Method and apparatus for driving piezoelectric transformer
First Claim
1. A driving method of a piezoelectric transformer, comprising steps of:
- controlling the piezoelectric transformer by switching an amplitude of the driving waveform into a small amplitude and driving said piezoelectric transformer at a driving frequency less than a natural frequency, when the driving frequency reaches a natural frequency at which the driving waveform becomes a non-zero voltage switching state or becomes a waveform superimposed with higher harmonic wave, while the driving waveform is increased within a frequency range which is higher than the resonance frequency;
controlling the piezoelectric transformer by switching the amplitude of the driving waveform into a large amplitude and driving the piezoelectric transformer at a driving frequency higher than the natural frequency when the driving frequency reaches a predetermined frequency near the resonance frequency, while driving the piezoelectric transformer at the small amplitude and driving the piezoelectric transformer at higher frequency than the resonance frequency;
wherein, when the source voltage is fixed, the output voltage at the time of switching the amplitude of the driving wave into the small amplitude is lower than the output voltage at the time of switching the amplitude of the waveform into the large amplitude.
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Abstract
A combination of two control methods are used, one of which is a method to control the boosting ratio of the piezoelectric transformer and another is a method to control the driving waveform of the piezoelectric transformer. The threshold values for switching the control methods are set with a hysteresis characteristic in order to avoid instability in the driving frequency at the time of switching and also to avoid driving at a natural frequency. When the source voltage is fixed, the driving frequency is increased by changing the resistance of the detection resistor 16 until the driving frequency reaches the natural frequency causing problems. When the driving frequency reaches the natural frequency, the power supply to the driving circuit is reduced to reduce the amplitude of the driving wave for reducing the driving frequency without changing the output voltage. At this state when the amplitude is small, the minimum output voltage is obtained by increasing the driving frequency to the natural frequency. This method and apparatus provide a wider range of output voltages and reliable output characteristics of the piezoelectric transformer.
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Citations
9 Claims
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1. A driving method of a piezoelectric transformer, comprising steps of:
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controlling the piezoelectric transformer by switching an amplitude of the driving waveform into a small amplitude and driving said piezoelectric transformer at a driving frequency less than a natural frequency, when the driving frequency reaches a natural frequency at which the driving waveform becomes a non-zero voltage switching state or becomes a waveform superimposed with higher harmonic wave, while the driving waveform is increased within a frequency range which is higher than the resonance frequency; controlling the piezoelectric transformer by switching the amplitude of the driving waveform into a large amplitude and driving the piezoelectric transformer at a driving frequency higher than the natural frequency when the driving frequency reaches a predetermined frequency near the resonance frequency, while driving the piezoelectric transformer at the small amplitude and driving the piezoelectric transformer at higher frequency than the resonance frequency; wherein, when the source voltage is fixed, the output voltage at the time of switching the amplitude of the driving wave into the small amplitude is lower than the output voltage at the time of switching the amplitude of the waveform into the large amplitude.
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2. A driving method of a piezoelectric transformer, comprising steps of:
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controlling the piezoelectric transformer by switching an amplitude of the driving waveform into a small amplitude and driving said piezoelectric transformer at a driving frequency less than a natural frequency, when the driving frequency reaches the proper driving frequency at which the driving waveform becomes a non-zero voltage switching state or becomes a waveform superimposed with higher harmonic wave, while the driving waveform is increased within a frequency range which is higher than the resonance frequency; controlling the piezoelectric transformer by switching the amplitude of the driving waveform into a large amplitude and driving the piezoelectric transformer at an driving frequency higher than the proper driving frequency when the driving frequency reaches a predetermined frequency near the resonance frequency, while driving the piezoelectric transformer at the small amplitude and driving the piezoelectric transformer at higher frequency than the resonance frequency; wherein, when the output voltage is fixed, the source voltage at the time of switching the amplitude of the driving wave into the small amplitude is higher than the source voltage at the time of switching the amplitude of the waveform into the large amplitude.
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3. A driving apparatus of a piezoelectric transformer comprises:
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a driving circuit for applying the driving waveform similar to a sine wave to the input portion of the piezoelectric transformer; a switching element connected with both input terminals of the piezoelectric transformer and a DC power source; a rectifying smoothing circuit for rectifying and smoothing the output signal from the piezoelectric transformer and for applying thereof to the load; a fixed impedance circuit, one end of which is connected to the output terminal of the piezoelectric transformer; a detection resistor connected to the other end of the fixed impedance circuit; a output voltage detection circuit for detecting voltage at both ends of the detection resistor; a control signal generator for generating a control voltage and a control current in response to the detected voltage detected by the output voltage detection circuit; a current control oscillator which oscillates at a frequency corresponding to the control current; a drive control signal generating means for receiving an oscillating signal, for generating a drive control waveform to supply to the driving circuit, and for generating a driving waveform; a control circuit for generating a signal for controlling a switching element at an duty ratio of the signal generated by receiving the oscillating signal from the current control signal; a hysteresis comparison means for comparing a standard voltage which is converted from the natural frequency at which the driving waveform turns to a zero voltage switching waveform or turns to a waveform superimposed with higher harmonic waves with the output signal of said control circuit, and for converting a duty-ratio of the output signal of the control circuit into a predetermined value of 100% or less than 100% based on the result of the comparison. - View Dependent Claims (4, 7, 8)
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5. An apparatus for driving the piezoelectric transformer comprises:
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a driving circuit which has a boosting type voltage resonance circuit including an input portion of the piezoelectric transformer and which inputs -a driving wave which is similar to a sine wave to the input portion of the piezoelectric transformer; a switching element connected in between the input terminal of said driving circuit and a DC power source; a rectifying smoothing circuit for rectifying and smoothing the output signal from the piezoelectric transformer and for application thereof to the load; a fixed impedance circuit one end of which is connected to the output terminal of said piezoelectric transformer; a detection resistor connected to the other end of the fixed impedance circuit; an output voltage detection circuit for detecting voltage at both ends of the detection resistor; a control signal generator for generating a control voltage and a control current in response to the detected voltage detected by the output voltage detection circuit; a current control oscillator which oscillates at a frequency corresponding to the control current; a drive control signal generating means for receiving an oscillating signal, for generating a drive control waveform to supply to the driving circuit, and for generating a driving waveform; a temperature detecting element physically attached to said switching transistors in the driving circuit; a control circuit for generating a signal for controlling a switching element at a duty ratio of the signal generated by receiving the oscillating signal from the current control signal; a hysteresis comparison means for comparing a standard voltage which is converted from the natural frequency at which the driving waveform turns into a zero voltage switching waveform or turns into a waveform superimposed with higher harmonic waves with the output signal of said control circuit, and for converting a duty-ratio of the output signal of the control circuit into a predetermined value of 100% or less than 100% based on the result of the comparison. - View Dependent Claims (6, 9)
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Specification