KR940002960Y1 - Water-supply measuring apparatus of washing machine - Google Patents

Abstract

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Description

Water supply sensor of washing machine

1 is a schematic configuration diagram of a conventional washing machine.

2 is a detailed configuration of the pressure sensor of FIG.

3 is a water supply detection circuit diagram of a conventional washing machine.

4 is a schematic configuration diagram of a washing machine of the present invention.

5 is a water supply detection circuit diagram of a washing machine of the present invention.

* Explanation of symbols for main parts of the drawings

1: suspension rod 2: outer case

3: water tank 4: washing tank

5: suspension support 25: variable resistor

26,26 ': Hanging jaw 80: Water supply detection unit

The present invention relates to a water supply detection of a washing machine, and more particularly, to a water supply detection device of a washing machine to control the water supply in the washing tank by accurately detecting the water level by the weight sensor by the weight of the washing tank.

As shown in FIG. 1, the water supply sensing device of the conventional washing machine includes a washing tank 4 in which a water tank 3 and an agitator body 8 are rotatably installed inside the outer case 2. It is elastically supported by, the bottom of the water tank 3, the motor 7 is connected to the clutch 11 by the V (V) belt 6, the suspension support 5 is the lower portion of the water tank (3) It is inserted between the lower end of the suspension support rod (1) and the support arm (9), the upper and lower ends penetrating through the support arm (9) attached to the outer periphery and the support portion (10) fixed to the upper side of the outer case (2). Is composed of a spring 12 is configured to move the suspension support rod 1 up and down by the weight of the laundry tank 4, the water tank 3 and the laundry support body and the force of the spring 12, water supply amount sensing device Phosphorous pressure sensor 14 is configured to attach to the outer circumferential surface of the water tank 3 with the air tram 13 to detect the level of the washing tank 4.

FIG. 2 is a detailed view of the pressure sensor 14 of FIG. 1, and as shown therein, an air chamber 15 generating air by the pressure of water in the water tank 3 has a bottom surface of the water tank 3. It is installed on one side, the air chamber 15 is connected to the pressure sensor 14 by the air tram 13, the rubber film 16 for maintaining the air tightness inside the pressure sensor 14 and The coil 18 which changes the voltage by the vertical flow of the core 17, and the spring 19 which elastically supports the core 17 are built.

3 is a water supply detection circuit diagram of a conventional washing machine. As shown in FIG. 3, a key input unit 30 for selecting a desired state by pressing a key for various states such as washing, rinsing, dehydration, and washing time, and the According to the key signal of the key input unit 30, the microcomputer 90 for controlling the overall operation of the system and the input AC power supply AC are stepped down through the transformer T1, and the constant voltage is controlled through the rectifying unit 100a and the constant voltage unit 100b. A power supply unit 100 which is converted into a constant voltage of a level and supplied to the microcomputer 90 and on / off-switched according to the output control signal of the microcomputer 90 to drive the water supply valve IV and the motor 7. A display for displaying various states of the washing machine driven by a load driver 70 made of resistors R1-R9, transistors TR1-TR3, and triacs TA1-TA3, and a control signal of the microcomputer 90. Part 20 and the microcomputer 90 by using the oscillation frequency of the oscillation An oscillator 40 for providing a pulse, a reset unit 50 for supplying a reset signal to the microcomputer 90, and a current source at a frequency of use to recognize a point where the waveform crosses zero and thus, Interrupt generating unit 60 for generating an interrupt signal once to the microcomputer 90 and the water supply of the washing tank 4 in accordance with the high motion on the core 17 of the pressure sensor 14 to the microcomputer 90 It is composed of a water supply amount detecting unit 80 composed of an input capacitor C1-C3, a coil 18, resistors R10-R12, and inverter gates I1-I3. In the drawing, reference numeral Vcc denotes a power supply terminal. .

In the water supply detecting device of the conventional washing machine configured as described above, the input AC power is first stepped down through the transformer T1 of the power supply unit 100 and converted into a constant level constant voltage through the rectifying unit 100a and the constant voltage unit 100b. When supplied to the system, the microcomputer 90 is driven by the operation of the oscillator 40, the reset unit 50, and the interrupt generator 60.

At this time, by the key operation of the key input unit 30, the microcomputer 90 drives the display unit 20 to display various operating states of the system, and also through the resistor R1 of the load driving unit 70, the transistor TR1. A high signal is applied to the base of the transistor T1 to turn on the transistor TR1.

Accordingly, the trigger signal through the resistor R7 of the load driver 70 is applied to the gate of the triac TA1, and the water supply valve IV is opened by turning on the triac TA1 to the washing tank 4. Water is supplied.

When the water level is supplied to the washing tank 4 in such a state, the air of the air chamber 15 installed in the water tank 3 is compressed by the pressure of water, and the compressed air is pressure sensor via the air tram 13. As the rubber membrane 16 of 14 is inflated, the core 17 moves upward.

As a result, the frequency component generated by the coil 18 is changed by the core 17, and the resonant circuit includes the resistors R10 (R11) and the capacitors C1 (C2) and C3 of the water supply sensor 80. The frequency is changed by the furnace, and the changed signal is waveform-formed through the inverter gates I1 (I2) and I3 and input to the microcomputer 90.

At this time, the microcomputer 90 turns off the triac TA1 by turning off the transistor TR1 of the load driver 70 when the water supply amount detected by the water supply amount detecting unit 80 is a constant water level, and closes the water supply valve IV. In addition to blocking the water supply, a high signal is applied to the bases of the transistors TR2 and TR3 through the resistors R2 and R3 to turn on the transistors TR2 and TR3.

When the transistors TR2 and TR3 are turned on, trigger pulses are applied to the gates of the triacs TA2 and TA3 through the resistors R8 and R9 so that the triacs TA2 and TA3 are turned on. It is turned on, and the motor 7 rotates the washing tub 4 to the left and right to wash.

After washing is completed, the microcomputer 90 turns on the drain valve to drain the water in the washing tank 4 through the drain hose, and the water pressure in the air chamber 15 as the water in the water tank 3 is drained. Is gradually lowered, the core 17 is moved downward by the force of the spring (19).

Accordingly, the frequency of the coil 18 is changed to an initial state, and after a certain time elapses after the detection of the microcomputer 90, the dehydration proceeds.

However, such a conventional water level detection device of the washing machine detects the water pressure of the washing tank using a pressure sensor, and thus requires an air tram, which may cause bubbles in the air tram, thus preventing accurate water supply. There is also a problem that can not detect the water supply due to the air tram is not bent or fail to perform the core function due to air leakage, hole clogging and foreign matter inside.

The present invention, in view of such a conventional problem, by installing a spring and a variable resistor between the support portion and the suspension support rod fixed on one side of the upper case of the outer case to detect the water level in accordance with the resistance value change of the variable resistor to determine the water supply in the washing tank In order to control the water supply amount of the washing machine was devised, when described in detail based on the accompanying drawings of the present invention as follows.

4 is a schematic configuration diagram of a washing machine of the present invention, and as shown therein, a washing tank 4 having a water tank 3 and an agitator body 8 rotatably formed therein is supported by a suspension support rod 1. It is elastically supported, and the motor 7 is connected to the clutch 11 by the V-belt 6 on the bottom of the water tank 3, and the suspension support 5 is connected to the lower outer circumferential surface of the water tank 3; A spring inserted between the attached support arm 9 and the lower end of the suspension support rod 1 having the upper and lower ends penetrated through the support 10 fixed to the upper side of the outer case 2 and the support arm 9 ( 12) and a spring (21) inserted between the suspension support rod (1) and the washing tank (4) and the support portion (10) attached to the top of the outer case (2), washing tank (4), water tank (3) and laundry The suspension support rod 1 is configured to be moved up and down by the weight of the phosphorous support body and the force of the springs 12 and 21, and is installed at one side of the outer case 2. The support 10 is provided with a variable resistor 25 having a fixed terminal 24, a variable terminal 23, and a variable lever 22, and the variable lever 22 of the variable resistor 25 is a suspension support rod 1. It is configured by inserting between the locking step (26) (26 ') formed on the top of the).

5 is a water supply amount detection circuit diagram of a washing machine of the present invention. As shown in FIG. 5, a key input unit 30 for selecting a desired state by pressing a key for various states such as washing, rinsing, dehydration, and washing time, and According to the key signal of the key input unit 30, the microcomputer 90 for controlling the overall operation of the system and the input AC power supply AC is stepped down through the transformer T1 and through the rectifying unit 100a and the constant voltage unit 100b. The power supply unit 100 is converted to a constant voltage of a predetermined level and supplied to the microcomputer 90, and is switched on and off according to the control signal of the microcomputer 90 to drive the water supply valve IV and the motor 7. A display for displaying various states of the washing machine driven by a load driver 70 made of resistors R1-R9, transistors TR1-TR3, and triacs TA1-TA3, and a control signal of the microcomputer 90. Clock to the microcomputer 90 by using the oscillation unit 20 and the oscillation frequency An oscillator 40 for providing a pulse, a reset unit 50 for providing a reset signal to the microcomputer 90, and a current source at a commercial frequency to recognize a point where the waveform intersects with zero every cycle Interrupt generator 60 for generating an interrupt signal to the microcomputer 90 once, resistors R11 to R22 for detecting a water supply amount by comparing the voltage according to the variable of the variable resistor 25 with a reference voltage, and a comparator ( CP1), transistor TR4, and buffer B1, each of which consists of a water supply amount detecting unit 80. In the figure, reference numeral Vcc denotes a power supply terminal.

Referring to the operation, effects of the present invention configured as described above in detail.

When the input AC power supply AC is stepped down through the transformer T1 of the power supply unit 100 and is converted into a constant voltage of a predetermined level through the rectifying unit 100a and the constant voltage unit 100b and supplied to the system, the oscillator 40 and The microcomputer 90 is driven by the operation of the set unit 50 and the interrupt generator 60.

At this time, by the key operation of the key input unit 30, the microcomputer 90 drives the display unit 20 to display various operating states of the system, and also through the resistor R1 of the load driving unit 70, the transistor TR1. The signal is turned on by applying a high signal to the base.

Accordingly, the trigger signal through the resistor R7 of the load driver 70 is applied to the gate of the triac TA1, and the water supply valve IV is opened by turning on the triac TA1 to the washing tank 4. Water is supplied.

When the water level is supplied to the washing tank 4 in such a state, the water weight is stronger than the force of the springs 12 and 21 inserted between the support arm 9 and the suspension support rod 1, so that the water tank 3 is Moving downward, and thus the suspension support rod 1 moves downward with the water tank 3, so that the variable lever 22 inserted between the latching jaws 26 and 26 'of the suspension support rod 1 is moved. The resistance of the variable resistor 25 is changed by downwardly centering the variable resistor 25.

Since the changed voltage is applied to the inverting input terminal (-) of the comparator CP1 configured in the water supply sensor 80 according to the change of the resistance value of the variable resistor 17, the comparator CP1 is a resistor R16 (R18). Compared to the reference voltage of the power supply terminal (Vcc) divided by the input through), the comparison voltage is input to the microcomputer 90.

At this time, the microcomputer 90 closes the water supply valve IV by turning off the transistor TR1 and the triac TA1 of the load driver 70 when the water supply amount detected by the water supply amount detection unit 80 is a constant water level, Alternately, a high signal is applied to the transistor base via (R2) (R3) to turn on the transistors TR2 (TR3) alternately.

When the transistors TR2 and TR3 are alternately turned on, trigger pulses are applied to the gates of the triacs TA2 and TA3 through the resistors R9 and R9 to thereby form the triacs TA2 and TA3. It is turned on and the motor 7 rotates the washing tub 4 to the left and right to wash.

After the washing is completed, the microcomputer 90 turns on the drain valve to drain the water in the washing tank 4 through the drain hose, and as the water in the water tank 3 is drained, the water tank 3 and the washing tank ( The force of the springs 12 and 21 is stronger than the total weight of 4), and the water tank 3 is gradually moved upward, and the suspension support rod 1 is gradually moved upward while the variable lever 22 of the variable resistor 25 is moved. Will be moved.

As the variable lever 22 is moved upward again, the resistance value of the variable resistor 25 is changed to an initial state, and the microcomputer 90 detects this to advance dehydration after a predetermined time.

As described in detail above, the present invention detects the amount of water supplied by the weight sensor, so that the amount of water supplied can be detected more accurately than the amount of water detected by the pressure sensor. There is an effect that can prevent the defective rate.

Claims (1)

A water supply sensor of a washing machine in which a water tank (3) and a washing tank (4) are elastically supported by a suspension support rod (1) that is moved up and down, and rotated by a drive of a motor (7) for washing. The spring 21 is inserted into the upper portion of the upper portion (1), and the locking jaws 26 and 26 'are formed at regular intervals at the ends thereof, and the variable lever 22 of the variable resistor 25 installed in the support 10 is provided. Is inserted into the locking step (26) (26 '), the amount of water supply of the washing machine, characterized in that configured to detect the amount of water in accordance with the resistance value of the variable resistor (25).