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JPH08251984A - Controller for single phase induction motor - Google Patents

Controller for single phase induction motor

Info

Publication number
JPH08251984A
JPH08251984A JP7070569A JP7056995A JPH08251984A JP H08251984 A JPH08251984 A JP H08251984A JP 7070569 A JP7070569 A JP 7070569A JP 7056995 A JP7056995 A JP 7056995A JP H08251984 A JPH08251984 A JP H08251984A
Authority
JP
Japan
Prior art keywords
induction motor
phase induction
power supply
main winding
current
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.)
Pending
Application number
JP7070569A
Other languages
Japanese (ja)
Inventor
Tomonori Kinoshita
知則 木下
Takashi Miyauchi
貴 宮内
Yoshihiko Nagase
好彦 長瀬
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.)
Sanyo Electric Co Ltd
Original Assignee
Sanyo Electric 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 Sanyo Electric Co Ltd filed Critical Sanyo Electric Co Ltd
Priority to JP7070569A priority Critical patent/JPH08251984A/en
Publication of JPH08251984A publication Critical patent/JPH08251984A/en
Pending legal-status Critical Current

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  • Control Of Ac Motors In General (AREA)

Abstract

PURPOSE: To obtain a controller for single phase induction motor in which vibration and noise caused by transient variation in torque can be reduced at the time of starting or stopping the induction motor. CONSTITUTION: A single phase induction motor 1 comprises main winding M and auxiliary winding A. The controller for the single phase induction motor comprises a sensor VT for detecting the power supply voltage, and a relay controller RC taking charge of the operation control. The relay controller RC contains a data related to the delay angle of main winding current IM from the power supply voltage under locked state and applies the power supply with a delay angle, determined based on the output from the sensor VT, from zero point of the power supply voltage or the vicinity thereof.

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、冷蔵庫や空気調和機
(エアコン)にて代表される冷凍機などに使用される単
相誘導電動機の制御装置に関するものである。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a control device for a single-phase induction motor used in refrigerators and refrigerators typified by air conditioners (air conditioners).

【0002】[0002]

【従来の技術】従来よりこの種単相誘導電動機は、例え
ば特開平5−122992号公報(H02P7/63
2)に示される如く商用単相100Vにて駆動すること
ができ、堅牢、長寿命、低コストと云う特徴があるため
に、冷蔵庫や空気調和機などの圧縮機駆動用としてに広
く用いられている。以下、図8乃至図12の電気回路を
参照しながら係る従来の一般的な単相誘導電動機100
を説明する。
2. Description of the Related Art Conventionally, a single-phase induction motor of this type has been disclosed in, for example, Japanese Patent Laid-Open No. 122992/1993 (H02P7 / 63).
As shown in 2), it can be driven by a commercial single-phase 100V, and because it is robust, has a long service life, and has low cost, it is widely used for driving compressors such as refrigerators and air conditioners. There is. Hereinafter, the conventional general single-phase induction motor 100 will be described with reference to the electric circuits of FIGS.
Will be explained.

【0003】図8において、単相誘導電動機100は主
巻線Mと、補助巻線Aとを備えており、係る単相誘導電
動機100には、前記補助巻線Aに直列に接続された運
転コンデンサCRと、この運転コンデンサCRに並列に
接続された始動コンデンサCSと始動リレースイッチS
W2との直列回路と、単相誘導電動機100への電源印
可を制御する電源リレースイッチSW1とが設けられて
いる。
In FIG. 8, a single-phase induction motor 100 is provided with a main winding M and an auxiliary winding A. The single-phase induction motor 100 is connected to the auxiliary winding A in series. Capacitor CR, starting capacitor CS and starting relay switch S connected in parallel with this operating capacitor CR
A series circuit with W2 and a power relay switch SW1 for controlling power application to the single-phase induction motor 100 are provided.

【0004】係る単相誘導電動機100は単相交流10
0V電源ACに接続されると共に、単相誘導電動機10
0の始動時には始動リレースイッチSW2は閉じてい
る。従って、補助巻線Aには運転コンデンサCRと始動
コンデンサCSの並列回路が接続され、前記電源リレー
スイッチSW1が閉じると、単相誘導電動機100は大
なる始動トルクを得て始動する。その後、同期速度の8
0%程となったところで始動リレースイッチSW2を開
き、始動コンデンサCSを回路から切り離して、以後は
運転コンデンサCRによる主巻線Mと補助巻線Aの電流
位相差にて単相誘導電動機100は運転を継続するもの
であった。
Such a single-phase induction motor 100 has a single-phase alternating current 10
The single-phase induction motor 10 is connected to the 0V power supply AC.
At the start of 0, the start relay switch SW2 is closed. Therefore, a parallel circuit of the operating capacitor CR and the starting capacitor CS is connected to the auxiliary winding A, and when the power relay switch SW1 is closed, the single-phase induction motor 100 starts with a large starting torque. After that, the synchronous speed of 8
At about 0%, the starting relay switch SW2 is opened, the starting capacitor CS is disconnected from the circuit, and thereafter the single-phase induction motor 100 is driven by the current phase difference between the main winding M and the auxiliary winding A due to the operating capacitor CR. It was to continue driving.

【0005】また、図9は前記始動コンデンサCSを用
いずに運転コンデンサCRのみ補助巻線Aに接続した回
路であり、始動特性はあまり良くないが、始動リレース
イッチSW2その他の素子を省けるため、比較的始動ト
ルクの小さい機器に賞用されるものであった。
FIG. 9 shows a circuit in which only the operating capacitor CR is connected to the auxiliary winding A without using the starting capacitor CS. The starting characteristic is not so good, but the starting relay switch SW2 and other elements can be omitted. It was used for equipment with relatively small starting torque.

【0006】更に、図10は前記始動コンデンサCSと
始動リレースイッチSW2の代わりに正温度係数固体素
子PTCを補助巻線Aに接続したものである。この正温
度係数固体素子PTCは温度に比例して抵抗値が増大す
る半導体素子であり、単相誘導電動機100の始動時、
正温度係数固体素子PTCの温度は低く、抵抗値も低い
ために補助巻線Aには大なる電流が流れて始動する。
Further, in FIG. 10, a positive temperature coefficient solid-state element PTC is connected to the auxiliary winding A instead of the starting capacitor CS and the starting relay switch SW2. This positive temperature coefficient solid-state element PTC is a semiconductor element whose resistance value increases in proportion to temperature, and when the single-phase induction motor 100 is started,
Since the temperature of the positive temperature coefficient solid state element PTC is low and the resistance value is also low, a large current flows through the auxiliary winding A to start the operation.

【0007】この通電によって正温度係数固体素子PT
Cは自己発熱するため、抵抗値が増大していくため、正
温度係数固体素子PTCに流れる電流は激減する。従っ
て、以後は運転コンデンサCRによる主巻線Mと補助巻
線Aの電流位相差にて単相誘導電動機100は運転を継
続するものであった。
By this energization, the positive temperature coefficient solid-state element PT
Since C self-heats and its resistance value increases, the current flowing through the positive temperature coefficient solid-state element PTC decreases drastically. Therefore, after that, the single-phase induction motor 100 continued to operate due to the current phase difference between the main winding M and the auxiliary winding A due to the operating capacitor CR.

【0008】更にまた、図11は図8の始動リレースイ
ッチSW2を上記正温度係数固体素子PTCに置換した
ものであり、図12は図10の正温度係数固体素子PT
Cに始動リレースイッチSW2を接続して、始動終了後
完全に正温度係数固体素子PTCを回路から切り離すよ
うにしたものである。
Further, FIG. 11 shows a case where the starting relay switch SW2 of FIG. 8 is replaced with the positive temperature coefficient solid state element PTC, and FIG. 12 shows a positive temperature coefficient solid state element PT of FIG.
A starting relay switch SW2 is connected to C so that the positive temperature coefficient solid-state element PTC is completely disconnected from the circuit after completion of starting.

【0009】[0009]

【発明が解決しようとする課題】ここで、前記電源AC
の電圧(以下、電源電圧と称する)V、主巻線Mを流れ
る電流(以下、主巻線電流と称する)IM、補助巻線A
を流れる電流(以下、補助巻線電流と称する)IA、及
び、それらの和である回路電流Iは、それぞれ位相の異
なる正弦波となるが、従来では単相誘導電動機100の
始動時、これらの各値とは無関係に電源リレースイッチ
SW1が閉じられていた。
Here, the power supply AC
(Hereinafter, referred to as power supply voltage) V, a current flowing through the main winding M (hereinafter, referred to as main winding current) IM, and an auxiliary winding A
A current (hereinafter, referred to as an auxiliary winding current) IA and a circuit current I, which is the sum thereof, are sine waves having different phases. Conventionally, these currents are generated when the single-phase induction motor 100 is started. The power relay switch SW1 was closed regardless of each value.

【0010】そのため、例えば主巻線電流IMが最大値
となる時点で電源リレースイッチSW1が閉じられる
と、始動時の過渡トルクが異常に大きくなり、その結
果、単相誘導電動機100及び前記圧縮機の始動時にお
ける振動・騒音が大きくなる問題があった。
Therefore, for example, when the power relay switch SW1 is closed at the time when the main winding current IM reaches the maximum value, the transient torque at the time of starting becomes abnormally large, and as a result, the single-phase induction motor 100 and the compressor. There was a problem that vibration and noise at the time of starting the vehicle increased.

【0011】同様に単相誘導電動機100の停止時、従
来では上記各電圧或いは電流の値に無関係に電源リレー
スイッチSW1を回路していたため、例えば主巻線電流
IMが最大値となる時点で電源リレースイッチSW1が
開路すると、トルクは大きな値から急激に零に至るた
め、やはり単相誘導電動機100及び前記圧縮機の振動
・騒音が大きくなる問題があった。
Similarly, when the single-phase induction motor 100 is stopped, the power supply relay switch SW1 is conventionally circuited irrespective of the value of each voltage or current, so that the power supply is turned on at the time when the main winding current IM reaches its maximum value, for example. When the relay switch SW1 is opened, the torque suddenly drops from a large value to zero, so that there is a problem that the vibration and noise of the single-phase induction motor 100 and the compressor also increase.

【0012】本発明は、係る従来の技術的課題を解決す
るために成されたものであり、始動、或いは、停止時の
過渡トルク変化による振動・騒音の発生を低減すること
ができる単相誘導電動機の制御装置を提供することを目
的とする。
The present invention has been made in order to solve the above-mentioned conventional technical problems, and is a single-phase induction capable of reducing the generation of vibration and noise due to a transient torque change at the time of starting or stopping. An object is to provide a control device for an electric motor.

【0013】[0013]

【課題を解決するための手段】請求項1の発明の制御装
置は、主巻線と補助巻線と有する単相誘導電動機に適用
され、電源電圧を検出する電圧検出手段と、運転制御を
司る制御手段とを備えており、この制御手段は、拘束状
態における前記電源電圧からの前記主巻線電流の遅れ角
に関するデータを有し、電圧検出手段の出力に基づき、
前記電源電圧の零若しくは零付近から前記遅れ角だけ遅
れて電源を印可するものである。
A control device according to the invention of claim 1 is applied to a single-phase induction motor having a main winding and an auxiliary winding, and controls a voltage detecting means for detecting a power supply voltage and an operation control. And a control means, the control means having data on a delay angle of the main winding current from the power supply voltage in a restrained state, based on the output of the voltage detection means,
The power supply is applied with a delay of the delay angle from zero or near zero of the power supply voltage.

【0014】請求項2の発明の制御装置は、主巻線と補
助巻線と有する単相誘導電動機に適用され、主巻線電流
を検出する電流検出手段と、運転制御を司る制御手段と
を備えており、この制御手段は、電流検出手段の出力に
基づき、前記主巻線電流の零若しくは零付近において電
源を断つものである。
A control device according to a second aspect of the present invention is applied to a single-phase induction motor having a main winding and an auxiliary winding, and includes a current detecting means for detecting a main winding current and a control means for controlling operation. This control means cuts off the power supply at or near zero of the main winding current based on the output of the current detection means.

【0015】請求項3の発明の制御装置は、主巻線と補
助巻線と有する単相誘導電動機に適用され、電源電圧を
検出する電圧検出手段と、前記主巻線電流を検出する電
流検出手段と、運転制御を司る制御手段とを備えてお
り、この制御手段は、拘束状態における前記電源電圧か
らの前記主巻線電流の遅れ角に関するデータを有してお
り、電圧検出手段の出力に基づき、前記電源電圧の零若
しくは零付近から前記遅れ角だけ遅れて電源を印可する
と共に、電流検出手段の出力に基づき、前記主巻線電流
の零若しくは零付近において電源を断つものである。
A control device according to a third aspect of the invention is applied to a single-phase induction motor having a main winding and an auxiliary winding, and a voltage detecting means for detecting a power supply voltage and a current detecting for detecting the main winding current. Means and control means for controlling the operation, the control means has data on the delay angle of the main winding current from the power supply voltage in the restrained state, the output of the voltage detection means. Based on this, the power supply is applied with the delay angle delayed from the power supply voltage at or near zero, and the power supply is cut off at or near zero of the main winding current based on the output of the current detection means.

【0016】[0016]

【作用】請求項1の発明の単相誘導電動機の制御装置に
よれば、制御手段が、拘束状態における電源電圧からの
主巻線電流の遅れ角に関するデータを有しており、電圧
検出手段の出力に基づき、電源電圧の零若しくは零付近
から当該遅れ角だけ遅れて電源を印可するので、単相誘
導電動機の始動時、主巻線電流は零若しくは零付近の値
から流れ始める。従って、異常な過渡トルクは発生せ
ず、始動時における振動や騒音を低減することが可能と
なる。
According to the control device for a single-phase induction motor of the present invention, the control means has data relating to the delay angle of the main winding current from the power supply voltage in the restrained state, and the control means of the voltage detection means. Based on the output, the power supply is applied with a delay angle from or near zero of the power supply voltage, so that the main winding current starts to flow from zero or a value near zero when the single-phase induction motor is started. Therefore, abnormal transient torque is not generated, and it is possible to reduce vibration and noise at the time of starting.

【0017】請求項2の発明の単相誘導電動機の制御装
置によれば、制御手段が、電流検出手段の出力に基づ
き、主巻線電流の零若しくは零付近において電源を断つ
ので、トルク発生への寄与度の大きい主巻線電流をこの
時点において零若しくは零付近とし、補助巻線電流のみ
による小さいトルクとすることができる。従って、断電
時におけるトルク変化が係る補助巻線電流のみによるト
ルクから零への小さい変化となり、停止時における振動
や騒音を低減することが可能となる。
According to the control device for a single-phase induction motor of the second aspect of the invention, the control means cuts off the power supply at or near zero of the main winding current based on the output of the current detection means, so that the torque is generated. It is possible to make the main winding current, which has a large contribution, to zero or near zero at this point, and to make a small torque by only the auxiliary winding current. Therefore, the torque change at the time of power interruption becomes a small change from the torque to zero due to only the auxiliary winding current, and the vibration and noise at the time of stop can be reduced.

【0018】請求項3の発明の単相誘導電動機の制御装
置によれば、制御手段が、拘束状態における電源電圧か
らの主巻線電流の遅れ角に関するデータを有しており、
電圧検出手段の出力に基づき、電源電圧の零若しくは零
付近から当該遅れ角だけ遅れて電源を印可すると共に、
電流検出手段の出力に基づき、主巻線電流の零若しくは
零付近において電源を断つものであるから、単相誘導電
動機の始動時と停止時おける過渡トルクを低減して振動
や騒音を著しく減少させることが可能となるものであ
る。
According to the control device for a single-phase induction motor of the third aspect of the invention, the control means has data relating to the delay angle of the main winding current from the power supply voltage in the restrained state,
Based on the output of the voltage detection means, while applying the power supply with a delay angle of zero or near zero of the power supply voltage,
Since the power supply is cut off at or near zero of the main winding current based on the output of the current detection means, the transient torque at the time of starting and stopping the single-phase induction motor is reduced to significantly reduce vibration and noise. It is possible.

【0019】[0019]

【実施例】以下、図面に基づき本発明の実施例を詳述す
る。図1は本発明の一実施例の単相誘導電動機1の電気
回路図を示している。尚、以降の各図において図8乃至
図12と同一符号は同一のものとする。図1において、
単相誘導電動機1は図示しない冷蔵庫(冷凍機)の冷凍
サイクルに含まれる圧縮機を駆動するものであり、主巻
線Mと、補助巻線Aとを備えており、係る単相誘導電動
機1には、前記補助巻線Aに直列に接続された運転コン
デンサCRと、この運転コンデンサCRに並列に接続さ
れた始動コンデンサCSと始動リレースイッチSW2と
の直列回路と、単相誘導電動機1への電源印可を制御す
る電源リレースイッチSW1とが設けられている。
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 shows an electric circuit diagram of a single-phase induction motor 1 according to an embodiment of the present invention. In the following drawings, the same reference numerals as those in FIGS. 8 to 12 are the same. In FIG.
The single-phase induction motor 1 drives a compressor included in a refrigeration cycle of a refrigerator (refrigerator) not shown, and includes a main winding M and an auxiliary winding A. Is connected to the auxiliary winding A in series, a series circuit of a starting capacitor CS and a starting relay switch SW2 connected in parallel to the operating capacitor CR, and to the single-phase induction motor 1. A power relay switch SW1 for controlling power application is provided.

【0020】係る単相誘導電動機1は単相交流(60H
z)100V電源ACに接続される。また、CTは主巻
線Mに流れる主巻線電流IMを検出する電流検出手段と
してのセンサー(カレントトランス)であり、VTは電
源ACの電源電圧Vを検出するセンサー(トランス)で
ある。また、RCは制御手段としての汎用マイクロコン
ピュータから構成されたリレーコントローラである。
The single-phase induction motor 1 is a single-phase alternating current (60H
z) Connected to 100V power supply AC. Further, CT is a sensor (current transformer) as a current detecting means for detecting the main winding current IM flowing in the main winding M, and VT is a sensor (transformer) for detecting the power supply voltage V of the power supply AC. RC is a relay controller composed of a general-purpose microcomputer as a control means.

【0021】そして、前記各センサーCT、VTが検出
した主巻線電流IM及び電源電圧Vの値に関する出力デ
ータはリレーコントローラRCに入力されると共に、リ
レーコントローラRCは各リレースイッチSW1、SW
2を開閉駆動する。また、リレーコントローラRCには
図示しない冷蔵庫の庫内温度を検出する庫内温度センサ
ーなども接続されている。
The output data relating to the values of the main winding current IM and the power supply voltage V detected by the sensors CT and VT are input to the relay controller RC, and the relay controller RC also causes the relay switches SW1 and SW to be switched.
2 is opened and closed. The relay controller RC is also connected to a refrigerator internal temperature sensor (not shown) that detects the refrigerator internal temperature.

【0022】以上の構成で次に動作を説明する。ここ
で、図2は前記電源電圧Vと、拘束状態の継続安定時に
おける本実施例の単相誘導電動機1の回路電流I、主巻
線電流IM、補助巻線電流IAの各波形を示しており、
この場合V=141sinθ(V)、I=22.6si
n(θ−25°)、IM=21.2sin(θ−45
°)、IA=8.5sin(θ+45°)であることが
実験により測定されている。即ち、電源電圧Vからの主
巻線電流IMの遅れ角(電気角)は45°であり、この
データは前記リレーコントローラRCに記憶されている
ものとする。
The operation of the above configuration will be described below. Here, FIG. 2 shows the power supply voltage V and each waveform of the circuit current I, the main winding current IM, and the auxiliary winding current IA of the single-phase induction motor 1 of the present embodiment when the restrained state is continuously stabilized. Cage,
In this case, V = 141 sin θ (V), I = 22.6 si
n (θ−25 °), IM = 21.2 sin (θ−45
), IA = 8.5 sin (θ + 45 °) has been experimentally measured. That is, the delay angle (electrical angle) of the main winding current IM from the power supply voltage V is 45 °, and this data is stored in the relay controller RC.

【0023】今、単相誘導電動機1が停止しているもの
とすると、始動リレースイッチSW2は閉じており、そ
の状態から前記冷蔵庫の庫内温度が上昇して所定の上限
温度に達すると、前記庫内温度センサーより運転指令が
発せられる(実際にはリレーコントローラRC内部でこ
の指令は作られる)。このとき、リレーコントローラR
CはセンサーVTの出力に基づいて電源電圧Vを監視し
ており、前記運転指令が発せられた場合には、当該電源
電圧Vが零若しくは零付近となった時点から、前記遅れ
角(45°)だけ遅れて電源リレースイッチSW1を閉
じる。
Now, assuming that the single-phase induction motor 1 is stopped, the starting relay switch SW2 is closed, and when the refrigerator internal temperature rises from that state to reach a predetermined upper limit temperature, the above-mentioned An operation command is issued from the internal temperature sensor (actually, this command is generated inside the relay controller RC). At this time, the relay controller R
C monitors the power supply voltage V based on the output of the sensor VT, and when the operation command is issued, from the time when the power supply voltage V becomes zero or near zero, the delay angle (45 ° ), The power relay switch SW1 is closed.

【0024】電源リレースイッチSW1が閉じられる
と、主巻線Mと補助巻線Aに電流が流れ始めると共に、
補助巻線Aには始動コンデンサCSと運転コンデンサC
Rの並列回路が接続されるので、単相誘導電動機1は所
要の始動トルクを得て始動する。尚、リレーコントロー
ラRCは同期速度の80%程に増速したところで始動リ
レースイッチSW2を開き、始動コンデンサCSを回路
から切り離す。
When the power relay switch SW1 is closed, current begins to flow in the main winding M and the auxiliary winding A, and
The auxiliary winding A has a starting capacitor CS and an operating capacitor C.
Since the R parallel circuit is connected, the single-phase induction motor 1 starts with a required starting torque. The relay controller RC opens the starting relay switch SW2 when the speed is increased to about 80% of the synchronous speed, and disconnects the starting capacitor CS from the circuit.

【0025】係る単相誘導電動機1の始動時、上述の如
く電源電圧Vが零若しくは零付近となった時点から、前
記遅れ角(45°)だけ遅れて電源リレースイッチSW
1を閉じるので、図2より明らかな如く主巻線電流IM
は零若しくは零付近の値から流れ始める。従って、電源
リレースイッチSW1が閉じた瞬間に従来の如き異常な
過渡トルクは発生せず、始動時における単相誘導電動機
1や前記圧縮機の振動・騒音を低減することができる。
When the single-phase induction motor 1 is started, the power supply relay switch SW is delayed by the delay angle (45 °) from the time when the power supply voltage V becomes zero or near zero as described above.
1 is closed, the main winding current IM is
Starts flowing at or near zero. Therefore, at the moment when the power relay switch SW1 is closed, an abnormal transient torque unlike the conventional one is not generated, and the vibration and noise of the single-phase induction motor 1 and the compressor at the time of starting can be reduced.

【0026】このようにして始動された単相誘導電動機
1の運転中(負荷運転)の回路電流I、主巻線電流I
M、補助巻線電流IAは図3に示されており、この場合
V=141sinθ(同じ)、I=4.2sin(θ−
15°)、IM=2.8sin(θ−55°)、IA=
1.4sin(θ+30°)となる。
The circuit current I and the main winding current I during the operation (load operation) of the single-phase induction motor 1 thus started.
M, auxiliary winding current IA is shown in FIG. 3, where V = 141 sin θ (same), I = 4.2 sin (θ−
15 °), IM = 2.8 sin (θ-55 °), IA =
It becomes 1.4 sin (θ + 30 °).

【0027】そして、前記冷蔵庫の庫内温度が降下して
所定の下限温度に達すると、前記庫内温度センサーより
運転停止指令が発せられる(実際にはリレーコントロー
ラRC内部でこの指令は作られる)。このとき、リレー
コントローラRCはセンサーCTの出力に基づいて主巻
線電流IMを監視しており、前記運転停止指令が発せら
れた場合には、当該主巻線電流IMが図3における零若
しくは零付近となった時点で電源リレースイッチSW1
を開路する。
When the inside temperature of the refrigerator drops and reaches a predetermined lower limit temperature, an operation stop command is issued from the inside temperature sensor (actually, this command is generated inside the relay controller RC). . At this time, the relay controller RC monitors the main winding current IM based on the output of the sensor CT, and when the operation stop command is issued, the main winding current IM is zero or zero in FIG. Power relay switch SW1 when it is near
Open the circuit.

【0028】これによって、主巻線M及び補助巻線Aへ
の通電は断たれるので、単相誘導電動機1は停止する
が、リレーコントローラRCは上述の如く主巻線電流I
Mの零若しくは零付近において電源リレースイッチSW
1を開路するので、トルク発生への寄与度の大きい主巻
線電流IMをこの時点(断電)において零若しくは零付
近とし、補助巻線電流IAのみによる小さいトルクとす
ることができる。従って、断電時におけるトルク変化が
係る補助巻線電流IAのみによるトルクから零への小さ
い変化となり、停止時における単相誘導電動機1や前記
圧縮機の振動・騒音を低減することができる。
As a result, the power supply to the main winding M and the auxiliary winding A is cut off, so that the single-phase induction motor 1 is stopped, but the relay controller RC causes the main winding current I as described above.
Power relay switch SW at or near zero of M
Since 1 is opened, the main winding current IM, which has a large contribution to torque generation, can be zero or near zero at this point (disconnection), and a small torque can be obtained only by the auxiliary winding current IA. Therefore, the torque change at the time of power interruption becomes a small change from the torque to zero due to only the auxiliary winding current IA, and the vibration and noise of the single-phase induction motor 1 and the compressor at the time of stop can be reduced.

【0029】次に、図4は前述の図9の方式のものに本
発明を適用した単相誘導電動機1の電気回路を、また、
図5は前述の図10の方式のものに本発明を適用した単
相誘導電動機1の電気回路を、更に、図6は図11の方
式のものに本発明を適用した単相誘導電動機1の電気回
路をそれぞれ示している。尚、各図において同一符号は
同一のものとする。この場合も始動時及び停止時におけ
るリレーコントローラRCの動作は前述と同様である
が、当然に始動リレースイッチSW2の制御は行わな
い。
Next, FIG. 4 shows an electric circuit of the single-phase induction motor 1 in which the present invention is applied to the system shown in FIG.
FIG. 5 shows the electric circuit of the single-phase induction motor 1 to which the present invention is applied to the system of FIG. 10 described above, and FIG. 6 shows the electric circuit of the single-phase induction motor 1 to which the present invention is applied to the system of FIG. The electric circuits are shown respectively. The same reference numerals are used in the drawings. In this case as well, the operation of the relay controller RC at the time of starting and stopping is the same as that described above, but of course the starting relay switch SW2 is not controlled.

【0030】また、図7は前述の図12の方式のものに
本発明を適用した単相誘導電動機1の電気回路を示して
いるが、この場合リレーコントローラRCは前述(図
1)と同様の制御を行うものである。
FIG. 7 shows an electric circuit of the single-phase induction motor 1 to which the present invention is applied to the system of FIG. 12 described above. In this case, the relay controller RC is the same as that described above (FIG. 1). It controls.

【0031】[0031]

【発明の効果】以上詳述した如く請求項1の発明によれ
ば、制御手段が、拘束状態における電源電圧からの主巻
線電流の遅れ角に関するデータを有しており、電圧検出
手段の出力に基づき、電源電圧の零若しくは零付近から
当該遅れ角だけ遅れて電源を印可するので、単相誘導電
動機の始動時、主巻線電流は零若しくは零付近の値から
流れ始める。従って、異常な過渡トルクは発生せず、始
動時における振動や騒音を低減することが可能となる。
As described in detail above, according to the invention of claim 1, the control means has data concerning the delay angle of the main winding current from the power supply voltage in the restrained state, and the output of the voltage detection means. On the basis of the above, since the power supply is applied with a delay angle from the zero or near zero of the power supply voltage, the main winding current starts to flow from zero or a value near zero when the single-phase induction motor is started. Therefore, abnormal transient torque is not generated, and it is possible to reduce vibration and noise at the time of starting.

【0032】請求項2の発明によれば、制御手段が、電
流検出手段の出力に基づき、主巻線電流の零若しくは零
付近において電源を断つので、トルク発生への寄与度の
大きい主巻線電流をこの時点において零若しくは零付近
とし、補助巻線電流のみによる小さいトルクとすること
ができる。従って、断電時におけるトルク変化が係る補
助巻線電流のみによるトルクから零への小さい変化とな
り、停止時における振動や騒音を低減することが可能と
なる。
According to the invention of claim 2, the control means cuts off the power supply at or near zero of the main winding current based on the output of the current detection means, so that the main winding having a large contribution to torque generation. The current can be zero or near zero at this time, and a small torque due to only the auxiliary winding current can be obtained. Therefore, the torque change at the time of power interruption becomes a small change from the torque to zero due to only the auxiliary winding current, and the vibration and noise at the time of stop can be reduced.

【0033】請求項3の発明によれば、制御手段が、拘
束状態における電源電圧からの主巻線電流の遅れ角に関
するデータを有しており、電圧検出手段の出力に基づ
き、電源電圧の零若しくは零付近から当該遅れ角だけ遅
れて電源を印可すると共に、電流検出手段の出力に基づ
き、主巻線電流の零若しくは零付近において電源を断つ
ものであるから、単相誘導電動機の始動時と停止時おけ
る過渡トルクを低減して振動や騒音を著しく減少させる
ことが可能となるものである。
According to the third aspect of the present invention, the control means has data on the delay angle of the main winding current from the power supply voltage in the restrained state, and the power supply voltage is zero based on the output of the voltage detection means. Alternatively, the power is applied with a delay of the delay angle from around zero, and the power is cut off at or near zero of the main winding current based on the output of the current detection means. It is possible to reduce the transient torque at the time of stoppage and significantly reduce vibration and noise.

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

【図1】本発明の単相誘導電動機の電気回路図である。FIG. 1 is an electric circuit diagram of a single-phase induction motor of the present invention.

【図2】実施例の単相誘導電動機の拘束状態の継続安定
時における電源電圧、回路電流、主巻線電流及び補助巻
線電流の波形を示す図である。
FIG. 2 is a diagram showing waveforms of a power supply voltage, a circuit current, a main winding current, and an auxiliary winding current when the restrained state of the single-phase induction motor of the embodiment is continuously stabilized.

【図3】実施例の単相誘導電動機の運転時(負荷運転)
における電源電圧、回路電流、主巻線電流及び補助巻線
電流の波形を示す図である。
FIG. 3 During operation of the single-phase induction motor of the embodiment (load operation)
6 is a diagram showing waveforms of a power supply voltage, a circuit current, a main winding current, and an auxiliary winding current in FIG.

【図4】本発明の単相誘導電動機のもう一つの電気回路
図である。
FIG. 4 is another electric circuit diagram of the single-phase induction motor of the present invention.

【図5】本発明の単相誘導電動機の更にもう一つの電気
回路図である。
FIG. 5 is still another electric circuit diagram of the single-phase induction motor of the present invention.

【図6】本発明の単相誘導電動機の更にまたもう一つの
電気回路図である。
FIG. 6 is yet another electric circuit diagram of the single-phase induction motor of the present invention.

【図7】本発明の単相誘導電動機の更にまたもう一つの
電気回路図である。
FIG. 7 is yet another electric circuit diagram of the single-phase induction motor of the present invention.

【図8】従来の単相誘導電動機の電気回路図である。FIG. 8 is an electric circuit diagram of a conventional single-phase induction motor.

【図9】従来の単相誘導電動機のもう一つの電気回路図
である。
FIG. 9 is another electric circuit diagram of a conventional single-phase induction motor.

【図10】従来の単相誘導電動機の更にもう一つの電気
回路図である。
FIG. 10 is still another electric circuit diagram of the conventional single-phase induction motor.

【図11】従来の単相誘導電動機の更にまたもう一つの
電気回路図である。
FIG. 11 is still another electric circuit diagram of the conventional single-phase induction motor.

【図12】従来の単相誘導電動機の更にまたもう一つの
電気回路図である。
FIG. 12 is still another electric circuit diagram of the conventional single-phase induction motor.

【符号の説明】[Explanation of symbols]

1 単相誘導電動機 A 補助巻線 CR 運転コンデンサ CT、VT センサー M 主巻線 RC リレーコントローラ SW1 運転リレースイッチ SW2 始動リレースイッチ 1 Single-phase induction motor A Auxiliary winding CR Operating capacitor CT, VT Sensor M Main winding RC Relay controller SW1 Operating relay switch SW2 Starting relay switch

Claims (3)

【特許請求の範囲】[Claims] 【請求項1】 主巻線と補助巻線と有する単相誘導電動
機において、 電源電圧を検出する電圧検出手段と、運転制御を司る制
御手段とを備え、この制御手段は、拘束状態における前
記電源電圧からの前記主巻線電流の遅れ角に関するデー
タを有しており、前記電圧検出手段の出力に基づき、前
記電源電圧の零若しくは零付近から前記遅れ角だけ遅れ
て前記電源を印可することを特徴とする単相誘導電動機
の制御装置。
1. A single-phase induction motor having a main winding and an auxiliary winding, comprising voltage detection means for detecting a power supply voltage and control means for controlling operation, the control means comprising the power supply in a restrained state. It has data on the delay angle of the main winding current from the voltage, and based on the output of the voltage detection means, applying the power source with a delay of the delay angle from or near zero of the power source voltage. The control device for the characteristic single-phase induction motor.
【請求項2】 主巻線と補助巻線と有する単相誘導電動
機において、 前記主巻線電流を検出する電流検出手段と、運転制御を
司る制御手段とを備え、この制御手段は、前記電流検出
手段の出力に基づき、前記主巻線電流の零若しくは零付
近において電源を断つことを特徴とする単相誘導電動機
の制御装置。
2. A single-phase induction motor having a main winding and an auxiliary winding, comprising current detection means for detecting the main winding current, and control means for controlling operation, the control means comprising: A control device for a single-phase induction motor, characterized in that the power supply is cut off at or near zero of the main winding current based on the output of the detection means.
【請求項3】 主巻線と補助巻線と有する単相誘導電動
機において、 電源電圧を検出する電圧検出手段と、前記主巻線電流を
検出する電流検出手段と、運転制御を司る制御手段とを
備え、この制御手段は、拘束状態における前記電源電圧
からの前記主巻線電流の遅れ角に関するデータを有して
おり、前記電圧検出手段の出力に基づき、前記電源電圧
の零若しくは零付近から前記遅れ角だけ遅れて前記電源
を印可すると共に、前記電流検出手段の出力に基づき、
前記主巻線電流の零若しくは零付近において電源を断つ
ことを特徴とする単相誘導電動機の制御装置。
3. In a single-phase induction motor having a main winding and an auxiliary winding, voltage detecting means for detecting a power supply voltage, current detecting means for detecting the main winding current, and control means for controlling operation. The control means has data relating to the delay angle of the main winding current from the power supply voltage in the restrained state, and based on the output of the voltage detection means, from zero or near zero of the power supply voltage. While applying the power source with a delay by the delay angle, based on the output of the current detection means,
A controller for a single-phase induction motor, characterized in that the power supply is cut off at or near zero of the main winding current.
JP7070569A 1995-03-03 1995-03-03 Controller for single phase induction motor Pending JPH08251984A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP7070569A JPH08251984A (en) 1995-03-03 1995-03-03 Controller for single phase induction motor

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP7070569A JPH08251984A (en) 1995-03-03 1995-03-03 Controller for single phase induction motor

Publications (1)

Publication Number Publication Date
JPH08251984A true JPH08251984A (en) 1996-09-27

Family

ID=13435320

Family Applications (1)

Application Number Title Priority Date Filing Date
JP7070569A Pending JPH08251984A (en) 1995-03-03 1995-03-03 Controller for single phase induction motor

Country Status (1)

Country Link
JP (1) JPH08251984A (en)

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP1659681A1 (en) * 2004-11-17 2006-05-24 Samsung Electronics Co., Ltd. Single-phase induction motor and method for reducing noise in the same
JP2007252049A (en) * 2006-03-14 2007-09-27 Toshiba Mitsubishi-Electric Industrial System Corp Single-phase induction motor employing magnetic energy regeneration current switch
CN107888123A (en) * 2017-12-26 2018-04-06 杭州恒业电机制造有限公司 A kind of monophase machine control circuit

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP1659681A1 (en) * 2004-11-17 2006-05-24 Samsung Electronics Co., Ltd. Single-phase induction motor and method for reducing noise in the same
JP2007252049A (en) * 2006-03-14 2007-09-27 Toshiba Mitsubishi-Electric Industrial System Corp Single-phase induction motor employing magnetic energy regeneration current switch
CN107888123A (en) * 2017-12-26 2018-04-06 杭州恒业电机制造有限公司 A kind of monophase machine control circuit

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