초록 ▼

In a method and a device according to the present invention, two piezo-elements of a piezo-electric actuator are driven with two voltages having a mutual phase difference. One of said piezo-elements is charged by a capacitive voltage step-up means to a voltage exceeding an available power supply vol

In a method and a device according to the present invention, two piezo-elements of a piezo-electric actuator are driven with two voltages having a mutual phase difference. One of said piezo-elements is charged by a capacitive voltage step-up means to a voltage exceeding an available power supply voltage. A capacitor is coupled to the piezo-element, which divides the voltage of the piezo-element and simultaneously transfers part of the energy stored in the piezo-element to said capacitor. A part of the energy transferred to said capacitor is later transferred back to said piezo-element, providing an energy-saving feature. The second piezo-element is driven in a similar way providing the required phase difference. In a further embodiment, the waveforms of the two driving signals are corrected using balancing capacitors.

대표청구항 ▼

The invention claimed is: 1. An apparatus comprising two piezo-element driving units, each of the two piezo-element driving units comprising at least: an output connectable to a piezo-element, a voltage step-up module having a node wherein a voltage of said node is adapted to be an alternating volt

The invention claimed is: 1. An apparatus comprising two piezo-element driving units, each of the two piezo-element driving units comprising at least: an output connectable to a piezo-element, a voltage step-up module having a node wherein a voltage of said node is adapted to be an alternating voltage whose maximum is higher than a voltage of a power supply, a first switch to connect said output to said node for charging said piezo-element, at least one capacitor, and a second switch to connect said at least one capacitor to said output, said at least one capacitor being adapted to be disconnected from said node during said charging, and said second switch being adapted to transfer charge from said piezo-element to said at least one capacitor and back from said at least one capacitor to said piezo-element such that said at least one capacitor is disconnected from said voltage step-up module during the charge transfer in both directions; wherein the outputs of the two piezo-element driving units are in different phases. 2. The apparatus according to claim 1, wherein each of said piezo-element driving units is optimized to drive a piezo-element with a predetermined nominal internal capacitance, and the capacitance of at least one of said at least one capacitor is substantially equal to said predetermined nominal internal capacitance of said piezo-element. 3. The apparatus according to claim 1, each of the piezo-element driving units comprising: a control module configured to receive a direction command signal; a balancing capacitor and a switch to connect/disconnect said balancing capacitor to/from said output depending on said direction command signal. 4. The apparatus according to claim 1, wherein the voltage of said node of said voltage step-up module is arranged to alternate substantially in the voltage range VS to two times VS wherein VS is a primary power supply voltage. 5. The apparatus according to claim 1, wherein said voltage step-up module is implemented using a field-effect transistor. 6. The apparatus according to claim 5, wherein a further voltage step-up module is arranged to provide a driving signal for said field-effect transistor. 7. A piezo-element driving device comprising at least two piezo-element driving units, said at least two units being controlled by a common control unit and powered by a common power supply, each of said piezo-element driving units comprising at least: an output connectable to a piezo-element, a voltage step-up module having a node, wherein the voltage of said node is adapted to be an alternating voltage whose maximum is higher than a voltage of a power supply, a first switch to connect said output to said node for charging said piezo-element, at least one capacitor, and a second switch to connect said at least one capacitor to said output, said at least one capacitor being adapted to be disconnected from said node during said charging, and said second switch being adapted to transfer charge from said piezo-element to said at least one capacitor and back from said at least one capacitor to said piezo-element such that said at least one capacitor is disconnected from said voltage step-up module during the charge transfer in the both directions; wherein the outputs of the two piezo-element driving units are in different phases. 8. A method comprising: driving two piezo-elements with respective driving units and performing with each driving unit a process comprising: charging a piezo-element using a voltage step-up module having a node, wherein a voltage of said node is adapted to be an alternating voltage whose maximum is higher than a voltage of a power supply, and wherein at least one capacitor is disconnected from said node during said charging, transferring charge from said piezo-element to said at least one capacitor, said at least one capacitor being disconnected from said node during the charge transfer, and transferring charge back from said at least one capacitor to said piezo-element, said at least one capacitor being disconnected from said node during the charge transfers, wherein the piezo-elements are driving in different phases. 9. The method according to claim 8, wherein the capacitance of at least one of said at least one capacitor is selected to be substantially equal to the nominal internal capacitance of said piezo-element. 10. The method according to claim 8, wherein a balancing capacitor is connected/disconnected to/from said piezo-element depending on a direction command signal. 11. The method according to claim 8, wherein the voltage of said voltage step-up module alternates substantially in the voltage range VS to two times VS wherein VS is a primary power supply voltage. 12. The method according to claim 8, wherein said voltage step-up module is implemented using a field-effect transistor. 13. The method according to claim 12, wherein a driving signal for said field-effect transistor is provided by a further voltage step-up module. 14. The method according to claim 8, wherein two piezo-elements are driven with two output voltages in such a way, that there is a mutual phase difference between said two output voltages. 15. A device comprising at least: two piezo-elements, and respective piezo-element driving units for each of the two piezo-elements, each piezo-element driving unit comprising: a voltage step-up module having a node, wherein a voltage of said node is adapted to be an alternating voltage whose maximum is higher than a voltage of a power supply, a first switch to connect said node to said piezo-element for charging said piezo-element, at least one capacitor, and a second switch to connect said at least one capacitor to said piezo-element, said at least one capacitor being adapted to be disconnected from said node during said charging, said second switch being adapted to transfer charge from said piezo-element to said at least one capacitor and back from said at least one capacitor to said piezo-element such that said at least one capacitor is disconnected from said voltage step-up module during the charge transfer in the both directions; wherein the node of one of the piezo-element driving units is in different phase than the node of the other of the piezo-element driving units. 16. The device according to claim 15, wherein said device comprises at least one piezo-electric actuator, wherein said actuator comprises at least two bimorphs. 17. The device according to claim 15, wherein said device is a mobile device. 18. The device according to claim 15, wherein said piezo-element is arranged to adjust the position of a focusing or zoom lens system.