KR100972085B1 - Method for suppling maximum efficiency power of ultrasonic cleaner - Google Patents

Abstract

PURPOSE: A maximum efficiency power supply system of a ultrasonic cleaner is provided to supply the maximum efficiency power by using a frequency of an area where the voltage and the current intersect near the resonant frequency. CONSTITUTION: A first process is to measure a usable frequency domain according to the model of the ultrasonic oscillator(S1). The first process sets the number of usable frequencies(S2). A second process clinches for each frequency band by using the winding ratio of the output transformer and tap of the resonant coil(S4). A third process is to find and fix the maximum efficient power frequency(S5).

Description

Maximum efficient power supply method of ultrasonic cleaner {METHOD FOR SUPPLING MAXIMUM EFFICIENCY POWER OF ULTRASONIC CLEANER}

The present invention relates to a power supply technology of the ultrasonic cleaner, in particular, the maximum efficiency power supply of the ultrasonic cleaner to supply the maximum efficiency power by using the frequency of the region where the voltage and current intersect before and after the resonant frequency in a single vibration device It is about a method.

The ultrasonic cleaner is a device for supplying ultrasonic waves to the piezoelectric body to transfer the vibration generated therefrom to the washing water, and to vibrate the surface of the material to be cleaned by the vibration of the washing water to perform the washing operation.

Such an ultrasonic cleaner is in a situation where it is widely used for washing various dishes in an industrial field as well as washing dishware for a kitchen.

The ultrasonic cleaner largely comprises a washing tank, an ultrasonic vibrator and an oscillator. The oscillator outputs a drive signal of the ultrasonic vibrator based on a drive signal and a control signal for driving the system of the ultrasonic cleaner. The ultrasonic vibrator generates ultrasonic waves in accordance with the oscillator driving signal supplied from the oscillator, and the object to be cleaned is cleaned by the ultrasonic waves thus generated.

Figure 1 shows the frequency used in the vibrator of the conventional ultrasonic cleaner. That is, the maximum difference between the current I and the voltage V supplied to the ultrasonic vibrator at the frequency 20 KHz is the maximum, which is the series resonant frequency of the ultrasonic vibrating element. Thereafter, the difference between the current I and the voltage V at the frequency (about 22.8 KHz) is minimized. Thereafter, the difference between the current I and the voltage V becomes maximum again at the frequency 25 KHz, which is the parallel resonant frequency of the ultrasonic vibration device.

However, in the conventional ultrasonic cleaner, the ultrasonic vibrator is driven using a series resonance frequency or a parallel resonance frequency in which the difference between the current and the voltage supplied to the ultrasonic vibrator is maximized.

As a result, a large amount of heat is generated in the oscillation circuit or the ultrasonic vibrating element, and moreover, the power efficiency is low.

Accordingly, an object of the present invention is to supply the power of maximum efficiency by using the frequency of the region where the voltage and current intersect before and after the resonance frequency in a single vibration device of the ultrasonic cleaner.

The objects of the present invention are not limited to the above-mentioned objects. Other objects and advantages of the invention will be more clearly understood by the following description.

The present invention for achieving the above object,

A first step of measuring a frequency domain usable for each model of the ultrasonic vibrator of the ultrasonic cleaner and setting the number of frequencies usable in the frequency domain;

A second step of setting the usable frequency bands and fixing the frequency bands by using the winding ratio of the output transformer and the tap of the resonance coil;

I / O power is measured for each of the usable frequency bands to find and fix the maximum efficiency power frequency, and the voltage and current supplied to the ultrasonic vibrator are equalized based on the output values of the current sensor and the voltage sensor. And a third process of tracking and setting the frequency of the maximum efficiency power based on the adjusted voltage current ratio.

In the present invention, when supplying power to a single vibrating element of the ultrasonic cleaner, by supplying the maximum efficiency power by using the frequency of the region where the voltage and current intersect before and after the resonance frequency, there is an effect that can achieve a power saving effect.

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

FIG. 2 is a block diagram of an ultrasonic cleaner to which the maximum efficiency power supply method of the present invention is applied. As shown in FIG. 2, a voltage-frequency conversion oscillator 1, an amplifier 2, an input transformer 3, an amplifier, an output transformer (5), a resonant coil 6, an ultrasonic vibrator 7, a washing tank 8, a current sensor 9, a voltage sensor 10, a microcomputer 11, and a display portion 12.

The voltage-frequency conversion oscillator 1 generates and outputs a signal having a frequency corresponding to the pulse width modulated signal input from the microcomputer 11 as the voltage-controlled oscillator.

The amplifier 2 amplifies and outputs the oscillation signal output from the voltage-frequency conversion oscillator 1 to a predetermined level, and the input transformer 3 is driven by the output signal.

The amplifier 4 amplifies and outputs the signal input through the secondary coil of the input transformer 3 to a predetermined level.

The output transformer 5 is driven by the output signal of the amplifier 4, and its output voltage is supplied to the ultrasonic vibrator 7 through the resonant coil 6.

The ultrasonic vibrator 7 is driven by the output voltage of the output transformer 5 to generate ultrasonic waves, and the vibration generated in this way is transmitted to the washing water in the washing tank 8. Then, the washing water vibration in the washing tank (8) vibrates the surface of the material to be washed to perform the washing action.

The current sensor 9 detects the current of the ultrasonic vibrator 7 and outputs the detected signal to the amplitude comparator 11A of the microcomputer 11, and the voltage sensor 10 is the voltage of the ultrasonic vibrator 7. Is detected and the detected signal is output to the amplitude comparator 11A.

The microcomputer 11 controls the oscillation frequency of the voltage-frequency conversion oscillator 1 based on the output signal of the amplitude comparator 11A.

Meanwhile, the technical contents of the present invention for outputting the maximum power relative to the input power from the ultrasonic vibrator 7 will be described in detail.

In the production process of the ultrasonic cleaner, a frequency range (for example, 20 to 175 kHz) usable for each model of the ultrasonic vibrator 7 is measured at one time. At this time, the usable frequency range of the ultrasonic vibrator 7 may be measured using an impedance analyzer, measuring a resistance curve with respect to frequency, or using a frequency oscillator and an oscilloscope (S1).

Then, the number of frequencies available in the usable frequency range is set. In general, although there are differences between the ultrasonic vibrators 7, there are 3 to 8 usable frequencies. In this embodiment, 1 to 4 are used. (S2)

Subsequently, the usable frequency bands (eg, 20-30 KHz, 50-55 KHz, 70-76 KHz, 110-120 KHz, ...) are set.

The set usable frequency band is fixed. To this end, the winding ratio of the output transformer 5 is adjusted, and a corresponding tap is selected from the taps of the resonant coil 6 using a plurality of relay switches 6A.

Subsequently, the input / output power is measured for each of the usable frequency bands using a power meter to find and fix the frequency of the maximum efficiency power, and then the variable resistor VR1 connected between the current sensor 9 and the output terminal of the voltage sensor 10. If the ratio of voltage and current at the output stage is adjusted to be the same, the microcomputer 11 tracks and sets the frequency of the maximum efficiency power based on the adjusted ratio of voltage and current at normal operation. S7)

That is, the amplitude comparator 11A of the microcomputer 11 compares the output value (amplitude) of the current sensor 9 with the output value (amplitude) of the voltage sensor 10, and when the output value of the voltage sensor 10 is small. The light emitting diode LED1 is turned on and the light emitting diode LED2 is turned off. At this time, the user adjusts the variable resistor VR1 so that the output value of the voltage sensor 10 is increased, and correspondingly, the microcomputer 11 supplies a pulse width modulation signal supplied to the voltage-frequency conversion oscillator 1. The frequency supplied to the ultrasonic vibrator 7 is increased by increasing the duty ratio.

On the contrary, when the output value of the voltage sensor 10 is larger, the light emitting diode LED2 is turned on and the light emitting diode LED1 is turned off. At this time, the user adjusts the variable resistor VR1 to increase the output value of the current sensor 9, and in response thereto, the microcomputer 11 supplies the pulse width modulation supplied to the voltage-frequency conversion oscillator 1; By reducing the duty ratio of the signal, the frequency supplied to the ultrasonic vibrator 7 is reduced.

Through this adjustment process, when the output value of the current sensor 9 and the output value of the voltage sensor 10 are equal to each other, the amplitude comparator 11A of the microcomputer 11 stops further adjustment operation, and the two light emission Turn on both diodes LED1 and LED2. The microcomputer 11 stores the duty ratio at this time, and outputs a pulse width modulation signal of the duty ratio after shipment of the product. Accordingly, a frequency with a current-to-voltage ratio of 1: 1 is supplied from the ultrasonic vibrator 7 so that the maximum efficiency power appears.

(A)-(c) of FIG. 3 show an example of finding a frequency with a current-to-voltage ratio of 1: 1 so that the maximum efficiency power appears through the above process. In other words, (a)-(c) of FIG. 3 is a frequency at which the voltage curve and the current curve cross each other, but FIG. 3 (a) shows that the current-to-voltage ratio is adjusted to 1: 1 so that maximum efficiency power appears. After the frequency 22.5KHz, Figure 3 (b) shows a frequency of 21.5KHz with a voltage-to-current ratio of 1: 0.5 means that the frequency must be slightly increased in order for the maximum efficiency power to appear. 3 (c) shows a frequency of 23.5KHz with a ratio of voltage to current of 0.5: 1, which means that the frequency must be lowered slightly in order for maximum efficiency power to appear.

Thereafter, the microcomputer 11 sets a range of the maximum allowable output and ends the series of maximum efficiency power setting processes as described above.

As a result, the present invention tracks the frequency in consideration of the existence of a frequency providing the maximum efficiency power around the series and parallel resonant points, and the current sensor 9 and the voltage sensor of the ultrasonic vibrator 7 as described above. The variable resistor VR1 connected between the output terminals of (10) is used to adjust the ratio of voltage and current at the output stage to be the same, and then the microcomputer 11 causes the ratio of the adjusted voltage and current to be adjusted in normal operation. Based on this, the frequency of maximum efficiency power is tracked and set. In addition, since the peripheral frequency of the series-parallel frequency is used, several frequencies may be selectively used.

Although the preferred embodiment of the present invention has been described in detail above, the scope of the present invention is not limited thereto, and may be implemented in various embodiments based on the basic concept of the present invention defined in the following claims. Such embodiments are also within the scope of the present invention.

1 is a waveform diagram of a frequency used in the vibrator of the conventional ultrasonic cleaner.

Figure 2 is a block diagram of the ultrasonic cleaner to which the maximum power supply method of the present invention is applied.

Figure 3 (a)-(c) is a waveform diagram showing the current-to-voltage ratio in the frequency domain where the voltage and current intersect according to the present invention.

4 is a control flowchart of the method for supplying the maximum efficiency power of the ultrasonic cleaner according to the present invention.

*** Description of the symbols for the main parts of the drawings ***

1: Voltage frequency conversion type oscillator

2,4 amplifier

3: input transformer

5: output transformer

6: resonant coil

7: ultrasonic vibrator

8: washing tank

9: current sensor

10: voltage sensor

11: microcomputer

11A: Amplitude Comparator

12: display unit

Claims (6)

A first step of measuring a frequency domain usable for each model of the ultrasonic vibrator of the ultrasonic cleaner and setting the number of frequencies usable in the frequency domain; A second step of setting the usable frequency bands and fixing the frequency bands by using the winding ratio of the output transformer and the tap of the resonance coil; Measuring the input and output power for each of the available frequency bands to find and fix the frequency of the maximum efficiency power, supply the output voltage of the current sensor and the voltage sensor to both terminals of the variable resistor and the intermediate ground point of the variable resistor by the user's adjustment After adjusting the amplitude ratio of the voltage and current supplied to the ultrasonic vibrator on the basis of the terminal voltage of both sides of the variable resistor which changes as it is moved, the maximum efficiency power based on the adjusted voltage current ratio during normal operation. And a third process of tracking and setting the frequency of the ultrasonic wave cleaner. The method of claim 1, wherein the first process uses an impedance analyzer, measures a resistance curve relative to frequency, or measures the usable frequency range using a frequency oscillator and an oscilloscope. Way. The method of claim 1, wherein the first process sets the number of usable frequencies to 1 to 4. The method of claim 1, wherein the third process includes allowing a user to adjust a ratio of output values of the current sensor and the voltage sensor using a variable resistor, and controlling a frequency supplied to the ultrasonic vibrator according to the adjustment value. Maximum efficiency power supply method of the ultrasonic cleaner, characterized in that made by. The ultrasonic cleaner according to claim 4, further comprising: lighting a light emitting diode having a larger output value of the current sensor and a voltage sensor, and lighting both light emitting diodes when their values are the same. Power supply method. 3. The third process of claim 1, wherein the microcomputer detects a change in the ratio between the output values of the current sensor and the voltage sensor, and outputs the pulse width modulator provided in the microcomputer when the output value of the voltage sensor is smaller than the output value of the current sensor. Changing the duty ratio of the pulse width modulation signal supplied to the voltage / frequency conversion oscillator in such a manner as to increase the duty ratio by changing the pulse width modulation signal PWM so that the frequency supplied to the ultrasonic vibrator is adjusted. Maximum efficiency power supply method of the ultrasonic cleaner comprising a.

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