KR20090087586A - Movement condition displaying device for ultrasonic cleaner - Google Patents

Abstract

A displaying device for the movement condition of an ultrasonic cleaner is provided to prevent ultrasonic oscillator from being damaged by the shortage of the washing water. A displaying device for the movement condition of an ultrasonic cleaner comprises an output transformer driving part(5), an ultrasonic oscillator(7), a current sensor(9A), a voltage sensor(9B), and a microcomputer(10). The output transformer driving part drives two switching transistors. The vibrator is driven by the output transformer driving part. The ultrasonic oscillator vibrates the washing water of a washing tub(8) with the ultrasonic wave. The current sensor and the voltage sensor respectively detect the current and voltage of the ultrasonic oscillator. The microcomputer detects and displays the short-circuit or the disconnection of the ultrasonic oscillator based on an output signal of the current sensor and the voltage sensor. The microcomputer detects and displays on a display unit the state of the load based on the impedance and phase change of the ultrasonic oscillator.

Description

MOVEMENT CONDITION DISPLAYING DEVICE FOR ULTRASONIC CLEANER}

The present invention relates to a technology for displaying a driving state of an ultrasonic cleaner, and more particularly, to a driving state display apparatus of an ultrasonic cleaner suitable for detecting and displaying what abnormality has occurred when an abnormality occurs in the ultrasonic cleaner.

The ultrasonic cleaner is a device for supplying AC power to the piezoelectric body to transmit 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 has recently been widely used for washing dishware as well as for washing various components in an industrial field.

When the ultrasonic cleaner is used, there is often a case in which it is impossible to operate normally, such as insufficient washing water, no washing water, or short circuit or disconnection of the ultrasonic vibrator. If left as it is, the ultrasonic cleaner is damaged and it is difficult to recover normally.

Nevertheless, the conventional ultrasonic cleaner is not equipped with a function to notify the user in a timely manner that normal operation is impossible such as insufficient washing water, no washing water, or short circuit or disconnection of the ultrasonic vibrator. Did. Due to this, there is a problem that the ultrasonic vibrator is broken due to lack of the washing water or the washing water, and a fire or a short circuit occurs due to short circuit or disconnection of the ultrasonic vibrator.

Accordingly, it is an object of the present invention to detect and display in a simple and inexpensive manner what is happening when an abnormality occurs in the ultrasonic cleaner.

The present invention for achieving the above object, the output transformer driving unit for driving two output transistors are alternately turned on the output transformer; An ultrasonic vibrator driven by the output voltage of the output transformer to generate ultrasonic waves to vibrate the washing water in the washing tank; A current sensor and a voltage sensor for respectively detecting the current / voltage of the ultrasonic vibrator; On the basis of the output signal of the current sensor and the voltage sensor, the state of short circuit or disconnection of the ultrasonic vibrator is detected and displayed on the display unit, and the state of washing water is insufficient or insufficient based on the impedance and phase change of the ultrasonic vibrator. To include a microcomputer displayed on the display unit.

The present invention detects the short-circuit or disconnection of the ultrasonic vibrator and the presence or absence of the wash water based on the current and voltage detection signal of the ultrasonic vibrator, the impedance and the phase change, and informs the user of the ultrasonic vibrator. Is prevented from being damaged, and a fire or an electric leakage is prevented from occurring due to a short circuit or disconnection of the ultrasonic vibrator.

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

1 is a block diagram showing an embodiment of a driving state display device of the ultrasonic cleaner according to the present invention, as shown in this, a voltage / frequency conversion oscillator (1) for oscillating a signal of a frequency corresponding to the input voltage Wow; An amplifier (2) for amplifying the oscillation signal output from the voltage / frequency conversion oscillator (1) to a predetermined level; An input transformer (3) for boosting the signal output from the amplifier (2); An amplifier (4) for amplifying the two signals input through the secondary coil of the input transformer (3) to a predetermined level; An output transformer driver 5 which turns on two switching transistors alternately by two gate signals output from the amplifier 4 to drive the output transformer 6; An ultrasonic vibrator 7 which is driven by an output voltage of the output transformer 6 to generate ultrasonic waves; A washing tank 8 in which a washing operation is performed by washing water vibrations generated by ultrasonic waves generated by the ultrasonic vibrator 7; A current sensor 9A for detecting a current of the ultrasonic vibrator 7, and a voltage sensor 9B for detecting a voltage of the ultrasonic vibrator; On the basis of the output signals of the current sensor 9A and the voltage sensor 9B, and the change of the impedance and phase of the ultrasonic vibrator 7, the wash water is insufficient or insufficient, and the state of the ultrasonic vibrator 7 is shorted or disconnected. It consists of the microcomputer 10 which detects and displays on the display part 11. As shown in FIG.

Referring to Figures 2 and 3 attached to the operation of the present invention configured as described above in detail as follows.

The voltage / frequency conversion oscillator 1 is a voltage controlled oscillator which generates and outputs a signal having a frequency corresponding to the input voltage.

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 two signals inputted through the secondary coil of the input transformer 3 to a predetermined level.

In the output transformer driver 5, the transistors T1 and T2 are alternately driven by two gate signals output from the amplifier 4, thereby driving the output transformer 6.

The ultrasonic vibrator 7 is driven by the output voltage of the output transformer 6 to generate ultrasonic waves, and the generated vibration 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 9A detects the current of the ultrasonic vibrator 7 and outputs the detection signal to the microcomputer 10, and the voltage sensor 9B detects the voltage of the ultrasonic vibrator 7 and detects the current. The signal is output to the microcomputer 10.

The microcomputer 10 is based on the output signals of the current sensor 9A and the voltage sensor 9B, and the short circuit, the disconnection state of the ultrasonic vibrator 7, and the wash water based on the impedance and the phase change of the ultrasonic vibrator 7. The presence or absence (load state and no load state) is detected and displayed on the display unit (for example, LCD) 11, which will be described in more detail as follows.

If the line of the ultrasonic vibrator 7 is not normally connected to both ends of the secondary coil of the output transformer 6 and is disconnected, no current is detected from the current sensor 9A. It becomes zero. Accordingly, the microcomputer 10 determines that the line of the ultrasonic vibrator 7 is disconnected when the level of the output signal of the current sensor 9A becomes zero, and the display unit 11 indicates "ultrasound oscillator disconnection". Display the contents.

When the line of the ultrasonic vibrator 7 is shorted, since the voltage is not detected by the voltage sensor 9B, its output signal level becomes zero. Therefore, when the level of the output signal of the voltage sensor 9B becomes zero, the microcomputer 10 judges that the line of the ultrasonic vibrator 7 is short-circuited, so that the display section 11 is called "ultrasound vibrator short circuit". Display the contents.

The phase comparator 10A of the microcomputer 10 detects the phase of the current and voltage of the ultrasonic vibrator 7 based on the output signals of the current sensor 9A and the voltage sensor 9B and outputs the voltage accordingly. do. The amplitude comparator 10B detects the amplitude of the current and voltage of the ultrasonic vibrator 7 based on the output signals of the current sensor 9A and the voltage sensor 9B, and outputs the voltage accordingly.

When the frequency generated by the ultrasonic vibrator 7 is higher or lower than the natural resonant frequency, the phase of the voltage and current of the ultrasonic vibrator 7 detected by the phase comparator 10A is ahead or behind the no-load reference phase. The amplitude of the voltage and current of the ultrasonic vibrator 7 detected by the amplitude comparator 10B becomes larger or smaller than the reference value at no load.

The microcomputer 10 controls the oscillation frequency of the voltage / frequency conversion oscillator 1 based on the output voltage of the phase comparator 10A to generate ultrasonic waves of a frequency targeted by the ultrasonic vibrator 7. Be sure to

In addition, the microcomputer 10 determines the no-load state and the load state based on the impedance and phase change of the ultrasonic vibrator 7 to display the contents of “no water” or “water lack” on the display unit 11. This principle is described in more detail with reference to FIG. 2 as follows.

Looking at the impedance characteristic graph (G1) of the ultrasonic vibrator 7 under load, the impedance recorded 700Ω at the frequency of 37Khz, slowly descended from it, recorded the lowest value 200Ω at the frequency of 37.33Khz, and then started to rise again. It records the highest 7KΩ at the frequency of 37.65Khz and starts to descend again, recording the highest 1KΩ at the frequency of 38Khz.

Looking at the phase characteristic graph G2 of the ultrasonic vibrator 7 under load, the lowest phase is recorded at -90 deg at the frequency of 37 kHz, and then rises in the S-shape to record the highest phase 40 deg at the frequency of 37.45 kHz. It begins to descend to S-shape again and records the lowest phase -90deg at the frequency of 40Khz.

Therefore, the microcomputer 10 has the information of the characteristic graphs G1 and G2 in the internal memory, and then detects the graphs G1 and G2 at predetermined intervals and stores the information similar to those stored in the memory. If it is found that it is determined that the washing water in the washing tank (8), that is, the load is currently loaded, and displays the contents (for example, the load state) on the display.

Looking at the impedance characteristic graph (G3) of the ultrasonic vibrator (7) at no load, the impedance recorded 700Ω at the frequency of 37Khz, and slowly dropped therefrom, and then the resonant frequency of the ultrasonic vibrator (f _o = 37.44Khz) After falling sharply in the vicinity of the record the lowest value 10Ω, it starts to rise sharply again and records the highest 12KΩ at the frequency of 37.72Khz, and begins to fall slowly again to record the highest 1KΩ at the frequency of 38Khz.

Looking at the phase characteristic graph G4 of the ultrasonic vibrator 7 at no load, the lowest phase of -90 deg is recorded at the frequency of 37 kHz, and it is continuously maintained, and is rapidly increased in the vicinity of the resonance frequency f _o to obtain the highest phase of 70 deg. After recording, it maintains its highest phase and then drops rapidly to the lowest phase of -90deg at the frequency of 37.72Khz.

Therefore, after the microcomputer 10 has the information of the characteristic graphs G3 and G4 in the internal memory, the microcomputer 10 detects the graphs G3 and G4 at predetermined intervals and is similar to that stored in the memory. If it is determined that the current is not contained in the washing tank (8), that is, it is determined as a no-load state and displays the contents (eg no-load state) on the display.

As another method of determining the load state or the no-load state in the microcomputer 10, the impedance of the ultrasonic vibrator 7 in the region of the resonance frequency f _o = 37.44Khz is detected and is equal to or less than a predetermined value. There is a method of judging the state and determining the load state if it is more than a predetermined value.

There may be a number of methods for allowing the microcomputer 10 to recognize the impedance of the ultrasonic vibrator 7. In this embodiment, the impedance of the ultrasonic vibrator 7 is detected and the voltage is output accordingly. An impedance detection part is mentioned.

1 is a block diagram of a driving state display device of the ultrasonic cleaner according to the present invention.

Figure 2 is a graph of the impedance and phase change characteristics of the ultrasonic oscillator.

Figure 3 is a schematic diagram showing a load / no load state of the washing tank in Figure 1;

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

1: voltage / frequency conversion oscillator, 2,4: amplifier

3: input transformer, 5: output transformer drive unit

6: output transformer, 7: ultrasonic vibrator

8: washing tank, 9A: current sensor

9B: voltage sensor, 10: microcomputer

10A: phase comparator, 10B: amplitude comparator

CH: resonant coil

Claims (6)

An output transformer driver configured to alternately turn on two switching transistors to drive an output transformer; An ultrasonic vibrator driven by the output voltage of the output transformer to generate ultrasonic waves to vibrate the washing water in the washing tank; A current sensor and a voltage sensor for respectively detecting the current / voltage of the ultrasonic vibrator; Based on the output signals of the current sensor and the voltage sensor, the short circuit or disconnection of the ultrasonic vibrator is detected and displayed on the display, and the load state or the no load state is detected based on the impedance and phase change of the ultrasonic vibrator. The driving state display device of the ultrasonic cleaner comprising a microcomputer to display on the display unit. The method of claim 1, Output transformer drive is provided at the front end A voltage / frequency conversion oscillator for oscillating a signal having a frequency corresponding to the input voltage; A first amplifier for amplifying the oscillation signal output from the voltage / frequency conversion oscillator to a predetermined level; An input transformer for boosting the signal output from the first amplifier; And a second amplifier for amplifying two signals input through the secondary coil of the input transformer to a predetermined level. The method of claim 1, The microcomputer determines that the line of the ultrasonic vibrator is disconnected when the level of the output signal of the current sensor becomes zero, and displays the content of "ultrasound vibrator disconnection" on the display unit. Status display. The method of claim 1, The microcomputer determines that the line of the ultrasonic vibrator is short-circuited when the level of the output signal of the voltage sensor becomes zero, and displays the content of "ultrasound vibrator short circuit" on the display unit. Status display. The method of claim 1, The microcomputer is configured to determine that the ultrasonic vibrator in the resonant frequency range of the ultrasonic vibrator is a no load state if the ultrasonic vibrator is less than a predetermined value, and to determine the load state if the ultrasonic vibrator is more than a predetermined value. The method of claim 1, A load state is a state in which the amount of washing water is sufficient in the washing tank, and a no load state is a state in which the washing water is insufficient or no washing state in the washing tank.

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