid valve 14 is interposed in the gas side pipe 17, and opens the gas side pipe 17 by being energized and opening by being energized in the same manner as the first solenoid valve 13, and the energization is stopped and closed. Then, the gas side pipe 17 is closed. In addition, the first solenoid valve 13 and the second
Each solenoid valve 14 is energized and controlled by the control device 21 (see FIG. 3).

【0028】第1逆止弁15は、第1電磁弁13を迂回
する第1迂回路22に配されて、暖房運転時に室内熱交
換器11より流出して室内絞り12で減圧された冷媒を
通過させることができる(冷媒の流れ方向を矢印で示
す)。第2逆止弁16は、第2電磁弁14を迂回する第
2迂回路23に配されて、冷房運転時に室内熱交換器1
1より流出した冷媒を通過させることができる(冷媒の
流れ方向を矢印で示す)。
The first check valve 15 is arranged in the first bypass 22 that bypasses the first electromagnetic valve 13, and discharges the refrigerant that has flowed out of the indoor heat exchanger 11 and is decompressed by the indoor throttle 12 during the heating operation. It can be passed (the direction of flow of the refrigerant is indicated by an arrow). The second check valve 16 is arranged in the second bypass 23 that bypasses the second electromagnetic valve 14, and the indoor heat exchanger 1 during the cooling operation.
It is possible to pass the refrigerant flowing out of 1 (the direction of the refrigerant flow is indicated by an arrow).

【0029】各室内ユニット3は室外ユニット2に対し
て、液側の連絡配管24およびガス側の連絡配管25に
より並列に分岐接続されている。
Each indoor unit 3 is branched and connected in parallel to the outdoor unit 2 by a liquid side communication pipe 24 and a gas side communication pipe 25.

【0030】上述のオイル還流手段は、図2に示すよう
に、冷媒圧縮機4の冷媒吐出側に接続されるガス側配管
9に介在されたオイル分離器26と、このオイル分離器
26と冷媒圧縮機4の冷媒吸入側に接続されるガス側配
管9とを連絡する2本のオイル還流管(第1オイル還流
管27と第2オイル還流管28)より構成される。
As shown in FIG. 2, the oil recirculation means described above includes an oil separator 26 interposed in a gas side pipe 9 connected to the refrigerant discharge side of the refrigerant compressor 4, the oil separator 26 and the refrigerant. It is composed of two oil return pipes (a first oil return pipe 27 and a second oil return pipe 28) which communicate with a gas side pipe 9 connected to the refrigerant suction side of the compressor 4.

【0031】オイル分離器26は、冷媒と冷凍機油とを
遠心分離する分離室26aと、この分離室26aで分離
された冷凍機油を貯留する貯留室26bとから成る。分
離室26aには、冷媒圧縮機4より吐出されたガス冷媒
が流入する流入口26cと、この分離室26aで冷凍機
油を分離したガス冷媒が流出する流出口26dとが設け
られている。貯留室26bは、分離室26aの下方に位
置し、分離室26aでガス冷媒より分離した冷凍機油が
自重により落下して貯留される。
The oil separator 26 comprises a separation chamber 26a for centrifuging the refrigerant and the refrigerating machine oil, and a storage chamber 26b for storing the refrigerating machine oil separated in the separation chamber 26a. The separation chamber 26a is provided with an inlet 26c into which the gas refrigerant discharged from the refrigerant compressor 4 flows, and an outlet 26d from which the gas refrigerant obtained by separating the refrigerating machine oil in the separation chamber 26a flows out. The storage chamber 26b is located below the separation chamber 26a, and the refrigerating machine oil separated from the gas refrigerant in the separation chamber 26a falls by its own weight and is stored.

【0032】第1オイル還流管27は、一端がオイル分
離器26の底面に開口して、他端がガス側配管9に連絡
されている。第2オイル還流管28は、一端が第1オイ
ル還流管27の開口位置よりも高いオイル分離器26の
側面に開口して、他端がガス側配管9に連絡されてい
る。
The first oil return pipe 27 has one end opened to the bottom surface of the oil separator 26 and the other end connected to the gas side pipe 9. One end of the second oil return pipe 28 is opened to the side surface of the oil separator 26 higher than the opening position of the first oil return pipe 27, and the other end is connected to the gas side pipe 9.

【0033】この第1オイル還流管27および第2オイ
ル還流管28には、オイル分離器26より冷媒圧縮機4
へ最適量の冷凍機油が戻るように、それぞれ抵抗27
a、28aが設けられている。但し、第2オイル還流管
28より第1オイル還流管27の方が流通抵抗が小さく
なるように(つまり第2オイル還流管28より第1オイ
ル還流管27の方が流れやすい)、それぞれの抵抗27
a、28aが設定されている。
The first oil return pipe 27 and the second oil return pipe 28 are connected to the refrigerant compressor 4 from the oil separator 26.
To return the optimum amount of refrigerating machine oil to
a and 28a are provided. However, the resistance of each of the first oil return pipes 27 is smaller than that of the second oil return pipes 28 (that is, the first oil return pipes 27 are easier to flow than the second oil return pipes 28). 27
a and 28a are set.

【0034】また、オイル分離器26の側面に開口する
第2オイル還流管28の開口径は、オイル分離器26の
底面に開口する第1オイル還流管27の開口径に比べて
大きく設定してある。なお、第2オイル還流管28の開
口位置(オイル分離器26の底面からの高さH)および
開口径は、空気調和装置1の使用し得る負荷条件、およ
び空気調和装置1の大きさにより決定されている。
The opening diameter of the second oil return pipe 28 opening on the side surface of the oil separator 26 is set larger than the opening diameter of the first oil return pipe 27 opening on the bottom surface of the oil separator 26. is there. The opening position (height H from the bottom surface of the oil separator 26) and the opening diameter of the second oil return pipe 28 are determined by the load condition that the air conditioner 1 can use and the size of the air conditioner 1. Has been done.

【0035】さらに、第1オイル還流管27および第2
オイル還流管28には、本発明の油量検出手段として、
それぞれ第1オイル還流管27および第2オイル還流管
28を流れる冷凍機油の温度を検出する温度センサ2
9、30が設けられている。
Further, the first oil return pipe 27 and the second oil return pipe 27
In the oil return pipe 28, as the oil amount detecting means of the present invention,
Temperature sensor 2 for detecting the temperature of the refrigerating machine oil flowing through the first oil return pipe 27 and the second oil return pipe 28, respectively.
9 and 30 are provided.

【0036】制御装置21は、マイクロコンピュータ
(図示しない)を内蔵するもので、操作パネル31(図
3参照)で設定された所望の空調状態が得られるよう
に、四方弁5、室外ファン19、室内ファン20、第1
電磁弁13、および第2電磁弁14の通電制御を行なう
とともに、何方か一台(3台以上の場合は少なくとも1
台)の室内ユニット3の運転が停止された場合に、冷凍
機油のサイクル内での滞留を防止するための冷凍機油滞
留防止制御(後述する)を実行する。なお、室内ユニッ
ト3の運転を停止するとは、室内ファン20の作動を停
止するとともに、室内熱交換器11に冷媒が流れないよ
うに、第1電磁弁13または第2電磁弁14の通電制御
を行なうことである。
The control device 21 has a microcomputer (not shown) built therein, and the four-way valve 5, the outdoor fan 19, and the outdoor fan 19, so that a desired air-conditioning condition set by the operation panel 31 (see FIG. 3) can be obtained. Indoor fan 20, first
While controlling the energization of the solenoid valve 13 and the second solenoid valve 14, one of them is operated (at least 1 if three or more are used).
When the operation of the indoor unit 3 of the stand is stopped, refrigerating machine oil retention control (to be described later) for preventing the refrigerating machine oil from staying in the cycle is executed. Note that stopping the operation of the indoor unit 3 means stopping the operation of the indoor fan 20 and controlling the energization of the first solenoid valve 13 or the second solenoid valve 14 so that the refrigerant does not flow to the indoor heat exchanger 11. It is to do.

【0037】次に、本実施例の作動を説明する。 イ)冷房モード 冷房モード時は、冷媒圧縮機4より吐出された冷媒が、
オイル分離器26→四方弁5→室外熱交換器6へ導かれ
て、この室外熱交換器6で室外ファン19の送風を受け
て凝縮液化される。その後、室外熱交換器6→室外絞り
7→第1電磁弁13(この時第1電磁弁13:ON)→
室内絞り12→室内熱交換器11へ送られる。この室内
熱交換器11では、室外絞り7および室内絞り12で減
圧膨脹された低温低圧の冷媒が室内ファン20により送
風された空気との熱交換によって蒸発し、室内熱交換器
11を通過する空気を冷却する。その後、室内熱交換器
11→第2逆止弁16(この時第2電磁弁14:OF
F)→四方弁5→アキュムレータ8を順に流れて、再び
冷媒圧縮機4に吸引される。
Next, the operation of this embodiment will be described. A) Cooling mode In the cooling mode, the refrigerant discharged from the refrigerant compressor 4 is
The oil separator 26 is guided to the four-way valve 5 and the outdoor heat exchanger 6, and the outdoor heat exchanger 6 blows air from the outdoor fan 19 to condense and liquefy it. After that, the outdoor heat exchanger 6 → the outdoor throttle 7 → the first solenoid valve 13 (at this time, the first solenoid valve 13: ON) →
The indoor throttle 12 is sent to the indoor heat exchanger 11. In this indoor heat exchanger 11, the low-temperature low-pressure refrigerant that has been decompressed and expanded in the outdoor throttle 7 and the indoor throttle 12 evaporates by heat exchange with the air blown by the indoor fan 20, and the air that passes through the indoor heat exchanger 11 To cool. After that, the indoor heat exchanger 11 → the second check valve 16 (at this time, the second solenoid valve 14: OF
F) → The four-way valve 5 → The accumulator 8 flows in this order, and the refrigerant is again sucked into the refrigerant compressor 4.

【0038】ロ)暖房モード 暖房モード時は、冷媒圧縮機4より吐出された冷媒が、
オイル分離器26→四方弁5→第2電磁弁14(この時
第2電磁弁14:ON)→室内熱交換器11へ導かれ
て、この室内熱交換器11で室内ファン20の送風を受
けて凝縮液化し、室内熱交換器11を通過する空気を加
熱する。その後、室内熱交換器11→室内絞り12→第
1逆止弁15(この時第1電磁弁13:OFF)→室外
絞り7→室外熱交換器6へ送られる。この室外熱交換器
6では、室内絞り12および室外絞り7で減圧膨脹され
た低温低圧の冷媒が室外ファン19により送風された空
気(外気)との熱交換によって蒸発する。その後、室外
熱交換器6→四方弁5→アキュムレータ8を順に流れ
て、再び冷媒圧縮機4に吸引される。
B) Heating mode In the heating mode, the refrigerant discharged from the refrigerant compressor 4 is
The oil separator 26 → the four-way valve 5 → the second solenoid valve 14 (the second solenoid valve 14: ON at this time) → is guided to the indoor heat exchanger 11, and the indoor heat exchanger 11 blows air from the indoor fan 20. The condensed air is condensed and liquefied to heat the air passing through the indoor heat exchanger 11. Then, the heat is sent to the indoor heat exchanger 11 → the indoor throttle 12 → the first check valve 15 (the first electromagnetic valve 13: OFF at this time) → the outdoor throttle 7 → the outdoor heat exchanger 6. In the outdoor heat exchanger 6, the low-temperature low-pressure refrigerant that has been decompressed and expanded by the indoor throttle 12 and the outdoor throttle 7 evaporates by heat exchange with the air (outside air) blown by the outdoor fan 19. After that, it flows in the order of the outdoor heat exchanger 6-> the four-way valve 5-> the accumulator 8 and is again sucked into the refrigerant compressor 4.

【0039】上記の作動において、冷媒圧縮機4より吐
出されたガス冷媒に含まれる冷凍機油は、オイル分離器
26でガス冷媒と分離されるが、完全に分離されること
はなく、少量の冷凍機油がガス冷媒とともに冷凍サイク
ルを循環して再び冷媒圧縮機4へ戻ることになる。この
ため、何方か一方の室内ユニット3の運転を停止する
と、その運転停止の室内ユニット3に冷凍機油が滞留し
て冷凍機油不足を招く。
In the above operation, the refrigerating machine oil contained in the gas refrigerant discharged from the refrigerant compressor 4 is separated from the gas refrigerant in the oil separator 26, but is not completely separated and a small amount of refrigeration is used. The machine oil circulates in the refrigeration cycle together with the gas refrigerant and returns to the refrigerant compressor 4 again. Therefore, when the operation of one of the indoor units 3 is stopped, the refrigerating machine oil accumulates in the stopped indoor unit 3 and the refrigerating machine oil runs short.

【0040】そこで、本実施例では、何方か一方の室内
ユニット3の運転を停止した場合に、制御装置21によ
り以下の冷凍機油滞留防止制御が行なわれる。この冷凍
機油滞留防止制御について、図4に示すフローチャート
に基づいて説明する。
Therefore, in this embodiment, when the operation of any one of the indoor units 3 is stopped, the control device 21 performs the following refrigerating machine oil retention control. This refrigerating machine oil retention control will be described based on the flowchart shown in FIG.

【0041】まず、制御装置21の閉状態判定手段によ
り、何方か一方の室内ユニット3の運転が停止されたか
否かを判定する(ステップS1)。この判定は、操作パ
ネル31より出力される操作信号によって判定すること
ができるが、室内ファン20の通電状態で判断しても良
いし、冷房運転時であれば第1電磁弁13、暖房運転時
であれば第2電磁弁14の通電状態で判定しても良い。
つまり、室内ファン20がOFF、冷房運転時であれば
第1電磁弁13がOFF、暖房運転時であれば第2電磁
弁14がOFFの時に室内ユニット3の運転が停止され
たと判定することができる。
First, the closed state determination means of the control device 21 determines whether or not the operation of one of the indoor units 3 is stopped (step S1). This determination can be made by the operation signal output from the operation panel 31, but may be made by the energized state of the indoor fan 20, or when the cooling operation is performed, the first electromagnetic valve 13 and the heating operation are performed. If so, the determination may be made based on the energized state of the second solenoid valve 14.
That is, it can be determined that the operation of the indoor unit 3 is stopped when the indoor fan 20 is OFF, the first electromagnetic valve 13 is OFF during the cooling operation, and the second electromagnetic valve 14 is OFF during the heating operation. it can.

【0042】この判定結果がNOの場合、つまり2台の
室内ユニット3が共に運転されている場合は、冷凍機油
滞留防止制御を実行する必要がないため、処理を停止す
る。ステップS1の判定結果がYESの場合、つまり何
方か一方の室内ユニット3の運転が停止された場合は、
制御装置21の比較判定手段により、温度センサ29と
温度センサ30の各検出値の差(Ta−Tb)が設定値
T1 より大きいか否かを判定する(ステップS2)。
When the result of this determination is NO, that is, when the two indoor units 3 are both operating, there is no need to execute the refrigerating machine oil retention control, so the processing is stopped. When the determination result of step S1 is YES, that is, when the operation of one of the indoor units 3 is stopped,
The comparison and determination means of the control device 21 determines whether or not the difference (Ta-Tb) between the detection values of the temperature sensor 29 and the temperature sensor 30 is larger than the set value T1 (step S2).

【0043】ここで、運転を停止した室内ユニット3に
冷凍機油が滞留していくと、オイル分離器26の貯留室
26bに貯留された冷凍機油量が除々に減少していく。
そして、貯留室26bの冷凍機油面(図2のA位置)が
第2オイル還流管28の開口上端位置(図2のB位置)
まで下がると、第2オイル還流管28より流出する冷凍
機油にガス冷媒が混在する。一方、オイル分離器26の
底面に開口する第1オイル還流管27には、冷凍機油の
みが流出する。
Here, as the refrigerating machine oil accumulates in the indoor unit 3 that has stopped operation, the amount of refrigerating machine oil stored in the storage chamber 26b of the oil separator 26 gradually decreases.
The freezer oil level (position A in FIG. 2) of the storage chamber 26b is the upper end position of the opening of the second oil return pipe 28 (position B in FIG. 2).
When it goes down, the gas refrigerant is mixed in the refrigerating machine oil flowing out from the second oil reflux pipe 28. On the other hand, only the refrigerating machine oil flows out into the first oil return pipe 27 that opens at the bottom surface of the oil separator 26.

【0044】冷凍機油に混在して流れるガス冷媒は、第
2オイル還流管28に設けられた抵抗28aによって減
圧されて温度が低下するため、冷凍機油のみが流出する
第1オイル還流管27に設置された温度センサ29の検
出値Taより第2オイル還流管28に設置された温度セ
ンサ30の検出値Tbの方が低くなる。さらに、冷凍機
油面がB→C→Dと下がるに連れて、第2オイル還流管
28に混在するガス冷媒の割合が多くなることから、図
5に示すように、温度センサ30の検出値Tbは除々に
低くなり、温度センサ29の検出値Taとの差は拡大す
る。その後、貯留室26bの冷凍機油面が第2オイル還
流管28の開口下端位置(図2のD位置)より低下する
と、温度センサ30の検出値Tbが第2オイル還流管2
8を流れるガス冷媒の温度で一定となる。
Since the gas refrigerant mixedly flowing in the refrigerating machine oil is decompressed by the resistance 28a provided in the second oil reflux pipe 28 and its temperature is lowered, it is installed in the first oil reflux pipe 27 through which only the refrigerating machine oil flows out. The detected value Tb of the temperature sensor 30 installed in the second oil recirculation pipe 28 becomes lower than the detected value Ta of the temperature sensor 29 thus set. Furthermore, as the refrigerating machine oil level decreases from B → C → D, the proportion of the gas refrigerant mixed in the second oil return pipe 28 increases, so that the detected value Tb of the temperature sensor 30 as shown in FIG. Gradually decreases, and the difference from the detection value Ta of the temperature sensor 29 increases. After that, when the refrigerating machine oil level in the storage chamber 26b drops below the opening lower end position (position D in FIG. 2) of the second oil reflux pipe 28, the detected value Tb of the temperature sensor 30 is changed to the second oil reflux pipe 2
It becomes constant at the temperature of the gas refrigerant flowing through 8.

【0045】このため、温度センサ29と温度センサ3
0の各検出値の差(Ta−Tb)が設定値T1 以上とな
る場合は、第2オイル還流管28よりガス冷媒が冷凍機
油に混在して流出していると判断することができる。そ
こで、ステップS2の判定結果がYESの場合は、ステ
ップS3の処理(本発明の開制御)で運転を停止した室
内ユニット3の第1電磁弁13(冷房運転時)または第
2電磁弁14(暖房運転時)を一旦ONすることによ
り、運転停止の室内ユニット3の室内熱交換器11に冷
媒を流して、滞留していた冷凍機油を冷媒とともに冷媒
圧縮機4へ還流させることができる。なお、ステップS
2の判定結果がNOの場合は、判定結果がYESになる
までステップS2を繰り返す。
Therefore, the temperature sensor 29 and the temperature sensor 3
When the difference between the detected values of 0 (Ta-Tb) is greater than or equal to the set value T1, it can be determined that the gas refrigerant is mixed with the refrigerating machine oil and flows out from the second oil reflux pipe 28. Therefore, if the determination result in step S2 is YES, the first solenoid valve 13 (during cooling operation) or the second solenoid valve 14 (in the cooling operation) of the indoor unit 3 that has stopped the operation in the process of step S3 (open control of the present invention). By temporarily turning on (during heating operation), the refrigerant can be caused to flow through the indoor heat exchanger 11 of the indoor unit 3 that is not in operation, and the refrigerating machine oil that has stagnated can be returned to the refrigerant compressor 4 together with the refrigerant. Note that step S
If the determination result of 2 is NO, step S2 is repeated until the determination result becomes YES.

【0046】続いて、ステップS3を実行した後、比較
判定手段により、温度センサ29の検出値Taと温度セ
ンサ30の検出値Tbとの差が設定値T2 (但しT1 >
T2)より小さいか否かを判定する(ステップS4)。
この判定結果がYESの場合、つまりTa−Tb<T2
の場合は、第1電磁弁13または第2電磁弁14の開弁
に伴って、運転停止中の室内ユニット3に滞留していた
冷凍機油が還流し、オイル分離器26内の冷凍機油面が
上昇していると判断することができる。
Then, after executing step S3, the difference between the detected value Ta of the temperature sensor 29 and the detected value Tb of the temperature sensor 30 is set by the comparison / determination means T2 (however, T1>
It is determined whether it is smaller than T2) (step S4).
When this determination result is YES, that is, Ta-Tb <T2
In the case of, the refrigerating machine oil staying in the indoor unit 3 which is not operating recirculates with the opening of the first solenoid valve 13 or the second solenoid valve 14, and the refrigerating machine oil level in the oil separator 26 is changed. You can judge that it is rising.

【0047】そこで、一旦ONされた第1電磁弁13
(冷房運転時)または第2電磁弁14(暖房運転時)を
OFFして(ステップS5・本発明の閉制御)、通常の
運転モードに復帰する。なお、ステップS4の判定結果
がNOの場合は、ステップS3へ戻り、ステップS4の
判定結果がYESとなるまで、第1電磁弁13または第
2電磁弁14の開弁状態を保つ。
Therefore, the first solenoid valve 13 that has been turned on once
(During the cooling operation) or the second solenoid valve 14 (during the heating operation) is turned off (step S5, the closing control of the present invention), and the normal operation mode is restored. In addition, when the determination result of step S4 is NO, it returns to step S3 and the open state of the 1st solenoid valve 13 or the 2nd solenoid valve 14 is maintained until the determination result of step S4 becomes YES.

【0048】このように、本実施例では、オイル分離器
26より冷媒圧縮機4へ還流する冷凍機油の不足が検出
された時だけ第1電磁弁13(冷房運転時)または第2
電磁弁14(暖房運転時)の開閉制御を行なうことがで
きるため、第1電磁弁13または第2電磁弁14を開弁
する頻度が少なくなる。これにより、第1電磁弁13ま
たは第2電磁弁14が開弁した時の冷凍サイクルバラン
スの頻繁な崩れがなくなることで空調フィーリングが向
上する。
As described above, in this embodiment, the first electromagnetic valve 13 (during cooling operation) or the second electromagnetic valve 13 is operated only when the shortage of the refrigerating machine oil flowing back to the refrigerant compressor 4 from the oil separator 26 is detected.
Since the opening / closing control of the solenoid valve 14 (during the heating operation) can be performed, the frequency of opening the first solenoid valve 13 or the second solenoid valve 14 decreases. As a result, the refrigeration cycle balance is not frequently collapsed when the first solenoid valve 13 or the second solenoid valve 14 is opened, so that the air conditioning feeling is improved.

【0049】また、本実施例では、負荷条件、配管長、
室内ユニット3の台数、空気調和装置1の施行状態等の
相違、および第1電磁弁13、第2電磁弁14の漏れの
ばらつきによらず、冷媒圧縮機4の冷凍機油不足を安
定、且つ未然に防止することができる。
In this embodiment, the load condition, the pipe length,
Regardless of the number of indoor units 3, differences in the operating state of the air conditioner 1, and variations in the leakage of the first solenoid valve 13 and the second solenoid valve 14, a shortage of refrigerating machine oil in the refrigerant compressor 4 is stable and Can be prevented.

【0050】〔変形例〕本実施例では、オイル分離器2
6より冷媒圧縮機4へ還流する冷凍機油量の不足を2つ
の温度センサ29、30の検出値に基づいて判断した
が、オイル分離器26内に貯留された冷凍機油の液面を
検出する液面検出手段を設けて、この液面検出手段の検
出値に基づいて冷凍機油量の不足を判断することもでき
る。
[Modification] In this embodiment, the oil separator 2 is used.
Although the amount of refrigerating machine oil flowing back to the refrigerant compressor 4 from 6 is determined based on the detection values of the two temperature sensors 29 and 30, a liquid for detecting the liquid level of the refrigerating machine oil stored in the oil separator 26. It is also possible to provide the surface detection means and judge whether the refrigerator oil amount is insufficient based on the detection value of the liquid level detection means.

【0051】本実施例では、運転モードに応じて冷媒圧
縮機4より吐出された冷媒の循環方向を四方弁5によっ
て切り替えるヒートポンプ式冷凍サイクルを説明した
が、本発明の冷凍サイクルは、室内熱交換器11を冷房
用熱交換器(冷媒蒸発器)として使用する冷房サイク
ル、または室内熱交換器11を暖房用熱交換器(冷媒凝
縮器)として使用する暖房サイクルに適用することもで
きる。
In this embodiment, the heat pump type refrigeration cycle in which the circulation direction of the refrigerant discharged from the refrigerant compressor 4 is switched by the four-way valve 5 in accordance with the operation mode has been described. It can also be applied to a cooling cycle in which the heat exchanger 11 is used as a heat exchanger for cooling (refrigerant evaporator) or a heating cycle in which the indoor heat exchanger 11 is used as a heat exchanger for heating (refrigerant condenser).

【0052】本実施例では、室外絞り7と室内絞り12
の2つの減圧手段を設けたが、第1電磁弁13に減圧膨
脹機能を持たせることで、室外絞り7および室内絞り1
2を廃止することもできる。つまり、第1電磁弁13
は、弁開度に応じて通過する冷媒流量を調節できる構造
として、この流量調節機能によって冷房運転時に室内熱
交換器11へ供給される冷媒を減圧膨脹する。
In this embodiment, the outdoor diaphragm 7 and the indoor diaphragm 12 are arranged.
Although the two pressure reducing means are provided, the outdoor throttle 7 and the indoor throttle 1 are provided by providing the first solenoid valve 13 with the pressure reducing and expanding function.
2 can be abolished. That is, the first solenoid valve 13
Has a structure in which the flow rate of the refrigerant passing therethrough can be adjusted according to the valve opening degree, and the flow rate adjusting function decompresses and expands the refrigerant supplied to the indoor heat exchanger 11 during the cooling operation.

【0053】本実施例では、室内ユニット3を2台設置
した場合を例示したが、3台以上設置した場合におい
て、運転を停止した室内ユニット3が2台以上あって
も、少なくとも1台の室内ユニット3について冷凍機油
滞留防止制御を実行することができる。もちろん、運転
を停止したすべての室内ユニット3に対して冷凍機油滞
留防止制御を実行することで、早期に冷凍機油不足を解
消できることは言うまでもない。
In this embodiment, the case where two indoor units 3 are installed is illustrated, but when three or more indoor units 3 are installed, even if there are two or more indoor units 3 that have stopped operation, at least one indoor unit 3 is installed. The refrigerating machine oil retention control can be executed for the unit 3. Of course, it is needless to say that the lack of refrigerating machine oil can be eliminated early by executing the refrigerating machine oil retention control for all the indoor units 3 that have stopped operation.

【図面の簡単な説明】[Brief description of drawings]

【図1】空気調和装置の全体模式図である。FIG. 1 is an overall schematic diagram of an air conditioner.

【図2】オイル還流手段の模式図である。FIG. 2 is a schematic diagram of an oil return means.

【図3】本実施例の制御系に係わるブロック図である。FIG. 3 is a block diagram relating to a control system of this embodiment.

【図4】本実施例の作動を示すフローチャートである。FIG. 4 is a flowchart showing the operation of this embodiment.

【図5】オイル分離器内の冷凍機油面の位置とセンサ温
度との関係を示すグラフである。
FIG. 5 is a graph showing the relationship between the position of the oil level of the refrigerator in the oil separator and the sensor temperature.

【図6】従来技術に係わる空気調和装置の模式図であ
る。
FIG. 6 is a schematic diagram of an air conditioner according to a conventional technique.

【符号の説明】[Explanation of symbols]

1 空気調和装置 4 冷媒圧縮機 5 四方弁(循環方向切替手段) 11 室内熱交換器 13 第1電磁弁(開閉手段) 14 第2電磁弁(開閉手段) 17 ガス側配管(冷媒配管) 18 液側配管(冷媒配管) 21 制御装置(制御手段) 26 オイル分離器(オイル還流手段) 27 第1オイル還流管(オイル還流手段) 28 第2オイル還流管(オイル還流手段) 29 温度センサ(油量検出手段) 30 温度センサ(油量検出手段) 1 Air Conditioner 4 Refrigerant Compressor 5 Four-way Valve (Circulation Direction Switching Means) 11 Indoor Heat Exchanger 13 First Electromagnetic Valve (Opening / Closing Means) 14 Second Solenoid Valve (Opening / Closing Means) 17 Gas Side Pipe (Refrigerant Piping) 18 Liquid Side pipe (refrigerant pipe) 21 Control device (control means) 26 Oil separator (oil return means) 27 First oil return pipe (oil return means) 28 Second oil return pipe (oil return means) 29 Temperature sensor (oil amount) Detection means) 30 Temperature sensor (oil amount detection means)

Claims (10)

【特許請求の範囲】[Claims] 【請求項1】a)一台または複数台の冷媒圧縮機に対し
て並列に分岐接続された複数の室内熱交換器を有すると
ともに、個々の前記室内熱交換器に通じる各冷媒配管に
それぞれ介在されて、開状態の時に前記冷媒配管を開
き、閉状態の時に前記冷媒配管を閉じる複数の開閉手段
を備えた冷凍サイクルと、 b)この冷凍サイクルで前記冷媒圧縮機の冷媒吐出側に
介在されて、前記冷媒圧縮機より吐出された冷媒に含ま
れる冷凍機油を冷媒より分離して、前記冷媒圧縮機へ還
流させるオイル還流手段と、 c)このオイル還流手段により前記冷媒圧縮機へ還流す
る冷凍機油量を検出する油量検出手段と、 d)この油量検出手段の検出値を設定値と比較する比較
判定手段と、 e)前記冷媒圧縮機の運転時に、複数の前記開閉手段の
うち閉状態の前記開閉手段があるか否かを判定する閉状
態判定手段と、 f)この閉状態判定手段で閉状態の前記開閉手段がある
と判定された場合において、前記比較判定手段で前記油
量検出手段の検出値が前記設定値以下であると判定され
た場合は、閉状態の前記開閉手段のうち少なくとも1つ
を開状態とする開制御を行なう制御手段とを備えた空気
調和装置。
1. An a) having a plurality of indoor heat exchangers that are branched and connected in parallel to one or a plurality of refrigerant compressors, and interposed in each refrigerant pipe leading to each of the indoor heat exchangers. A refrigeration cycle having a plurality of opening / closing means for opening the refrigerant pipe in the open state and closing the refrigerant pipe in the closed state; and b) interposing on the refrigerant discharge side of the refrigerant compressor in the refrigeration cycle. An oil recirculation means for separating refrigerating machine oil contained in the refrigerant discharged from the refrigerant compressor from the refrigerant and returning it to the refrigerant compressor; and c) refrigeration for returning to the refrigerant compressor by the oil recirculation means. An oil amount detecting means for detecting the amount of machine oil; d) a comparing and judging means for comparing the detected value of the oil amount detecting means with a set value; and e) closing the plurality of opening / closing means when the refrigerant compressor is in operation. State of the A closed state judging means for judging whether or not there is an opening / closing means, and f) in the case where the closed state judging means judges that there is the opening / closing means in the closed state, the comparison judging means judges whether the oil amount detecting means An air conditioner comprising: a control unit that performs open control to open at least one of the opening / closing units in the closed state when it is determined that the detected value is equal to or less than the set value.
【請求項2】前記制御手段は、前記開制御を実行した
後、前記比較判定手段で前記油量検出手段の検出値が前
記設定値より大きいと判定された場合は、前記開制御に
よって開状態となった前記開閉手段を再び閉状態とする
閉制御を行なうことを特徴とする請求項1記載の空気調
和装置。
2. The control means, after executing the opening control, if the comparison determination means determines that the detection value of the oil amount detection means is larger than the set value, the open state is determined by the opening control. The air conditioner according to claim 1, wherein the closing control is performed to close the opened and closed means again.
【請求項3】前記オイル還流手段は、冷媒と冷凍機油と
を分離して、その分離した冷凍機油を貯留するオイル分
離器と、一端が前記オイル分離器内に開口して他端が前
記冷媒圧縮機の冷媒吸入口に連絡されたオイル還流管と
を有し、 前記油量検出手段は、前記オイル還流管を流れる冷凍機
油の温度を検出する油温検出手段を有し、この油温検出
手段の検出値に基づいて前記オイル分離器より前記冷媒
圧縮機へ還流する冷凍機油量を検出することを特徴とす
る請求項1または2記載の空気調和装置。
3. The oil recirculation means separates the refrigerant and the refrigerating machine oil and stores the separated refrigerating machine oil, and one end is opened in the oil separator and the other end is the refrigerant. An oil recirculation pipe connected to the refrigerant suction port of the compressor, and the oil amount detection means has an oil temperature detection means for detecting the temperature of the refrigerating machine oil flowing through the oil recirculation pipe. The air conditioner according to claim 1 or 2, wherein the amount of refrigerating machine oil flowing back to the refrigerant compressor from the oil separator is detected based on the detection value of the means.
【請求項4】前記オイル還流管は、前記オイル分離器に
貯留された冷凍機油が所定量減少した時に、冷凍機油と
ともにガス冷媒が前記オイル分離器より流出するよう
に、前記一端が前記オイル分離器の底面より所定の高さ
位置に開口することを特徴とする請求項3記載の空気調
和装置。
4. The oil separation pipe has one end for separating the oil so that a gas refrigerant flows out from the oil separator together with the refrigerating machine oil when the refrigerating machine oil stored in the oil separator decreases by a predetermined amount. The air conditioner according to claim 3, wherein the air conditioner is opened at a predetermined height position from the bottom surface of the vessel.
【請求項5】前記油量検出手段は、前記オイル分離器に
貯留された冷凍機油の液面を検出する液面検出手段を有
し、この液面検出手段の検出値に基づいて前記オイル分
離器より前記冷媒圧縮機へ還流する冷凍機油量を検出す
ることを特徴とする請求項3または4記載の空気調和装
置。
5. The oil amount detecting means has a liquid level detecting means for detecting the liquid level of the refrigerating machine oil stored in the oil separator, and the oil separating means is based on the detection value of the liquid level detecting means. The air conditioner according to claim 3 or 4, wherein an amount of refrigerating machine oil flowing back to the refrigerant compressor from a refrigerator is detected.
【請求項6】前記室内熱交換器は、内部を流れる低温低
圧の冷媒との熱交換によって通過する空気を冷却する冷
房用熱交換器であることを特徴とする請求項1〜5の何
れかに記載の空気調和装置。
6. The indoor heat exchanger is a cooling heat exchanger for cooling air passing therethrough by heat exchange with a low-temperature low-pressure refrigerant flowing inside. The air conditioner according to 1.
【請求項7】前記室内熱交換器は、内部を流れる高温高
圧の冷媒との熱交換によって通過する空気を加熱する暖
房用熱交換器であることを特徴とする請求項1〜5の何
れかに記載の空気調和装置。
7. The indoor heat exchanger is a heating heat exchanger for heating air passing therethrough by heat exchange with a high-temperature and high-pressure refrigerant flowing inside. The air conditioner according to 1.
【請求項8】前記冷凍サイクルは、冷房運転と暖房運転
との切り替えに応じて前記冷媒圧縮機より吐出された冷
媒の循環方向を切り替える循環方向切替手段を有し、 前記室内熱交換器は、前記冷房運転の時に低温低圧の冷
媒が供給されて、その低温低圧の冷媒との熱交換によっ
て通過する空気を冷却する冷房用熱交換器として機能
し、前記暖房運転の時に高温高圧の冷媒が供給されて、
その高温高圧の冷媒との熱交換によって通過する空気を
加熱する暖房用熱交換器として機能することを特徴とす
る請求項1〜5の何れかに記載の空気調和装置。
8. The refrigeration cycle has a circulation direction switching means for switching the circulation direction of the refrigerant discharged from the refrigerant compressor according to switching between cooling operation and heating operation, and the indoor heat exchanger comprises: A low-temperature low-pressure refrigerant is supplied during the cooling operation, and functions as a cooling heat exchanger that cools passing air by heat exchange with the low-temperature low-pressure refrigerant, and a high-temperature high-pressure refrigerant is supplied during the heating operation. Has been
The air conditioner according to any one of claims 1 to 5, which functions as a heating heat exchanger that heats passing air by heat exchange with the high-temperature and high-pressure refrigerant.
【請求項9】前記開閉手段は、冷媒の流れ方向において
前記室内熱交換器の上流側に設置されたことを特徴とす
る請求項1〜8の何れかに記載の空気調和装置。
9. The air conditioner according to claim 1, wherein the opening / closing means is installed upstream of the indoor heat exchanger in the flow direction of the refrigerant.
【請求項10】前記開閉手段は、弁開度に応じて通過す
る冷媒流量を調節する流量調節機能を有し、この流量調
節機能によって冷房運転時に前記室内熱交換器へ供給さ
れる冷媒を減圧膨脹することを特徴とする請求項6また
は8記載の空気調和装置。
10. The opening / closing means has a flow rate adjusting function for adjusting the flow rate of the refrigerant passing therethrough according to the valve opening degree, and the flow rate adjusting function reduces the pressure of the refrigerant supplied to the indoor heat exchanger during cooling operation. The air conditioner according to claim 6 or 8, wherein the air conditioner expands.
JP13458294A 1994-06-16 1994-06-16 Air conditioner Expired - Fee Related JP3467837B2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP13458294A JP3467837B2 (en) 1994-06-16 1994-06-16 Air conditioner

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP13458294A JP3467837B2 (en) 1994-06-16 1994-06-16 Air conditioner

Publications (2)

Publication Number Publication Date
JPH085167A true JPH085167A (en) 1996-01-12
JP3467837B2 JP3467837B2 (en) 2003-11-17

Family

ID=15131743

Family Applications (1)

Application Number Title Priority Date Filing Date
JP13458294A Expired - Fee Related JP3467837B2 (en) 1994-06-16 1994-06-16 Air conditioner

Country Status (1)

Country Link
JP (1) JP3467837B2 (en)

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Publication number Priority date Publication date Assignee Title
JPH10232056A (en) * 1997-02-20 1998-09-02 Hitachi Ltd Air-conditioning device
JP2001324247A (en) * 2000-05-16 2001-11-22 Sanyo Electric Co Ltd Oil level detector for high pressure conveyor and air conditioning apparatus
JP2008249231A (en) * 2007-03-30 2008-10-16 Yanmar Co Ltd Air conditioner
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US20160116196A1 (en) * 2014-10-27 2016-04-28 Lg Electronics Inc. Oil separator and air conditioner including an oil separator
CN105588361A (en) * 2015-11-04 2016-05-18 青岛海信日立空调系统有限公司 Multi-split air-conditioning system
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Cited By (19)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH10232056A (en) * 1997-02-20 1998-09-02 Hitachi Ltd Air-conditioning device
JP2001324247A (en) * 2000-05-16 2001-11-22 Sanyo Electric Co Ltd Oil level detector for high pressure conveyor and air conditioning apparatus
JP2008249231A (en) * 2007-03-30 2008-10-16 Yanmar Co Ltd Air conditioner
EP2730862A1 (en) * 2012-11-12 2014-05-14 LG Electronics Inc. Air conditioner with an oil separator
US20140130539A1 (en) * 2012-11-12 2014-05-15 Pilhyun Yoon Oil separator and air conditioner using the same
US9500396B2 (en) 2012-11-12 2016-11-22 Lg Electronics Inc. Oil separator and air conditioner using the same
CN103471299A (en) * 2013-08-30 2013-12-25 青岛海信日立空调系统有限公司 Multi-connected air-conditioner oil control system and oil control method
EP3015796A1 (en) * 2014-10-27 2016-05-04 LG Electronics Inc. Oil separator and air conditioner including an oil separator
CN105546894A (en) * 2014-10-27 2016-05-04 Lg电子株式会社 Oil separator and air conditioner
US20160116196A1 (en) * 2014-10-27 2016-04-28 Lg Electronics Inc. Oil separator and air conditioner including an oil separator
CN105546894B (en) * 2014-10-27 2018-04-06 Lg电子株式会社 Work oil eliminator and air regulator
US10684049B2 (en) 2014-10-27 2020-06-16 Lg Electronics Inc. Oil separator and air conditioner including an oil separator
CN105588361A (en) * 2015-11-04 2016-05-18 青岛海信日立空调系统有限公司 Multi-split air-conditioning system
CN108362024A (en) * 2017-01-26 2018-08-03 荏原冷热系统株式会社 Centrifugal refrierator
CN108362024B (en) * 2017-01-26 2021-01-12 荏原冷热系统株式会社 Centrifugal refrigerator
CN109916106A (en) * 2019-04-25 2019-06-21 南京天加环境科技有限公司 A kind of heat pump air conditioner unit that can control lubricating oil temperature and its control method
CN109916106B (en) * 2019-04-25 2024-02-27 南京天加环境科技有限公司 Heat pump air conditioner unit capable of controlling temperature of lubricating oil and control method thereof
JP2021148348A (en) * 2020-03-18 2021-09-27 株式会社富士通ゼネラル Air conditioning device
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