JP2896162B2 - Refrigeration cycle device - Google Patents

Description

The present invention relates to a refrigeration cycle apparatus having a high-voltage switch and an overcurrent protection device, and in particular, whether or not a high-pressure switch and an overcurrent protection device operate. The present invention relates to a refrigeration cycle device provided with a protection device operation detection circuit for detecting a refrigeration cycle.

(Prior Art) Conventionally, this type of refrigeration cycle apparatus has a high-pressure switch that shuts off the current to the compressor when a high-pressure side pressure such as the discharge pressure of the compressor rises to a predetermined pressure, and an overcurrent flows into the compressor. Occasionally, an overcurrent protection device (IOL) that shuts off the current is provided to protect the compressor.

The protection device of the high-voltage switch and the overcurrent protection device is an input port of a controller, such as a microcomputer, which controls the operation of the compressor, etc., after the contact point.
An AC interrupt circuit is connected, and by opening these contacts when these protective devices operate, the power to the AC interrupt circuit is cut off and the controller stops operating to stop the compressor operation. .

Therefore, such a conventional refrigeration cycle device does not independently include a circuit for detecting the operation of the protection device.

(Problems to be Solved by the Invention) However, in such a conventional refrigeration cycle device, for example, when the high-voltage switch is operated, the power supply to the controller itself constituted by the microcomputer is cut off and the operation thereof is stopped. There is a problem in that it is not possible to perform any kind of control.

That is, the refrigeration cycle device is an air conditioner,
When the high-pressure switch operates during the cooling operation, the cooling load is generally lighter than the heating load, so the failure often occurs, and the cooling operation is not automatically restored after the cooling operation is stopped. It is desirable.

On the other hand, when the high-pressure switch is operated during the heating operation of the air conditioner, the heating load is higher than the cooling load, so that the air conditioner is often overloaded. May be. However, as described above, in the conventional example, when the high-voltage switch is operated, the controller itself stops the operation due to the stop of energization, so that control such as automatically returning the heating operation again after the operation of the high-pressure switch cannot be performed.

Therefore, the present invention has been made in view of the above circumstances,
An object of the present invention is to provide a refrigeration cycle apparatus capable of appropriately controlling the operation of the protection device after the operation by detecting the operation of the protection device, thereby improving the operation efficiency and reliability. .

[Configuration of the invention]

(Means for Solving the Problems) The present invention is configured as follows to solve the above problems.

That is, the present invention turns ON / OFF the power supply to the compressor.
A magnet switch to be controlled, a high-voltage switch that cuts off current to the compressor when the high-pressure side pressure of the compressor exceeds a predetermined pressure, and an overcurrent protection that cuts off current when overcurrent flows into the compressor. And a normally closed contact of the high-voltage switch and the overcurrent protection device connected in series to an output side of an excitation coil of the magnet switch, and at least the high-voltage switch and the overcurrent protection device. One of them operates to detect the presence or absence of a current flowing through the output side of the excitation coil of the magnet switch that trips when its contact is opened, thereby determining whether at least one of the high-voltage switch and the overcurrent protection device is operating. A protection operation detection circuit for detecting the signal, and a signal from the protection operation detection circuit. When the air-conditioning operation is the cooling operation, if the return of the high-voltage switch is not detected within a predetermined time required for the judgment for preventing the abnormal stop due to the noise malfunction from the operation of the protection operation detection circuit, the cooling operation is automatically performed. Control is performed so that an abnormal display is performed without returning to normal operation.If the air conditioning operation is in heating operation, within a predetermined time sufficient for the high pressure side pressure to decrease to the operation return point of the high pressure switch from the operation of the protection operation detection circuit A controller for performing control to return the heating operation to self-service when the return of the high-voltage switch is detected.

(Operation) When at least one of the high-voltage switch and the overcurrent protection device operates, the contact is opened, the exciting coil of the magnet switch is demagnetized, and the magnet switch trips.

Then, the non-current state of the exciting coil is detected as an abnormal state by the protection operation detection circuit, and when the controller that receives a signal from the protection operation detection circuit determines that the air conditioning operation is the cooling operation, a predetermined period of time is determined. If the return of the high-pressure switch is not detected within this time, an abnormality is displayed without automatically returning the cooling tillage, and if it is determined that the air-conditioning tillage is the heating operation, the high-pressure side pressure is reduced from the operation of the protection operation detection circuit. When the return of the high-pressure switch is detected within a predetermined time sufficient to lower the operation return point of the high-pressure switch, control for automatically returning the heating operation is performed. Therefore, according to the present invention, the presence or absence of the operation of the protection operation detection circuit can be detected by the protection device operation detection circuit, and the controller receiving the signal from the protection operation detection circuit can control the high-voltage switch and the overcurrent protection device. Control of the refrigeration cycle device after the operation can be appropriately performed according to the cooling and heating operations, and both improvement in the operation efficiency and reliability of the refrigeration cycle device can be achieved.

Embodiment An embodiment of the present invention will be described below with reference to FIGS. 1 and 2.

FIG. 1 is a wiring diagram showing an overall configuration of an embodiment of the present invention. In the drawing, a three-phase power supply 1 includes a magnet switch 2 for three phases (R, S, T), a converter 3a, and an inverter 3b.
And the compressor 4 are connected in series in this order.

The magnet switch 2 is connected to a three-phase power source 1 and the magnet switch 2 on the input side of the exciting coil 2a.
A required one of the lines R, S, and T, for example, a T phase is connected via a contact 6 of a relay for a magnet switch, and a protection operation detection circuit 5 is provided.

The protection operation detection circuit 5 has the normally closed contacts of the high voltage switch 7 and the overcurrent protection device 8 interposed in this order on the output side of the exciting coil 2a in this order, and then the three-phase three-wire R
Connected to the phase.

A midpoint A between the output side of the exciting coil 2a and the normally closed contact of the high voltage switch 7 has a resistor having a resistance sufficiently larger than the impedance Z of the magnet switch 2.
Through R ₁ is connected to one end B of the photo triac 10 of the photocoupler 9.

The other end C of the phototriac 10 is connected to, for example, the R-phase of the three-phase three-wire.

On the other hand, it is connected to the output terminal D of the phototransistor 11 of the photocoupler 9 through the resistor R ₂ together to connect the battery 12 of 5V, via a resistor R ₃ to the input E of the controller 13. The middle of the wiring connecting the input terminal E of the controller 13 and the resistor R ₃ is grounded via a capacitor C _1.

The controller 13 has a means for supplying an operation frequency command signal to the inverter 3b and controlling the rotation speed of the compressor 4.

Further, the controller 13 has control means for opening and closing the contact 6 of the relay for the magnet switch.

 Next, the operation of the present embodiment will be described.

First, when a control signal is given from the controller 13 to the relay for the magnet switch, the contact 6 is closed, and the exciting coil 2a of the magnet switch 2 is energized via the closed contact, so that the contact of the magnet switch 2 is closed.

For this purpose, the power supply voltage of the three-phase power supply 1 is changed via the closed contact of the magnet switch 2 to the converter 3a and the inverter.
3b, which are applied to the compressor 4, respectively, to drive the compressor 4 at a required rotational speed, thereby operating a refrigeration cycle device, for example, an air conditioner.

When both the high-voltage switch 7 and the overcurrent protection device 8 are inoperative during this air-conditioning operation, the current flowing through the exciting coil 2a of the magnet switch 2 is applied to the normally closed contacts of the high-voltage switch 7 and the overcurrent protection device 8. Through to the R phase.

At this time, in the protection operation detection circuit 5, the point A on the output side of the exciting coil 2a and the phototriac 10
At the one end point B is the same as the R-phase potential.

Therefore, the phototriac 10 of the photocoupler 9 is turned off without being energized, and does not emit light.

Therefore, the phototransistor 11 is also turned off, and the potential of the output terminal D is 5 V of the battery 12, and this 5 V is further connected to the capacitor C ₁ via the resistors R ₂ and R _3.
Is charged.

Therefore, the controller 13 receives the potential 5 V at the input terminal E, and determines that both the high-voltage switch 7 and the overcurrent protection device 8 are inoperative, that is, normal.

On the other hand, when at least one of the high-voltage switch 7 and the overcurrent protection device 8, for example, the high-voltage switch 7 operates, the normally closed contact is opened to open the magnet switch 2.
The energization of the excitation coil 2a is interrupted.
Is demagnetized, the contact of the magnet switch 2 is opened, the power supply to the converter 3a from the three-phase power supply 1 is cut off, and the power supply to the inverter 3b and the compressor 4 is cut off to stop the drive. As a result, the air conditioning operation also stops.

On the other hand, in the protection operation detecting circuit 5, since the normally closed contact of the high-voltage switch 7 is opened, the potential at the point C at one end of the phototriac 10 becomes lower than the potential at the other point B. Since a sine wave voltage B is applied as shown in FIG. 2, one of the phototriacs 10 is turned on (O
N) to emit light.

This light is received by the phototransistor 11, and the phototransistor 11 is turned on, so the capacitor
5V battery 12 charged in the C ₁ is grounded via the phototransistor 11 during conduction.

Therefore, while 5 V is applied to the point D of the phototransistor 11 as shown in FIG. 2, the potential at the input terminal E of the controller 13 becomes almost OV.

The controller 13 receives the potential OV at the input terminal E, determines that the high-voltage switch 7 has operated, and performs air-conditioning operation control thereafter.

That is, if the return of the high-pressure switch 7 is not detected within 10 seconds from the operation of the high-pressure switch 7 during the air-conditioning operation during the cooling, the cooling operation is stopped and then automatically returned to an abnormal state without stopping.

That is, since the cooling load is lighter than the heating load, the cause of the operation of the high-voltage switch 7 during the cooling operation is often a failure rather than an overload. It is. It should be noted that 10 seconds of the abnormality determination is provided as a time required for determination for preventing abnormal stop due to a noise malfunction.

On the other hand, when the high-pressure switch 7 operates during the heating operation, the heating load is higher than the cooling load, and the cause is often an overload. If the high-pressure switch 7 returns within this time, control is performed to automatically return again after the required time has elapsed after the heating operation is stopped. This 30 seconds is a time sufficient for the high pressure side pressure to drop to the operation return point of the high pressure switch 7 when the compressor 4 is stopped with common sense.

Therefore, according to the present embodiment, the operation of the high-voltage switch 7 and the overcurrent protection device 8 can be detected, and the control after the operation of these protection devices can be appropriately performed. Improvement and reliability can be achieved.

Further, since the normal operation of the protective device does not work no current flows through the resistor R _1, it is possible to suppress heat generation in the resistance R _1.

In the above embodiment, the three-phase compressor 4 has been described, but the present invention is not limited to this.
It can also be applied to single-phase compressors.

〔The invention's effect〕

As described above, according to the present invention, the presence or absence of the operation of the high-voltage switch and the overcurrent protection device can be detected by the protection operation detection circuit, and the controller receiving the signal from the protection operation detection circuit can control the high-voltage switch and the overcurrent protection device. The control of the refrigeration cycle device after the operation of the current protection device can be appropriately performed in accordance with the cooling and heating operations, so that the operation efficiency can be improved and the reliability of the entire device can be improved.

[Brief description of the drawings]

FIG. 1 is a main part wiring diagram of one embodiment of a refrigeration cycle apparatus according to the present invention, and FIG. 2 is a waveform diagram showing voltage waveforms at points B, D, and E shown in FIG. 2: magnet switch, 2a: excitation coil, 5: protection operation detection circuit, 7: high-voltage switch, 8: overcurrent protection device,
9 ... photocoupler, 10 ... phototriac, 11 ... phototransistor.

Claims (1)

(57) [Claims] A magnet switch for controlling ON / OFF of power supply to the compressor; a high-voltage switch for cutting off power supply to the compressor when a high-pressure side pressure of the compressor exceeds a predetermined pressure; And an overcurrent protection device that cuts off the current when it flows in. A normally closed contact of the high-voltage switch and the overcurrent protection device is connected in series to an output side of an excitation coil of the magnet switch. At least one of the high-voltage switch and the overcurrent protection device operates to detect the presence or absence of a current flowing through the output side of the excitation coil of the magnet switch that trips when its contact is opened, thereby detecting the high-voltage switch. Operation detection circuit for detecting the presence or absence of operation of at least one of the overcurrent protection device and the overcurrent protection device When the signal from the protection operation detection circuit is received and the air-conditioning operation is the cooling operation, the high-voltage switch is turned on within a predetermined time required for determining from the operation of the protection operation detection circuit to prevent abnormal stop due to noise malfunction. If return is not detected, control is performed to display an abnormality without automatically returning cooling tillage,
If the air-conditioning cultivation is in the heating operation, if the return of the high-pressure switch is detected within a predetermined time sufficient to reduce the high-pressure side pressure from the operation of the protection operation detection circuit to the operation return point of the high-pressure switch, the heating operation is performed. A refrigeration cycle apparatus comprising: a controller that performs control for automatically returning the refrigeration cycle.