KR0126458B1 - Control apparatus for a compressor - Google Patents

Abstract

A compressor controller includes a high pressure switch for detecting the pressure outputted from a compressor when the compressor is driven in a cooling cycle and a thermistor for detecting the condensed refrigerant pressure and the overload state of a condensing unit. When the high pressure switch is returned, the speed of the compressor is converted from the slow speed to the high speed to a normal operation. When the temperature detected by the thermistor increases during the high speed operation, it is determined to be the overload state and the circuit is entirely cut off. Also, when the temperature of the condensed refrigerant at the outlet of the condensing unit which is detected by the thermistor is in the over-cooled state, an outdoor fan is rotated at a slow speed so that the temperature of the refrigerant is increased, thereby preventing an over-cooling.

Description

Compressor controller

1 is a circuit diagram of a conventional compressor control device.

2 is a block diagram of a compressor control device applied to the present invention.

3 is a detailed circuit diagram of a compressor control device applied to the present invention.

* Description of the symbols for the main parts of the drawings *

COMP: Compressor, HS: High Pressure Switch,

TH: Thermistor, MIC: Control,

RY1: Compressor speed selection relay, RY2: Overload relay,

RY3: Outdoor fan control relay, SW1, SW2: Compressor speed selector switch,

FAN: Fan, MG2, MG4: Magnet,

R2, S2, C2, R4, S4, C4: Magnet terminal.

The present invention relates to a compressor control device, and in particular, to detect the discharge pressure of the compressor, the condenser temperature of the condenser in the refrigeration cycle, and to control the operating speed of the compressor and the speed of the condenser fan according to the detected discharge pressure and the condensation temperature The present invention relates to a compressor control device capable of improving and protecting a compressor.

In the conventional compressor control apparatus, as shown in FIG. 1, when an abnormality occurs in the high pressure switch HS for detecting the discharge pressure of the compressor COMP, the magnet MG for controlling the driving of the compressor COMP is provided. The magnet switch (MS) that is off and interlocked with it is turned off to stop the operation of the compressor (COMP).

At this time, the compressor (COMP) does not restart until the user turns on the high pressure switch (HS), there is a problem that reduces the efficiency of the compressor due to the start stop and restart.

It is an object of the present invention to operate a compressor operating at high speed by driving a relay when a high pressure switch for detecting a discharge pressure of the compressor is generated at the start of the compressor, and when the high pressure switch returns to normal, the original speed Another object of the present invention is to detect the condensation temperature of the refrigerant discharged from the condenser and to reach a predetermined temperature or more, by operating a relay to turn off the refrigerant circuit from the overload state. It is to protect the refrigerant circuit.

In order to realize the above object, the present invention provides a high-pressure switch for detecting the discharge pressure of the compressor, a thermistor for detecting the discharge refrigerant temperature of the condenser, and outputs a controlled signal by comparing and controlling the compressor, outdoor fan, and overload with a reference value. A controller for controlling the compressor, a compressor speed selection relay for selecting a compressor at a high speed and a low speed while the on / off operation is performed according to the operation of the high pressure switch, an overload relay for detecting an overload state of the thermistor and performing an on-off operation, and detecting the thermistor. An outdoor fan control relay for driving the outdoor fan with high and low temperatures according to the set temperature, a compressor speed selection switch for selecting a rotation speed of the compressor, and a speed selection of the compressor speed selection relay. Drive terminal of the compressor is turned on and off by switching magnet Depending on the terminal and the magnet, the operation of the outdoor fan control relay for selecting characterized by the adapted and the outdoor fan relay terminal selection control for selecting a speed of the outdoor fan, the on-off operation by the overload relay to the overload relay terminals.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of a compressor control applied to the present invention, and FIG. 3 is a detailed circuit diagram of the compressor control device applied to the present invention. The high pressure switch HS which detects the discharge pressure of the compressor COMP and the discharge of the condenser are shown in FIG. Thermistor TH for detecting the refrigerant temperature, the discharge pressure detected by the high pressure switch HS, the reference pressure, the refrigerant temperature and the overload temperature of the thermistor (TH) to detect the voltage and reference voltage The control unit MIC for comparing and outputting a signal corresponding to the compared signal, the compressor speed selection relay RY1 for selecting at high speed and low speed according to the signal compared and output from the control unit MIC, and the control unit ( The overload relay RY2 performs on / off operation by the signal output from the MIC and the outdoor fan FAN is weakly controlled by the signal output from the controller MIC. The electric charge is a speed switching relay connected and switched by the operation of the outdoor fan control relay RY3, the compressor speed selection switches SW1 and SW2 for selecting the rotational speed of the compressor COMP, and the compressor speed selection relay RY1. Terminal RY1-S, magnets MG2 and MG4 for switching the speed of the compressor by the speed selection of the compressor speed selection relay RY1, and interlocking alternately by the operations of the magnets MG2 and MG4. The magnet terminal to change the speed of the compressor by selecting the drive terminal of the compressor (COMP) while the on-off operation by the switching operation selectively to the contact terminals (P1) (P2) and the magnets (MG2, MG4) The outdoor fan FAN is selected to be strong or weak in accordance with the operation of the start start terminals R2 and R4, the start terminals S2 and S4, the common terminals C2 and C4, and the outdoor fan control relay RY3. Controlled outdoor fan selection relay terminal RY3-S, and Hayeoseo the OFF operation by the load relay (RY2) is a circuit configuration hayeoseo overload relay terminal (RY2-S) is blocked the whole power.

Referring to the effects of the present invention configured as described above are as follows.

First, when power is supplied to the compressor control circuit, the high pressure switch HS detects the discharge pressure from the compressor COMP, and the thermistor TH also detects the refrigerant temperature of the condenser and an overload condition. When the discharge pressure detected from the HS is not high pressure compared to a predetermined reference voltage by the controller MIC, a signal is output to the compressor speed selection relay RY1 to drive the compressor speed selection relay RY1. At the same time, the compressor speed selection switch SW2 is driven on.

Therefore, since the speed switching relay terminals RY1-S interlocked with the compressor speed selection relay RY1 are turned on from the off state, the magnet MG2 is driven, and the magnet MG2 is driven. Since the common terminal C2 of the start terminal R2 of the starting terminal R2 of the compressor COMP is connected, as shown by a dotted line in FIG. 3, the compressor COMP operates as a two-pole starting voltage. Drive at high speed.

At this time, the magnet MG4 is not driven because the contact terminal P4 of the magnet MG2 is turned off by the operation of the magnet MG2.

On the other hand, the compressor COMP operates at a high speed as described above, and the discharge pressure of the compressor COMP becomes a high pressure state, and when the high pressure switch HS is operated, the compressor speed selection linked with the high pressure switch HS is selected. The switch SW2 is turned off, while the compressor speed selector switch SW1 is turned on.

Therefore, the control unit MIC stops the driving of the compressor speed selection relay RY1, so that the driving of the magnet MG2 is stopped to start the terminal R2, the start terminal S2 of the compressor COMP, and the common terminal. While the terminal C2 is turned off, the magnet MG4 is driven to drive the start terminal R4, the start terminal S4, and the common terminal C4 of the compressor COMP linked thereto. As shown by the solid line in FIG. 3, the compressor COMP is operated at a four-pole starting voltage, so the compressor COMP is driven at a low speed.

When the compressor COMP is driven at a low speed and the high pressure switch HS returns, that is, when the discharge pressure of the compressor COMP is low, the compressor speed selection switch SW1 interlocked with the high pressure switch HS is applied. ) Is turned off, while the compressor speed selector switch SW2 is turned on, and the speed change relay terminals RY1 to S associated with the compressor speed selector relay RY1 are turned on from the off state. Thus, the driving magnet MG4 stops the operation.

On the contrary, the magnet MG2 is driven so that the starting terminal R2, the starting terminal S2, and the common terminal C2 of the compressor COMP interlocked with the driving of the magnet MG2 are operated at high speed, which is normal operation. To drive.

At this time, the thermistor (TH) detects the refrigerant temperature and the overload condition. When the temperature detected by the thermistor (TH) rises and becomes an overload state, the overload relay (RY2) operates on the printed circuit board (PCB) to overload the relay. The terminals RY2-S are turned off to stop the driving of the entire control circuit.

When the compressor COMP is in a supercooled state at the outlet side of the condenser due to the high pressure driving, the control unit MIC drives the outdoor fan control relay RY3, so that the outdoor fan selection relay terminal RY3- is driven in conjunction with the compressor. By switching S) from the high speed state to the low speed state, the outdoor fan FAN is driven at a low speed to increase the condenser refrigerant temperature in the supercooled state.

As described above, the present invention is equipped with a high pressure switch for detecting the discharge pressure of the compressor when the compressor is driven in the refrigeration cycle, and equipped with a thermistor for detecting the condensation refrigerant pressure and overload of the condenser, when the high pressure switch is operated, To operate the high speed switch at high speed and low speed, and when the operation of the high pressure switch is returned, the operation speed of the compressor is normally operated from low speed to high speed, and when the temperature detected by the thermistor increases during the high speed operation, It is judged that the entire circuit is shut off and stopped, and when the outlet condensation refrigerant temperature detected by the thermistor becomes a supercooled state, the outdoor fan is rotated at a low speed to prevent the supercooled state. To increase the efficiency and protect the compressor. Will.

Claims (1)

High pressure switch (HS) for detecting the discharge pressure of the compressor, thermistor (TH) for detecting the discharge refrigerant temperature of the condenser, and control unit (MIC) for controlling the compressor, outdoor fan, overload compared to the reference value to output a controlled signal And a compressor speed selection switch (SW1) (SW2) for selecting a compressor at a high speed and a low speed while the on-off operation is performed according to the operation of the high pressure switch (HS), and an overload which detects an overload state of the thermistor and performs on-off operation. A relay RY2, an outdoor fan control relay RY3 for strongly driving the outdoor fan while being turned on and off according to the temperature sensed by the thermistor, and a compressor speed selection relay RY1 for selecting the rotational speed of the compressor. And the magnets MG2 and MG4 for switching the speed of the compressor by the speed selection of the compressor speed selection relay and the magnets MG2 and MG4 being turned on and off. Magnet terminals R2, S2, C2 (R4, S4, C4) for selecting the drive terminals of the accumulator, and an outdoor fan selection relay terminal for selectively controlling the outdoor fan speed according to the operation of the outdoor fan control relay RY3 ( And an overload relay terminal (RY2-S) operating on and off by the overload relay (RY2).