KR20210064669A - a method of controller for screw compressor - Google Patents

Abstract

The present invention relates to a control method of a screw compressor control device using an inverter and a pressure switch. More particularly, the present invention relates to a screw compressor optimum operation control device and a monitoring method thereof that not only improves energy efficiency by inputting the values obtained from a pressure switch and flow meter sensor normally installed in a screw compressor into an inverter to control the power supply to a motor, preventing unnecessary power loss, but also reduces power consumption by controlling the operation to prevent damage to the electric circuit and motor from the stress of a starting current caused by the frequent starting of the screw compressor, but, under certain conditions when switching from load operation to no-load operation, automatically controlling on/off and monitoring real-time status, flow, and electric power.

Description

Control method of a screw compressor control device {a method of controller for screw compressor}

The present invention relates to a screw compressor control device, and more particularly, to a control method for a screw compressor control device using an on/off state of an inverter, a pressure switch, an air flow sensor, and load devices.

In general, when compressing air, the piston type is mainly applied at low capacity, and the screw type is mainly used at large capacity. In the case of the large capacity screw type, a large starting current (approximately less than the full load current) at the first start of the screw compressor. 3-4 times) is required.

Therefore, the general starting method of a general screw compressor uses the Y-Δ starting method, which is a general starting method of a large-capacity motor. That is, the screw compressor opens the suction valve during the driving period to generate compressed air, and the motor operates at full load to supply compressed air into the receive tank. When the pressure in the tank exceeds the upper limit, the suction valve is closed by an electric signal. (UN-driven) Stops the production of compressed air.

However, the motor continuously operates.

The reason is that if the compressor is turned on/off frequently, it may cause a problem due to motor damage or MC (NAGNECTIC CONTACTOR) failure.

On the other hand, when the pressure in the tank becomes lower than the lower limit set value due to the use of compressed air, the suction valve is opened again to generate compressed air. This operation is repeated every few minutes and the suction valve is closed without stopping the motor during non-operation. Since the generation of compressed air is controlled by closing, the motor is operated without load, consuming about 50~70% of power during operation.

Such no-load operation makes it possible to prevent damage to the electric circuit and the motor from the stress of the starting current due to restarting from a stop state.

In addition, recently, PID (proportional, integral, differential) control method is widely used to control screw compressors. The PID controller calculates the amount of compressed air used and controls the motor at the number of revolutions that can generate compressed air equivalent to the current amount. If you give a command to the inverter, which is the motor driver, to do this, the inverter controls the motor according to the command given by the controller. This PID control method maintains the compressed air pressure constant, thereby reducing the no-load loss of the motor and saving power. there is

In addition, in the conventional general screw compressor control method, the motor of the compressor is continuously driven as long as the operation is performed, so that power loss occurs even when there is no load. Even if it is not done, power consumption occurs due to various losses, and there is a problem in that unnecessary energy consumption occurs.

In order to solve such a problem, the present applicant has proposed an improved screw compressor control device through Registration Office No. 20-0374633 as shown in FIG. 1 .

Looking at the prior art shown in the accompanying FIG. 1, the compressed air produced by the motor 40 is stored in the receive tank 60 through the oil separator 50, and the produced compressed air is transferred to the receive tank 60. Compressed air air supply line 20 to a known screw compressor control device that measures the pressure of compressed air in the supplied air supply line 20 and controls the load operation and no-load operation of the motor 40 according to the reference pressure value. A pressure switch 11 having various setting values is installed in the motor 40, and an inverter 30 having a slow start function is installed to control the power supply to the motor 40, and the pressure switch 11 of the upper limit value among the pressure switches is installed. The measurement signal is transmitted to the inverter 30 to cut off the power supply of the motor 40 , and the measurement signal of the pressure switch 11 of the lower limit of the pressure switches is transmitted to the inverter 30 to supply power to the motor 40 . It is configured so that it can be resumed.

The screw compressor control device previously applied by the present applicant in this way supplies the compressed air produced by the motor 40 and the compressor to the receiving tank 60 through the air supply line 20 .

At this time, an oil separator 50 is installed in the air supply line 20 to remove oil in the compressed air, and a pressure switch 11 is installed on one side thereof to measure the pressure of the compressed air.

The pressure switch 11 measures the pressure of the compressed air supplied through the air supply line 20. In order to enable measurement of various measurement values, the pressure switch 11 is set according to the measurement value desired by the user. It will be installed, it would be most preferable to install at least two or more, and the pressure switch 11 puts out in advance that any of the inexpensive mechanical or electronic type may be used.

Therefore, when the pressure switch 11 with a specific set value measures the pressure change of the compressed air in the air supply line 20 as described above, the signal is transmitted to the inverter 30 that controls the power supply of the motor 40. is transmitted

Therefore, when a specific signal is input to the inverter 30 , the inverter 30 supplies or cuts the power supplied to the motor 40 to control the operation of the motor 40 . same as

That is, after installing the pressure switch 11 corresponding to approximately the lower limit set value and the upper limit set value in the compressed air air supply line 20, the measurement signal of each pressure switch 11 is applied to the ON and OFF control signals of the inverter 30, respectively. When converted to and applied to, compressed air is produced by the screw compressor, and the pressure of compressed air measured in the air supply line 20 is measured at the pressure switch 11 of the upper limit set value, and the signal is turned OFF to the inverter 30. is input, the inverter 30 stops the operation of the motor 40 by blocking the power supplied to the motor 40 of the screw compressor that produces compressed air, thereby stopping the production of compressed air.

Therefore, by blocking unnecessary operation of the motor 40 after sufficient compressed air pressure is generated, not only power loss due to no-load operation is prevented, but also damage or mechanical damage caused by heat generated during the operation of the motor 40 It is possible to prevent various losses, such as losses due to friction, even when actual load operation is not performed.

As described above, although the screw compressor control device previously applied by the present applicant has the above-described advantages, it has a problem in that it does not satisfy the needs of consumers who require more precise control.

The present invention has been devised to solve the above problems, and an object of the present invention is to input the value obtained from the pressure switch installed in the screw compressor to the inverter while maintaining the advantages of the screw compressor control device previously applied as the present application. By controlling the power supply of the motor, it not only improves energy efficiency by preventing unnecessary power loss, but also controls the operation to prevent damage to the electric circuit and the motor from the stress of the starting current caused by the frequent start of the screw compressor. An object of the present invention is to provide a screw compressor control method that reduces power consumption by controlling the forced on/off control method under certain conditions when switching from the to no-load operation.

In the control method of the screw compressor control apparatus according to the present invention for achieving the above object, compressed air produced by a motor is stored in a receive tank through an oil separator, and the produced compressed air is supplied to the receive tank. A pressure switch is installed in the line, the power supply is controlled to the motor, and an inverter with a slow start function is installed, but the upper limit setting value measurement signal of the pressure switch is transmitted to the inverter to cut off the power supply to the motor, and the pressure switch It consists of a screw compressor control device that controls the load operation and no-load operation by transmitting the lower limit set value measurement signal of the inverter to resume the power supply of the motor; An air flow sensor is further installed at the output end of the receive tank, and a control unit for calculating the amount of air currently present in the receive tank by combining the pressure switch and the air flow sensor is further installed, wherein the control unit includes the pressure switch and the air flow rate It is characterized in that the operation of the motor is determined based on the calculation of the amount of air according to the combination of sensors.

A preferred feature of the present invention is to further include an automatic alarm signal output unit for outputting an alarm signal according to a control signal of a control unit when an error condition of the pressure switch and the air flow sensor occurs; The automatic alarm signal output unit includes: a power supply unit for applying power by its own power supply; a first relay switch installed on one side of the output terminal of the power unit to switch power output from the power unit; a second relay switch installed on the other side of the output terminal of the power supply unit to switch the power supply unit output from the power supply unit; a third relay switch coupled to the output terminal of the second relay switch and generating a magnetic force when the second relay switch is switched; a first circuit connection switch performing a function of energizing the circuit while the iron piece is pulled by the third relay switch; a power switch for outputting a second alarm signal that serves to induce an alarm signal to be displayed through the alarm signal display unit by supplying power to the alarm signal output control unit while the iron piece is pulled by the third relay switch; The second relay switch is switched to induce the third relay switch to be switched, and accordingly, the first circuit connection switch and the power switch for outputting the second alarm signal are switched, and thereafter, the second relay switch is turned off and the first By switching the relay switch, the third relay switch is turned off, and at the same time, the switching state of the first circuit connection switch configured to be interlocked with the first relay switch and the power switch for outputting the second alarm signal is maintained to maintain the alarm state. a control unit; an iron piece for circuit operation that is in contact with the first circuit connection switch and relays the power transmitted from the first relay switch to continue the flow of power; an iron piece for connecting power to an alarm signal output control unit designed to operate in conjunction with the iron piece for circuit operation and for guiding the alarm device to operate by connecting power to the alarm signal output control unit when the iron piece for circuit operation is turned on; It is installed at the bottom of the iron plate for circuit operation and is made in the form of a bar magnet with an S pole at the lower end, so that the first circuit connection switch and the iron piece for circuit operation are always kept off when the third relay switch is not operated due to the influence of the S pole. a first self-maintaining means; Installed on the top of the first circuit connection switch, the upper end is made in the form of a bar magnet having an S pole, and when the third relay switch is not operated, the first self-maintaining means having an S pole at the lower end is pushed up to push up the iron piece for circuit operation It maintains an electrically off state as a pole, and when the third relay switch is operated, the iron piece for circuit operation is pulled so that the S pole constituting the upper part of the body and the N pole constituting the upper part of the body of the first self-maintaining means are located close At the same time, the N pole constituting the lower part of the body and the S pole constituting the lower part of the body of the first self-maintaining means are positioned close to each other and magnetically coupled to the first self-maintaining means and at the same time the first circuit connection switch is switched. 3 Even if the operation of the relay switch is stopped, the attachment state of the iron piece for circuit operation continues to maintain the power supply state through the first relay switch. At this time, when the iron piece for circuit operation is operated by the operation of the third relay switch, an alarm signal is output a second self-maintaining means operable to automatically operate an iron piece for power connection of the control unit to output an alarm signal to the outside; The third relay switch is installed at the lower end of the iron plate for circuit operation in a state of being spaced apart from the first self-maintaining means and is made in the form of a bar magnet having an S pole at the lower end and pushed by the second self-maintaining means having an upper end at the S pole. During operation, the iron piece for circuit operation is lifted from the first circuit connection switch to maintain the cut-off state of the circuit, and when the third relay switch is operated, the iron piece for circuit operation is lowered to maintain the ON state of the first circuit connection switch. means and; It is installed around the periphery of the N pole of the second self-maintaining means and induces the second self-maintaining means and the first self-maintaining means to be coupled while maintaining a certain gap without being directly coupled to each other when magnetically coupled, a spacer for guiding the first self-maintaining means and the second self-maintaining means to be naturally separated from each other when dismantling; It is coupled to the iron piece for circuit operation and the iron piece for power connection of the alarm signal output control unit, and when the user operates to stop the operation of the alarm signal, the iron piece for circuit operation and the iron piece for power connection of the alarm signal output control unit are turned off to operate the alarm signal display unit It consists of further including a manual operation switch that induces the alarm signal not to be output any more by stopping it.

In the control method of the screw compressor control device of the present invention according to the above configuration, the value obtained from the pressure switch installed in the screw compressor is usually input to the inverter to control the power supply to the motor, thereby preventing unnecessary power loss and improving energy efficiency. operation is controlled to prevent damage to electric circuits and motors from the stress of the starting current caused by frequent starting of the screw compressor, but the forced on/off control method under certain conditions when switching from load operation to no-load operation It has the effect of reducing power consumption by controlling the

1 is a block diagram of a screw compressor control device registered by the applicant of the present invention as an earlier application.
2 to 6 are block diagrams showing a control method of the screw compressor control apparatus according to the present invention.

Hereinafter, the control method of the screw compressor control apparatus according to the present invention will be described in detail with reference to the drawings.

1 is a configuration diagram of a screw compressor control device registered by the applicant of the present invention as an earlier application, and FIGS. 2 to 6 are configuration diagrams showing a control method of a screw compressor control device according to the present invention.

As shown, in the control method of the screw compressor control apparatus according to the present invention, the compressed air produced by the motor 40 is stored in the receiving tank 60 through the oil separator 50, and the produced compressed air is A pressure switch 11 having various set values is installed in the air supply line 20 supplied to the receive tank 60, the power supply is controlled to the motor 40, and an inverter 30 having a slow start function is installed. However, the measurement signal of the pressure switch 11 of the upper limit of the pressure switches is transmitted to the inverter 30 to cut off the power supply to the motor 40, and the measurement signal of the pressure switch 11 of the lower limit of the pressure switches is transmitted to the inverter 30. The basic configuration is a screw compressor control device that transmits to the inverter 30 to resume power supply of the motor 40 to control the load operation and the no-load operation.

In addition, an air flow sensor is installed at the output end of the receive tank to check the air flow rate present in the receive tank, and the amount of air present in the receive tank is calculated according to the air flow rate to determine the on/off time of the motor.

That is, the present invention calculates the amount of air currently present in the receive tank by combining the pressure switch and the air flow sensor, and determines the operation of the motor based on the calculation of the amount of air according to the combination of the pressure switch and the air flow sensor. You can decide to drive the motor.

In addition, in the present invention, the air consumption is calculated using time-series pattern analysis and the air consumption time is predicted to make a final decision to turn on/off the operation of the compressor by measuring every time unit, unit unit, and monthly unit. By doing so, it is possible to minimize the amount of electricity consumed by the operation of the compressor.

That is, by calculating the air consumption according to the use of the compressor and calculating the air pressure to predict the time of air exhaustion, the compressor is operated at the necessary time to prevent the loss of the body due to frequent on/off operation of the compressor and to minimize the consumption of electricity. because you can

On the other hand, when an error condition of the pressure switch and the air flow sensor occurs, an error condition is alerted through the automatic alarm signal output unit 1000 to induce resolution within a short time, and the automatic alarm signal output unit 1000 is a power supply unit 1110, a first relay switch RY1, a second relay switch RY2, a third relay switch RY3, a first circuit connection switch sw1, and a second circuit connection switch sw2 and an alarm control unit 1120 .

The power supply unit 1110 applies power by its own power supply.

The first relay switch RY1 is installed on one side of the output terminal of the power unit to switch the power output from the power unit.

The second relay switch RY2 is installed on the other side of the output terminal of the power unit to switch the power unit output from the power unit.

The third relay switch RY3 is coupled to the output terminal of the second relay switch and generates a magnetic force when the second relay switch is switched.

The first circuit connection switch sw1 performs a function of energizing the circuit while the iron piece is pulled by the third relay switch.

The power switch sw2 for outputting the second alarm signal is powered by the alarm signal output control unit 1140 while the iron piece is pulled by the third relay switch to induce the alarm signal to be displayed through the alarm signal display unit 1150. plays a role

The alarm control unit 1120 switches the second relay switch to induce the third relay switch to be switched, so that the first circuit connection switch and the power switch for outputting the second alarm signal are switched accordingly, and then the second relay switch By turning off and simultaneously switching the first relay switch, the third relay switch is turned off, and the switching state of the first circuit connection switch configured to be interlocked with the first relay switch and the power switch for outputting the second alarm signal is maintained to maintain the alarm state. serves to sustain.

In addition, the present invention provides an iron piece 1131 for circuit operation, an iron piece 1132 for power connection of the alarm signal operation control unit, a first self-maintaining means 1133, a second self-maintaining means 1134, and an auxiliary self-maintenance The means 1133a, the clearance agent 1134a, and the manual operation switch 1135 are further included.

The iron piece 1131 for circuit operation is in contact with the first circuit connection switch sw1 to relay the power transmitted from the first relay switch to continue the flow of power.

The iron piece 1132 for power connection of the alarm signal output control unit is designed to operate in conjunction with the iron piece 1131 for circuit operation, and when the iron piece 1131 for circuit operation is turned on, power is connected to the alarm signal output control unit 1140 and induce the alarm system to operate.

The first self-maintaining means 1133 is installed at the lower end of the iron plate 1131 for circuit operation and is formed in the form of a bar magnet having an S pole at the lower end, so that when the third relay switch does not operate due to the influence of the S pole, the first circuit connection switch ( sw1) and the iron piece 1131 for circuit operation are always in an off state.

The second self-maintaining means 1134 is installed on the upper portion of the first circuit connection switch sw1, but is formed in the form of a bar magnet having an S pole at the upper end, and the first self-maintaining means having an S pole at the lower end when the third relay switch is not operated. By pushing the means 1133 to each other, the iron piece 1131 for circuit operation is pushed up to maintain an electrically off state, and when the third relay switch is operated, the iron piece 1131 for circuit operation is pulled and the S constituting the upper part of the body The pole and the N pole constituting the upper part of the body of the first self-maintaining means 1133 are located close to each other, and at the same time the N pole constituting the lower part of the body and the S constituting the lower part of the body of the first self-maintaining means 1133 When the poles are positioned close to each other and magnetically coupled to the first self-maintaining means 1133 and at the same time the first circuit connection switch sw1 is switched, even if the operation of the third relay switch stops, the attachment of the iron piece 1131 for circuit operation The state continues to maintain the power supply state through the first relay switch. At this time, when the iron piece for circuit operation is operated by the operation of the third relay switch, the iron piece for connecting the power supply of the alarm signal output control unit is automatically operated to output the alarm signal to the outside.

The auxiliary self-maintaining means 1133a is installed at the lower end of the iron plate 1131 for circuit operation in a state spaced apart from the first self-maintaining means 1133 at a predetermined interval, and is formed in the form of a bar magnet having an S pole at the lower end, so that the upper end is S While being pushed by the second self-maintaining means, which is the pole, the iron piece 1131 for circuit operation is lifted from the first circuit connection switch sw1 when the third relay switch is not in operation to maintain the cut-off state of the circuit, and the circuit when the third relay switch is operated The iron piece 1131 for operation is lowered to maintain the ON state of the first circuit connection switch sw1.

In particular, the auxiliary self-maintaining means 1133a affects the second self-maintaining means 1134 even if the first self-maintaining means 1133 is lost, so that when the third relay switch does not operate, the OFF state of the first circuit connection switch is maintained. and magnetically coupled to the second self-maintaining means when the third relay switch is operated to maintain the ON state of the first circuit connection switch sw1.

The spacer 1134a is installed to surround the N pole of the second self-maintaining means 1134, and is not directly coupled to each other when the second self-maintaining means and the first self-maintaining means are magnetically coupled, but has a predetermined gap. Induces to be coupled to each other while maintaining the first self-maintaining means and the second self-retaining means are induced to be more naturally separated by the action of the spacer when dismantling. If the spacer is not present, the body of the first self-holding means and the body of the second self-holding means are directly attached to each other, so that it is difficult to separate from each other later. Accordingly, in the present invention, a spacer is additionally installed so that the first self-maintaining means and the second self-maintaining means can be easily separated.

And, the reason for installing the spacer only around the N pole of the second self-maintaining means is that the first self-maintaining means and the second self-maintaining means must be separated when the relay switch is not operated, and at this time, the S of the first self-maintaining means The pole and the S pole of the second self-maintaining means face each other, so that the separated state can be easily maintained. If the spacer is wrapped up to the S pole of the second self-maintaining means, when the third relay switch does not operate, the pushing strength between the S poles of the first self-maintaining means and the second self-maintaining means is weakened by the interference of the spacer. Maintaining a spaced state may become unstable.

Accordingly, in the present invention, a spacer is installed only on the N pole of the second self-maintaining means to facilitate separation of the first self-maintaining means and the second self-maintaining means, and when magnetically coupled to each other, adjacent poles are separated. Due to the arrangement, it was made to easily maintain a magnetically coupled state. In fact, when the first self-maintaining means and the second self-maintaining means are coupled to each other, the N pole of the first self-maintaining means and the S pole of the second self-maintaining means are located directly adjacent to each other, thereby magnetically strongly coupled to each other. Even if the relay switch is turned off, the on state of the first circuit connection switch sw1 may be maintained as the falling state of the iron piece 1131 for circuit operation is continued.

The manual operation switch 1135 is coupled to the iron piece for circuit operation and the iron piece for connecting the power of the alarm signal output control unit, and when the user operates to stop the alarm signal operation while the alarm signal output unit is off, the iron piece for circuit operation and the alarm By turning off the iron piece for power connection of the signal output control unit, the operation of the alarm signal display unit is stopped so that the alarm signal is no longer output.

Hereinafter, the operation of the automatic alarm signal output unit 1000 will be described.

First, looking at the control relationship for outputting the alarm signal, the control unit applies power to the second relay switch to operate the third relay switch. Accordingly, as the first circuit connection switch sw1 and the power switch sw2 for outputting an alarm signal are turned on by the operation of the third relay switch, power is applied to the alarm signal output control unit 1140 to display the alarm signal.

When the first circuit connection switch sw1 operates, the control unit blocks the operation of the second relay switch to cut off the operation of the third relay switch, and simultaneously operates the first relay switch.

On the other hand, if the operator turns off the first circuit connection switch and the power switch for alarm signal output while the alarm signal is being output, the control unit understands this, and then operates the second relay switch to operate the third relay switch to operate the iron piece It is possible to continuously operate the alarm signal display unit 1150 by maintaining the closed circuit while moving and at the same time restoring the power output to the alarm signal control unit 1140 .

That is, in the present invention, if the alarm factor is not resolved, the warning sound is continuously output to induce the alarm factor to be solved.

That is, when the control unit applies a switching signal to the second relay switch and the first relay switch, the power is restored and the alarm signal is automatically output. Since it works again, it can induce the operator to solve the cause of the alarm signal reliably.

If the control unit recognizes that the output of the alarm signal is no longer necessary, the power signal is no longer applied to the first relay switch and the second relay switch. In this case, the user operates the manual switch 1135 to manually block the alarm signal. be able to do

The technical idea should not be interpreted limited to the above-described embodiment of the present invention. Various modifications can be made at the level of those skilled in the art without departing from the gist of the present invention as claimed in the claims. Accordingly, such improvements and modifications fall within the protection scope of the present invention as long as it is apparent to those skilled in the art.

40: motor
50: oil separator
60: receive tank
1000: automatic alarm signal output unit

Claims (2)

The compressed air produced by the motor 40 is stored in the sheave tank 60 through the oil separator 50, and the pressure switch ( 11) is installed, the motor 40 controls the power supply, and an inverter 30 having a slow start function is installed, but the upper limit setting value measurement signal of the pressure switch 11 is transmitted to the inverter 30 to transmit the motor (40) cut off the power supply and transmit the lower limit set value measurement signal of the pressure switch 11 to the inverter 30 to resume the power supply of the motor 40, so that the load operation and no-load operation are performed. It consists of a screw compressor control device to control;
An air flow sensor is further installed at the output end of the receive tank, and a control unit for calculating the amount of air currently present in the receive tank by combining the pressure switch and the air flow sensor is further installed, wherein the control unit includes the pressure switch and the air flow rate A control method of a screw compressor control device, characterized in that the operation of the motor is determined based on the calculation of the air amount according to the combination of sensors. The method of claim 1,
When an error condition of the pressure switch and the air flow sensor occurs, the automatic alarm signal output unit 1000 for outputting an alarm signal according to a control signal of the control unit is further included;
The alarm signal automatic output unit 1000,
a power supply unit 1110 for applying power by its own power supply; a first relay switch (RY1) installed on one side of the output terminal of the power supply unit to switch power output from the power supply unit; a second relay switch (RY2) installed on the other side of the output terminal of the power supply unit to switch the power supply unit output from the power supply unit; a third relay switch (RY3) coupled to the output terminal of the second relay switch and generating a magnetic force when the second relay switch is switched; a first circuit connection switch (sw1) performing a function of energizing the circuit while the iron piece is pulled by the third relay switch; As the iron piece is pulled by the third relay switch, power is supplied to the alarm signal output control unit 1140 to induce the alarm signal to be displayed through the alarm signal display unit 1150. A power switch for outputting a second alarm signal ( sw2) and; The second relay switch is switched to induce the third relay switch to be switched, and accordingly, the first circuit connection switch and the power switch for outputting the second alarm signal are switched, and thereafter, the second relay switch is turned off and the first By switching the relay switch, the third relay switch is turned off, and at the same time, the switching state of the first circuit connection switch configured to be interlocked with the first relay switch and the power switch for outputting the second alarm signal is maintained to maintain the alarm state. a control unit 1120; an iron piece 1131 for circuit operation that is in contact with the first circuit connection switch (sw1) and relays the power transmitted from the first relay switch to continue the flow of power; It is designed to operate in conjunction with the iron piece 1131 for circuit operation, and when the iron piece 1131 for circuit operation is turned on, power is connected to the alarm signal output control unit 1140 to induce the alarm device to operate. For iron pieces 1132 and; The first circuit connection switch sw1 and the iron piece 1131 for circuit operation are installed at the lower end of the iron plate 1131 for circuit operation and are formed in the form of a bar magnet with an S pole at the lower end, and when the third relay switch does not operate due to the influence of the S pole, the first circuit connection switch sw1 and the iron piece 1131 for circuit operation ) a first self-maintaining means 1133 for inducing to always maintain the off state; The first circuit connection switch sw1 is installed in the upper part of the first circuit connection switch sw1, but is made in the form of a bar magnet having an S pole at the upper end, and when the third relay switch is not operated, the first self-maintaining means 1133 having an S pole at the lower end is pushed to each other to push the circuit The iron piece 1131 for operation is electrically maintained by pushing up, and when the third relay switch is operated, the iron piece 1131 for circuit operation is pulled, the S pole constituting the upper part of the body and the first self-maintaining means 1133 ), the N pole constituting the upper part of the body is located close to each other, and at the same time, the N pole constituting the lower part of the body and the S pole constituting the lower part of the body of the first self-maintaining means 1133 are located close to each other, and the first magnetic When the holding means 1133 is magnetically coupled and the first circuit connection switch sw1 is switched at the same time, even if the operation of the third relay switch stops, the attachment state of the iron piece 1131 for circuit operation continues to close the first relay switch. A second self-maintenance that operates so that the alarm signal is output to the outside by automatically operating the iron piece for circuit operation when the iron piece for circuit operation is operated by the operation of the third relay switch means 1134; It is installed at the lower end of the iron plate 1131 for circuit operation in a state of being spaced apart from the first self-maintaining means 1133 by a predetermined interval and is formed in the form of a bar magnet having an S pole at the lower end and pushed against the second self-maintaining means having an S pole at the upper end. When the third relay switch is not operated, the iron piece 1131 for circuit operation is lifted from the first circuit connection switch (sw1) to maintain the cutoff state of the circuit, and when the third relay switch is operated, the iron piece 1131 for circuit operation is lowered. Auxiliary self-maintaining means (1133a) for maintaining the on state of the first circuit connection switch (sw1) and; It is installed around the N pole of the second self-maintaining means 1134, and when the second self-maintaining means and the first self-maintaining means are magnetically coupled, they are not directly coupled to each other but are coupled while maintaining a certain gap and a spacer (1134a) for guiding the first self-maintaining means and the second self-maintaining means to be naturally separated from each other when dismantling; It is coupled to the iron piece for circuit operation and the iron piece for power connection of the alarm signal output control unit, and when the user operates to stop the operation of the alarm signal, the iron piece for circuit operation and the iron piece for power connection of the alarm signal output control unit are turned off to operate the alarm signal display unit The control method of the screw compressor control device, characterized in that it further comprises a manual operation switch (1135) for inducing that the alarm signal is no longer output by stopping the.

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