KR19980021848A - Washing machine control device - Google Patents

Abstract

The present invention relates to a laundry control apparatus of a washing machine for detecting the amount of laundry and the degree of contamination thereof to be washed more cleanly.

To this end, the present invention is a microcomputer for controlling the entire system of the washing machine, a load driving unit for controlling the driving of the washing motor under operation according to the control signal instantaneously output from the microcomputer, and when the operating voltage applied to the washing motor is cut off The quantity detection unit that detects the quantity in the washing tank instantaneously by input power generated by the rotational inertia force of the washing motor and inputs it to the microcomputer, the contamination sensor that detects and outputs the contamination level of the laundry in the washing tank instantaneously, Yipirom, which stores the program to proceed, proportional integrating operation part that detects the error by comparing the actual speed fed back from the washing motor and the reference speed and outputs an error compensation value, and the actual speed fed back from the washing motor. Calculate the standard speed, the initial current and the current after laundry. The load calculation unit outputting to the purge unit, the neuro-purge unit for changing the command speed and phase angle and outputting the calculation value output from the load operation unit through the neuro-purge process, the error compensation value output from the proportional integral operation unit, It is composed of a phase control unit for controlling the speed of the washing motor according to the command speed and phase angle changed from the neuro-purge unit.

Description

Washing machine control device

1 is a block diagram of a conventional washing machine washing control device.

2 is a block diagram of a washing machine washing control apparatus according to the present invention.

3 is a block diagram illustrating a speed control block of a washing motor applied to FIG. 2.

4 shows the initial washing control process of FIG. 2 and the introduction of new laundry.

Output waveform diagram of the washing control process.

Explanation of symbols for the main parts of the drawings

101: micom 102: load driving unit

103: washing motor 104: quantity detection unit

105: washing tank 106: pollution sensor

107: EEPROM 108: proportional integral operation unit

109: load calculation section 110: neuro-purge section

111: phase control unit

The present invention relates to a washing machine, and more particularly, to a laundry control apparatus for washing the laundry by detecting the amount of laundry and the degree of contamination thereof during cleaning.

The conventional washing machine has a load for controlling the driving of the washing motor 3 by operating according to the microcomputer 1 for controlling the entire system of the washing machine and the control signal output from the microcomputer 1 as shown in FIG. When the operating voltage applied to the driving unit 2 and the washing motor 3 is cut off, the amount of power in the washing tank (not shown in the drawing) is detected by the excitation voltage generated by the rotational inertia force of the washing motor 3 and the micom ( It is comprised by the quantity detection part 4 input to 1).

In the conventional washing machine configured as described above, when a user presses a washing key configured in a key input unit (not shown in the drawing) and inputs a washing stroke by detection of a quantity, the microcomputer 1 reads the key signal of the key input unit and performs an initial operation. do.

That is, the microcomputer 1 initially opens the cold and hot water valves (not shown) through the load driving unit 2 to supply water to a small amount of water in a washing tank.

Then, when the water supply is completed to a small level in the washing tank, the microcomputer 1 rotates the washing motor 3 clockwise or counterclockwise through the load driving unit 2 for a predetermined time in order to detect the amount of water in the washing tank.

On the other hand, the microcomputer 1 turns off the washing motor 3 through the load driving unit 2 after a predetermined time elapses.

At this time, the washing motor 3 stops gradually as the speed decreases without immediately stopping by the inertia force of rotation even if the operating voltage is blocked in the load driving unit 2.

That is, if the quantity in the washing tank is large, the rotation of the washing motor 3 is stopped more quickly because the friction force between the pulsator (not shown in the drawing) and the laundry is increased. The rotation slowly decreases.

In this way, the excitation voltage generated by the rotational inertia force of the washing motor 3 is detected by the quantity detecting unit 4, and the input is input to the microcomputer 1 after it is converted into a digital signal.

Then, the microcomputer 1 determines that the quantity of the quantity is large and small according to the number of waveforms obtained from the quantity detecting unit 4, and one of the water level (high water level, medium water level, low water level, small water level, minimum water level) according to the determined quantity of water. In addition to setting the washing level of the washing time will be set.

Thereafter, the washing administration is performed for a predetermined time, and when the washing administration is completed, the water is drained, and then the amount of water is detected again to determine the rinsing level.

When the rinsing water level is determined in this way, the rinsing stroke is advanced to the determined water level.

However, such a conventional washing machine does not check the amount or contamination even if the laundry is put in the middle of the laundry, there was a problem that can not be washed for this.

Therefore, the present invention is to solve the problems of the prior art as described above, an object of the present invention is to detect the amount of laundry put into the laundry and to measure the degree of contamination to perform more precise washing.

Technical means for achieving the object of the present invention is a microcomputer for controlling the entire system of the washing machine, a load driving unit for controlling the driving of the washing motor in accordance with the control signal instantaneously output from the micom, and applied to the washing motor When the operation voltage is cut off, the capacity of the washing tank instantaneously detects the amount of laundry in the washing tank by the inertia voltage generated by the rotational inertia force of the washing motor, and immediately detects and outputs the contamination level of the laundry in the washing tank. It is made of a contamination sensor, and YPIROM storing a program for proceeding the laundry administration.

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

2 is a block diagram of a washing machine washing control apparatus according to the present invention, the microcomputer 101 for controlling the entire system of the washing machine, and the washing motor according to the control signal instantaneously output from the microcomputer 101 ( The load driving unit 102 for controlling the driving of the 103 and the amount of force in the washing tank 105 by the excitation voltage generated by the rotational inertia force of the washing motor 103 when the operating voltage applied to the washing motor 103 is blocked. The quantity detection unit 104 which detects and instantaneously inputs the microcomputer 101, the contamination sensor 106 which detects and outputs the contamination degree of the laundry in the washing tank 105 instantaneously, and proceeds to the washing administration. It consists of the Y pyrom 107 which stores the program for this.

The operation and effects of the present invention configured as described above will be described with reference to FIGS. 2 through 4.

First, when a user presses a laundry key (not shown in the accompanying drawings) configured in the key input unit (not shown) to input a washing stroke by detecting the amount of water, the microcomputer 101 reads the key signal of the key input unit. Perform initial operation.

That is, initially, the microcomputer 101 opens the cold water and hot water valves (not shown in the accompanying drawings) through the load driving unit 102 to supply water to a small amount of water in the washing tank 105.

Then, when the water supply to the small amount of water in the washing tank 105 is completed, the microcomputer 101 rotates the washing motor 103 clockwise or half through the load driving unit 102 for a predetermined time in order to detect the amount of water in the washing tank 105. Rotate clockwise.

Then, the microcomputer (01) is turned off the washing motor 103 through the load driving unit 102 after a predetermined time elapses.

At this time, the washing motor 103 does not stop immediately by the inertia force of rotation even if the supply of the operating voltage is cut off in the load driving unit 102 is gradually stopped as the speed is reduced.

That is, if the quantity in the washing tank l05 is large, the rotation of the washing motor 103 is stopped more quickly because the friction force between the pulsator (not shown in the accompanying drawings) and the laundry (not shown in the attached drawings) is increased. If less, the frictional force is less, the rotation of the washing motor 103 is gradually reduced.

In this principle, the quantity detecting unit 104 detects the excitation voltage generated by the rotational inertia force of the washing motor 103, forms it, converts it into a digital signal, and inputs it to the microcomputer 101.

In addition, the contamination sensor 107 detects the contamination level of the laundry in the washing tank 105, converts the result into an electrical signal, and inputs the result to the microcomputer 101.

Then, the microcomputer (011) determines the amount of small and small amounts of contamination and the degree of contamination of the laundry according to the number of waveforms obtained by the quantity detecting unit 104 and the contamination value detected from the contamination sensor 107, and the determined quantity and pollution degree. According to the water level (high water level, medium water level, low water level, low water level, minimum water level), one of the washing water level is set, the washing time is set, and the washing administration is performed for the set time.

In addition, the microcomputer (011) receives the load change instantaneously detected from the quantity detection unit 104 and the pollution sensor 107 and the contamination level during the washing operation during the set time to receive the load driving unit 102 The washing process is controlled by the control.

Subsequently, when the user puts new laundry into the washing tank 105 during washing, the microcomputer 101 feeds back the actual speed of the washing motor 103 to the proportional integral operation unit 108 as shown in FIG. 3. Will be entered.

Then, the proportional integral operation unit 108 compares the input reference speed with the feedback actual speed, detects the error, and outputs an error compensation value to the phase controller 111.

In addition, the load calculation unit 109 calculates the reference speed, the actual speed, and the initial current amount i _A and the current amount i _B after the laundry is input from the washing motor 103, and calculates the result of the neuro-purge unit. Output to (110).

Then, the neuro-purge unit 110 changes the speed with respect to the load by changing the phase angle to advance or backward the command phase angle by the following equation.

T _input = J (d _w / d _t )-T _L

Where T _input = Input Torque, T _L = Load Torque, j = Inertia Moment.

⇒ d _w / d _t = (1 / J) T _input -T _L

⇒ T _L =-(1 / J) (d _w / d _t ) + T _input . Formula (1)

In the above formula (1), T _input is as follows.

T = Ψ * i... Formula (2)

Where T = original torque, Ψ = magnetic flux, i = current, and * = vector product.

Therefore, the input current is as follows.

i _id = i _A · cos θ − i _B · sin θ, i _iq = -i _A · sin θ + i _B · sin θ. Formula (3)

Here, Equation (3) is converted from the stator coordinate system to the rotor coordinate system, i _id and i _iq are DC values, and the actual torque generating current is i _iq and the current generating magnetic flux is i _ia . ) Is changed to

T = L _m (i _id × i _iq ). Formula (4)

In addition, the measurement of (theta) angle is as follows.

Θ = w _r t + θ _sl . Formula (5)

Where w _r = actual velocity and θ _sl = slip angle.

Substituting equation (4) into equation (1)

T _L =-(1 / J) (d _w / d _t ) + L _m (i _id × i _iq )... Formula (6)

By Neuro-Fuzzy the above equation development process, it is possible to measure the load completely instantaneously and do the washing as there is no speed decrease or increase as long as it does not exceed the motor rating no matter what load is input. can do.

In addition, by measuring the degree of contamination through a contamination sensor it is possible to adjust the washing time instantaneously.

4 is an output waveform diagram of the initial washing control process of FIG. 2 and the washing control process when new laundry is put in. As shown in FIG. The command speed is reached after ts time.

In addition, the phase control unit 111 controls the speed of the washing motor 103 according to the error compensation value output from the proportional integration operation unit 108 and the phase angle control signal output from the neuro-purge unit 110. .

However, since the rotational speed of the actual washing motor 103 is different from the standard output speed due to various factors, the actual output speed is fed back and compared with the reference speed by correcting the reference speed. By repeating the above process until the match is to control the speed of the washing motor 103.

Thereafter, the washing administration is performed for a predetermined time, and when the washing administration is completed, the water is drained, and then the amount of water is detected again to determine the rinsing water level as described above.

When the rinsing water level is determined in this way, the rinsing stroke is advanced to the determined water level.

As described above, the present invention has the effect of detecting the amount of laundry and its pollution during washing and preventing the reduction or increase of speed through this, so that not only the original laundry but also new laundry can be washed cleanly.

Claims (1)

A microcomputer 101 for controlling the entire system of the washing machine, a load driver 102 controlling the driving of the washing motor 103 by operating according to a control signal instantaneously output from the microcomputer 101, and the washing motor. When the operation voltage applied to the 103 is cut off, the quantity detection unit for detecting the quantity in the washing tank 105 by the excitation voltage generated by the rotational inertia force of the washing motor 103 and instantaneously inputting it to the micom l01 ( 104, a contamination sensor 106 for detecting and outputting the contamination level of the laundry in the washing tank 105 instantaneously, an Y pyrom 107 for storing a program for proceeding the washing process, and the washing motor ( A proportional integrating unit 108 which detects the error by comparing the actual speed fed back from the reference speed and the reference speed and outputs an error compensation value, the actual speed and the reference speed fed back from the washing motor 103, And early Ryuryang (i _A) and the operation accepted is the laundry amount of electric current (i _B) after the input and as a result the neuro-flops the calculated value output from unit 110 load calculating section 109 and the load calculating section 109 for output to a From the neuro-purge unit 110 to change the command speed and phase angle through the neuro-fuzzy process and output the error compensation value and the neuro-purge unit 110 output from the proportional integral operation unit 108 Washing control device of the washing machine comprising a phase control unit 111 for controlling the speed of the washing motor 103 in accordance with the changed command speed and phase angle.