KR940000579Y1 - Circuit for supply electricity of tableware - Google Patents

Abstract

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Description

Power supply circuit of dish dryer

1 is a power supply circuit diagram of a conventional dish dryer.

(A) to (h) of FIG. 2 are output waveform diagrams of a microcomputer for driving the display unit of FIG.

(A) to (f) of FIG. 3 are output waveform diagrams of respective parts due to the voltage difference of the constant voltage means of FIG.

4 is a power supply circuit diagram of the present invention dish dryer.

* Explanation of symbols for main parts of the drawings

1: Micom 2: Power supply means

3: first constant voltage means 4: second constant voltage means

5: display driving means 6: display means

The present invention relates to the power supply of the dish dryer, and in particular, the power supply of the dish dryer to prevent the malfunction of the circuit caused by the unbalance of the voltage difference by supplying stably without two voltage difference in the circuit using the power supply double. It is about a circuit.

As shown in FIG. 1, the power supply circuit of the conventional dish dryer includes a function selection input means 7 for selecting a desired stroke by pressing a function selection switch for washing, rinsing, drying and various stroke states. According to the function selection of the function selection input means 7, the microcomputer 1 for controlling the overall operation of the dish dryer and the AC voltage AC input are stepped down by the transformer 2a and the bridge diode 2b and the capacitor The power supply means 2 rectifying through C1 and the voltage output from the power supply means 2 control the transistor TR1 through the respective resistors R1 and Zener diodes ZD1 and condenser. A first constant voltage means 3 for smoothing through (C2) and inputting a constant voltage of a predetermined stage to the power terminal Vcc of the microcomputer 1, and a voltage of the power supply means 2 to a constant voltage of a predetermined stage Zener diode (ZD2), resistor (R2), and transistor Resistor R3 for switching the voltage of the second constant voltage means 4 by switching by the second constant voltage means 4 composed of the rotor TR2 and the condenser C3 and a control voltage output from the microcomputer 1. Display driving means 5 consisting of R4 and transistors TR3 and TR4, and a resistance to visually display the washing, rinsing, and drying strokes by being driven by the output voltage of the display driving means 5 Display means (6) consisting of R5-R8) and light emitting elements (LED1-LED4), load driving means (8) for controlling the blower and heating body by driving by the control voltage of the microcomputer (1), and in the washing tank Water temperature sensing means 9 which detects water temperature and inputs it to the microcomputer 1, and receives a current source at a commercial frequency and recognizes the point where the waveform crosses zero with one signal and interrupts the signal once per period. Initializing means to the micom (1) consists of an initializing means (11) for stabilizing the malfunction of the dryer It can control.

In this way, the power supply circuit of the conventional dish dryer configured as described above, when the power switch of the dish dryer is turned on, the input alternating current AC is stepped down through the transformer 2a of the power supply means 2 and the stepped down voltage is bridged diode ( It is rectified in 2b) and smoothed through the capacitor C1 and then applied to the first constant voltage means 3 and the second constant voltage means 4.

The voltage output from the power supply means 2 is dropped by the resistors R1 and R2 of the first and second constant voltage means 3 and 4, and then by the zener diodes ZD1 and ZD2. It is applied to the base of the transistors TR1 and TR2 at a constant voltage to conduct the transistors TR1 and TR2.

Therefore, the voltage output from the power supply means 2 is smoothed through the transistors TR1 and TR2 of the first constant voltage means 3 and the second constant voltage means 4 and in the capacitors C1 and C2. And is applied to the power supply terminal Vcc of the microcomputer 1 and to the display driving means 5.

At this time, when the user selects a desired stroke through the function selection input means 7, that is, a washing, rinsing and drying stroke, the microcomputer 1 conducts the light emitting elements (LED 1 -LED 4) of the corresponding display means 6. To output a low potential as shown in (a) of FIG. 2 to its output terminal A1, and a low potential as shown in (h) of FIG. 2 to the output terminal A6.

The low potential output from the output terminal A1 of the microcomputer 1 is applied to the base of the transistor TR3 configured in the display driving means 5 to conduct the transistor TR3, and the transistor TR3 When conducting, the output voltage of the second constant voltage means 4 conducts through the transistor TR3 of the display driving means 5 the light emitting element LED4 of the display means 6 at high potential as shown in FIG. This function will be displayed.

In addition, in order to conduct the light emitting element LED1 of the display means 6 in accordance with the function selection of the function selection input means 7, the microcomputer 1 has its output terminal A2 as shown in FIG. In addition to outputting the potential, the output terminal A3 outputs a low potential as shown in (e) of FIG. 2, and the low potential output from the microcomputer 1 is applied to the transistor TR4 of the display driving means 5. Is applied to the base of the wire to conduct it.

Accordingly, the output voltage of the second constant voltage means 4 conducts the light emitting element LED1 of the display means 6 through the transistor TR4 at high potential as shown in FIG. Will be displayed.

However, in the power supply circuit of the conventional dish dryer, the display driving means is cut off by the control voltage of the microcomputer only when the output voltage of the first constant voltage means is greater than the output voltage of the second constant voltage means, so that the operation of the light emitting element of the display means. If the output voltage of the first constant voltage means is output 0.7 volts or more lower than the output voltage of the second constant voltage means due to the characteristics of the transistor and the zener diode of the constant voltage means, as shown in (c) to (f) of FIG. Regardless of the output voltage of the microcomputer, that is, a low voltage input to the power supply terminal of the microcomputer is applied to the transistor base of the display driving means, and the output voltage of the second constant voltage means is applied to the emitter of the transistor. The transistor is turned on by the potential difference to apply a high potential as shown in Figs. 3 (a) and 3 (b) to the display means.

This causes a problem that the light emitting device of the display means operates in an uncontrolled state irrespective of the output voltage of the microcomputer.

Therefore, an object of the present invention is to step down the transistor base voltage of the first constant voltage means in a predetermined step through a diode and then apply it to the transistor base of the second constant voltage means, so that the output voltage of the second constant voltage means does not change under any input power supply voltage. The power supply circuit of the dish dryer is provided to reduce and output the output voltage of the first constant voltage means in a predetermined step so as to stably control the driving of the display means.

As a means for achieving the object of the present invention, the first constant voltage means for maintaining the voltage obtained from the power supply means at a constant level of constant voltage to provide the operating voltage of the microcomputer and the first constant voltage means It is achieved by including a second constant voltage means for stepping down a voltage in a predetermined step and changing the voltage input to the display driving means to a constant voltage by the stepped voltage, in detail based on the accompanying drawings of the present invention. The explanation is as follows.

4 is a power supply circuit diagram of the inventive dish dryer. As shown in FIG. 4, the user selects a desired stroke by pressing a function selection switch for washing, rinsing, drying, and various stroke states, and According to the function selection of the function selection input means 7, the microcomputer 1 for controlling the overall operation of the dish dryer and the input AC voltage AC are stepped down by the transformer 2a and the bridge diode 2b and the capacitor The power supply means 2 rectifying through C1 and the voltage output from the power supply means 2 are applied to the base of the transistor TR1 through the resistor R1 and the zener diode ZD1 for control. And the first constant voltage means 3 for smoothing through the capacitor C2 to input a constant voltage at a predetermined stage to the power terminal Vcc of the microcomputer 1, and the resistance R1 of the first constant voltage means 3. Output voltage of the power supply means (2) through the diode (D1) By the second constant voltage means 4 for reducing the transistor TR2 to a predetermined level, smoothing it through the capacitor C3, and outputting the constant voltage at a predetermined level, and the control voltage output from the microcomputer 1. Display driving means (5) consisting of resistors (R2) (R3) and transistors (TR3) and (TR4) for conducting and interrupting to control the output voltage of the second constant voltage means (4), and the control voltage of the microcomputer (1). And display means (6) made of a resistor (R4-R7) and a light emitting element (LED1-LED4) for conducting and blocking by the output voltage of the display driving means (5) to visually display the washing, rinsing, and drying operations. A load driving means (8) for controlling the blower and the heating body by driving by the control voltage of the microcomputer (1), a water temperature sensing means (9) for sensing the water temperature in the washing tank and inputting it to the microcomputer (1); The current source is supplied at the commercial frequency to recognize the point where the waveform crosses zero as a signal. An interrupt signal once per cycle and the interrupt generating means (10) for the input to the microcomputer (1), to reset the power-off the microcomputer (1) shall be composed of the initialization means 11 for stabilizing the operation of the dryer.

As described above, the operation and effects of the present invention constituted in detail are as follows.

When the power switch of the dish dryer is turned on, the input AC voltage AC is stepped down through the transformer 2a of the power supply means 2, and the stepped down voltage is rectified at the bridge diode 2b and smoothed through the capacitor C1. And then to the first constant voltage means 3 and the second constant voltage means 4.

The voltage output from the power supply means 2 drops through the resistor R1 of the first constant voltage means 3 and is applied to the base of the transistor TR1 as a zener voltage of the zener diode ZD1, and the transistor (R1) becomes conductive.

Accordingly, the voltage output from the power supply means 2 is smoothed through the transistor TR1 and the capacitor C2 by 0.7 volts lower than the zener voltage of the zener diode ZD1, and thus, the power terminal Vcc of the microcomputer 1. ) Is entered.

In addition, the voltage input to the base of the transistor TR1 is lowered by a 0.7 volt conduction voltage through the diode D1 of the second constant voltage means 4, and then is input to the base of the transistor TR2 to supply the transistor TR2. It becomes conductive.

Therefore, the voltage output from the power supply means 2 is higher than the output voltage of the first constant voltage means 3, that is, the voltage input to the power supply terminal Vcc of the microcomputer 1 by the conduction amount of the transistor TR2. 0.7 volts is inputted to the emitter of the transistors TR3 (TR4) which are smoothed through the above-described transistor TR2 and through the capacitor C3 and constituted in the display driving means 5.

At this time, when the user selects a desired stroke through the function selection input means 7, that is, a washing, rinsing and drying stroke, the microcomputer 1 conducts the light emitting elements (LED 1 -LED 4) of the corresponding display means 6. Will be displayed visually.

For example, in order to conduct the light emitting elements LED1-LED4 of the display means 6, the microcomputer 1 outputs a low potential to its output terminals A1 and A6, and the output terminal of the microcomputer 1. The low potential output from (A1) is applied to the base of the transistor TR3 of the display driving means 5 to conduct the transistor TR3.

When the transistor TR3 conducts, the output voltage of the second constant voltage means 4 conducts the light emitting elements LED1-LED4 of the display means 6 to display the corresponding stroke function.

As described above in detail, according to the present invention, after the transistor base voltage of the first constant voltage means is stepped down through a diode in a predetermined step, the output voltage of the second constant voltage means is also output in a predetermined step lower than the output voltage of the first constant voltage means. Therefore, under any voltage fluctuation, the operation of the display driving means is absolutely controlled only by the control voltage of the microcomputer, thereby preventing the uncontrollable state of the display means caused by the output voltage difference between the first and second constant voltage means. .

Claims (2)

A power supply means for stepping down the input AC voltage and changing the stepped voltage into a DC voltage, and outputting the voltage obtained from the power supply means by the Zener voltages of the resistor R1 and the zener diode ZD1. In the power supply circuit of the dish dryer comprising a first constant voltage means for inputting a constant voltage of a predetermined step into the microcomputer, step down the transistor (TR1) base voltage of the first constant voltage means in a predetermined step and the stepped voltage And a second constant voltage means for controlling the base of the transistor TR2 to provide a constant voltage at a predetermined level to the display drive means. 2. The power supply circuit of claim 1, wherein the base voltage of the first constant voltage means is stepped down by a diode and applied to the base of the transistor TR2.