KR20000043410A - Circuit for controlling a driving motor of a washing machine - Google Patents

Abstract

The present invention relates to a control circuit of a washing motor for driving a washing tank and a pulsator, and an object of the present invention is to prevent the driving motor from being placed in an unbalanced magnetic flux state by virtue of a starting capacitor for torque improvement during dehydration, thereby preventing vibration noise. The present invention provides a drive motor control circuit for a washing machine.

The technical configuration of the present invention connects the starter coil 32 and the series circuit of the switch 34 and the starter capacitor 33 to both ends of the main coil 31 of the washing machine driving motor 20 to which the AC drive voltage is applied. The switch 34 is configured to be switched off by a drive motor speed setting value reaching signal or a starting time setting value reaching signal output from the microcomputer 10 in the dehydration driving mode.

As described above, the present invention switches the circuit connection state of the driving motor during the dehydration operation and the washing operation, respectively, to prevent the unbalance of the magnetic flux generated by the start coil and the start capacitor in the existing dehydration mode, thereby preventing vibration during dehydration. It can be prevented.

Description

Drive motor control circuit of washing machine

The present invention relates to a control circuit of a laundry driving motor for driving a washing tank and a pulsator, and in particular, a washing machine for preventing a vibration noise by causing an unbalance of a driving capacitor to increase torque in a driving motor during dehydration operation. It relates to a drive motor control circuit of.

After the laundry is put into the washing machine and the washing operation conditions are determined by using the function selection buttons of the operation selector provided on the instrument panel of the washing machine, the start control is pressed. The washing control microcomputer detects the load value of the load sensor sensing the weight of the laundry in the washing tank. It is accepted.

There are a load cell method and a load current detection method in the method of measuring the washing amount by the load sensor. The load cell method measures the weight of the washing machine by subtracting the weight of the washing tank by measuring the load cell installed at the lower part thereof by increasing the weight of the washing tank by adding the laundry to the washing tank, and measuring the weight of the actual washing machine. When turned on, the driving motor is temporarily driven to rotate the pulsator connected thereto, and the amount of washing in the washing tank is measured by comparing the magnitude of the driving motor driving current according to the magnitude of the rotational resistance of the pulsator to a reference value. .

In the former case, the exact value of the laundry can be read, but there is a difficulty in designing the mechanical installation structure of the load cell sensor. Recently, the technique of measuring the washing amount by reading the change of the drive motor driving current, which is the latter, is the most common. Is being applied to.

FIG. 1 is a circuit diagram of a general washing machine control system, which includes a memory 13 storing information related to a system program, a reservation, and the like, and a timer 14 for present time information and a timing count. (10) is connected so that key input data of the operation selection unit 12 for inputting the function selection and setting conditions of the washing control program is input.

The microcomputer 10 also receives the sensing data of the water level sensor 11 for sensing the water level for each quantity of water supplied to the washing tank 22 and the sensing data of the load sensor for sensing the weight of the laundry to determine the washing amount. Is connecting.

The water supply control signal output from the microcomputer 10 is connected to the water supply valve 16 through the water supply valve driving unit 15 to operate, and the drain control signal through the drain valve driving unit 17 by the drain control signal. 18) is working.

In addition, the drive motor control signal output from the microcomputer 10 is connected to be applied to the drive motor 20 through the motor driving unit 19, the power generated in the drive motor 20 is the washing tank through the gear mechanism 21 It is connected so that it may be transmitted to 22 and the pulsator 23.

When washing is performed using a washing machine having such a washing machine control circuit, the washing machine user puts the laundry in the washing tank and selects the washing operation mode and the dehydration time using the operation selector 12 and then presses the start button. .

Accordingly, the microcomputer 10 of the washing machine control circuit temporarily drives the driving motor 20 to cause the pulsator 23 to rotate forward and backward several times. At this time, the load current applied to the driving motor is read through the current sensor. It will be.

When the load current according to the washing amount is input to the microcomputer 10, the microcomputer finds the washing quantity information for each sensing washing quantity in the table of the memory 13 and determines the quantity required by the laundry currently in the washing tank and the corresponding water level. Done.

When the position of the water level sensor for detecting the set water supply level for the laundry is determined, the microcomputer 10 controls the water supply valve driving unit 15 to open the water supply valve 16 to surround the washing tank 22. Do watering on.

When water supply is continued and the water supply completion up to the set water level is detected by the water level sensor 11 and this sensing data is input to the microcomputer 10, the microcomputer 10 is driven through the motor driving unit 19. The washing operation mode is performed by supplying a drive current to the drive motor 20 so that the pulsator 23 rotates forward and backward by the gear mechanism 21 coupled to the drive motor.

When washing is completed as the washing operation according to the rotation operation of the pulsator 23 is performed for the strength and time set by the washing program input of the operation selecting unit 12, the microcomputer 10 is the drain valve driver 17. The drain valve 18 is operated to discharge the wash water stored in the reservoir.

After completion of drainage, the microcomputer 10 ends the series of washing operations by performing a rinsing operation mode and a dehydration operation to rinse the detergent remaining in the laundry.

On the other hand, the washing operation and the dehydration operation in the washing machine is performed by receiving the power generated in one drive motor 20 through the gear mechanism 21, the internal circuit configuration of such a drive motor 20 is a powerful torque Since it is designed for the washing operation that requires, the vibration is generated in the dehydration operation mode.

2 is an internal circuit diagram of a conventional drive motor, and shows a state in which a series circuit of a start coil 32 and a start capacitor 33 is connected to both ends of the main coil 31 of the washing machine drive motor 20.

In this case, when the motor is started, a large current is supplied to the starting coil 32 through the starting capacitor 33, thereby obtaining a strong torque. After that, when the driving motor 20 reaches a predetermined rotation speed, the motor rotation is performed by the magnetic flux by the main coil 31.

This starter condenser connection circuit is advantageous in the washing operation mode that requires strong torque. The washing operation is performed by repeating the forward and reverse rotation of the drive motor. This is because it needs to be reached quickly.

However, when the driving motor 20 must be continuously operated at high speed like the dehydration operation mode in a state in which the series circuit by the starting capacitor and the starting coil is connected to both ends of the main coil, the phase difference caused by the condenser 33 ( In the capacitive circuit, the current is higher than the voltage) causing an unbalance of the magnetic flux of the motor, which causes the washing machine to generate noise due to vibration.

An object of the present invention is a source of vibration noise caused by the starting capacitor for improving the torque of the driving motor when the dehydration in the control circuit of the washing motor for driving the washing tank and the pulsator causes a magnetic flux imbalance of the driving motor It is to provide a drive motor control circuit of a washing machine that can be prevented.

1 is a block diagram of a general washing machine control circuit.

2 is an internal circuit diagram of a conventional driving motor.

3 is a first embodiment of an anti-vibration control circuit during dehydration according to the present invention.

Figure 4 is a second embodiment of the anti-vibration control circuit when dewatering according to the present invention.

※ Explanation of symbols about main part of drawing ※

10: microcomputer 11: water level sensor

12: operation selection unit 13: memory

14: timer 15: water supply valve drive unit

16: water supply valve 17: drain valve drive unit

18: drain valve 19: drive motor drive unit

20: drive motor 21: gear mechanism

22: washing tank 23: pulsator

24: pulse generator 31: main coil

32: starting coil 33: starting capacitor

34: switch

A feature of the present invention for achieving the above object is to connect a series circuit of a start coil and a switch and a start capacitor at both ends of the main coil of the washing machine driving motor to which the AC drive voltage is applied, and the switch is output from the microcomputer in the dehydration operation mode. It is configured to connect so as to be switched off by the drive motor speed set value reach signal or start time set value reach signal.

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

3 is a first embodiment of an anti-vibration control circuit during dehydration according to the present invention.

As referred to herein, the starter coil 32 and the switch between the main coil 31 of the drive motor 20 to which the AC voltage generated from the motor driver 19 is applied in response to the control signal of the microcomputer 10. 34) and a timer (14) for connecting the series circuit composed of the starting capacitor (33), and determining whether a preset reference time is reached after inputting a starting current to the coil of the driving motor (20). The switch 34 is connected to be switched off with a control signal output from the microcomputer 10 when the set time is reached by reading real time timing information from the real time timing information.

Referring to the operation of the first embodiment of the present invention as follows.

When the motor control signal from the microcomputer 10 according to the washing program is applied to the driving motor 20 through the motor driving unit 19, the driving current is input to the main coil 31 and the starting coil 32.

At this time, since the current through the start capacitor 33 is supplied to the start coil 32 before the voltage, a current is supplied to the start coil 32 before the main coil 31 to start the motor. Accordingly, the drive motor 20 is easily started and then rotates with a large torque in response to the magnetic flux by the main coil 31.

At the same time, the microcomputer 10 receives the timing count from the timer 14 after generating the drive motor control signal and determines whether the preset time has been reached. Here, the time set in advance is determined by the time until the drive motor 20 starts to start and reaches the normal speed.

Accordingly, when the timing counted value after the start of the driving motor 20 reaches a preset value, the microcomputer 10 outputs a timing control signal, and the switch 34 is opened by the signal, so that the start coil 32 The phenomenon of the magnetic flux imbalance in the main coil 31 due to) is essentially eliminated.

Figure 4 is a second embodiment of the anti-vibration control circuit when dewatering according to the present invention.

As referred to herein, between the main coil 31 of the driving motor 20 to which the AC voltage generated from the motor driving unit 19 is applied in response to the control signal of the microcomputer 10, the starting coil 32 and the switch ( 34) and a series circuit composed of the starting capacitor 33, and starting from the pulse generator 24 to determine whether the preset rpm is reached after inputting a starting current to the coil of the drive motor 20. The switch 34 is connected to be switched off as a pulse control signal output from the microcomputer 10 when the previously set motor rotation speed, that is, the normal speed, is read.

Referring to the operation of the second embodiment of the present invention as follows.

When the motor control signal from the microcomputer 10 according to the washing program is applied to the driving motor 20 through the motor driving unit 19, the driving current is input to the main coil 31 and the starting coil 32.

At this time, since the current through the start capacitor 33 is supplied to the start coil 32 before the voltage, the current is supplied to the start coil 32 before the main coil 31 to start the drive motor 20. Accordingly, the drive motor 20 is easily started and then rotates with a large torque in response to the magnetic flux by the main coil 31.

At the same time, the microcomputer 10 monitors the pulses emitted from the pulse generator 24 after outputting the drive motor control signal, and determines whether the number of input pulses reaches the number of pulses generated at a predetermined normal speed.

When it is determined that the driving motor 20 has reached the normal speed by monitoring the number of pulses coming from the pulse generator side, the microcomputer 10 outputs a pulse control signal to the switch 34 to switch off by the start coil. The phenomenon that magnetic flux imbalance occurs in the main coil 31 is essentially blocked.

As described above, the present invention solves the problem of the imbalance of magnetic flux caused by the motor torque improving capacitor connected between the main coil and the starting coil of the motor during the dehydration operation when the washing operation and the dehydration operation are performed using one motor. As it can be solved through the installation of a simple switch, a unique effect of removing the noise from the washing tank due to the flux imbalance is shown.

Claims (2)

In the washing driving motor driving circuit of the washing machine, a series circuit of the starting coil 32, the switch 34, and the starting capacitor 33 is connected to both ends of the main coil 31 of the washing machine driving motor 20 to which the AC driving voltage is applied. After connecting the starting current to the coil of the drive motor 20, in order to determine whether the rpm set in advance is reached or not, the rotation speed information according to the motor rotation from the pulse generator 24 is read and the previously set normal The drive motor control circuit of the washing machine, characterized in that the switch 34 is configured to be switched off as a pulse control signal output from the microcomputer 10 when the speed is reached. The real time timing information from the timer 14 according to claim 1, wherein the switch 34 determines whether a preset reference time has been reached after inputting a starting current to the coil of the driving motor 20. Driving motor control circuit of the washing machine characterized in that the configuration is connected to switch off by the control signal output from the microcomputer 10 when the set time is reached.