High voltage pulsed power supply using solid state switches with voltage cell isolation
First Claim
1. A pulse generator that generates a voltage pulse, the pulse generator comprising:
- a plurality of first voltage cells, each voltage cell having a capacitor in series with a main switch such that all capacitors are connected in series when all main switches are on to generate a voltage pulse that is delivered to a load;
a plurality of return switches, each return switch associated with a voltage cell, wherein the return switches enable each capacitor in the plurality of voltage cells to charge while each main switch is in an off state;
an isolation diode associated with each return switch, wherein the isolation diode provides a path for the voltage pulse when a corresponding voltage cell is inoperative, anda second voltage cell connected in series with the plurality of voltage cells, the second voltage cell including;
a pair of capacitors in series with a second main switch;
at least one diode arranged with the pair of capacitors such that the pair of capacitors charge in series when the second main switch is off and discharge in parallel when the second main switch is on; and
a ringing circuit that includes;
an inductor in series with the pair of capacitors; and
a ringing capacitor in parallel with the inductor, wherein the ringing capacitor charges to twice a value of the pair of capacitors and provides droop compensation to the voltage pulse.
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Accused Products
Abstract
Systems and methods for generating a high voltage pulse. A series of voltage cells are connected such that charging capacitors can be charged in parallel and discharged in series. Each cell includes a main switch and a return switch. When the main switches are turned on, the capacitors in the cells are in series and discharge. When the main switches are turned off and the return switches are turned on, the capacitors charge in parallel. One or more of the cells can be inactive without preventing a pulse from being generated. The amplitude, duration, rise time, and fall time can be controlled with the voltage cells. Each voltage cell may also include a balance network to match the stray capacitance seen by each voltage cell. Droop compensation is also enabled. Isolation diodes ensure that a discharge current can bypass inoperable voltage cells.
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Citations
16 Claims
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1. A pulse generator that generates a voltage pulse, the pulse generator comprising:
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a plurality of first voltage cells, each voltage cell having a capacitor in series with a main switch such that all capacitors are connected in series when all main switches are on to generate a voltage pulse that is delivered to a load; a plurality of return switches, each return switch associated with a voltage cell, wherein the return switches enable each capacitor in the plurality of voltage cells to charge while each main switch is in an off state; an isolation diode associated with each return switch, wherein the isolation diode provides a path for the voltage pulse when a corresponding voltage cell is inoperative, and a second voltage cell connected in series with the plurality of voltage cells, the second voltage cell including; a pair of capacitors in series with a second main switch; at least one diode arranged with the pair of capacitors such that the pair of capacitors charge in series when the second main switch is off and discharge in parallel when the second main switch is on; and a ringing circuit that includes; an inductor in series with the pair of capacitors; and a ringing capacitor in parallel with the inductor, wherein the ringing capacitor charges to twice a value of the pair of capacitors and provides droop compensation to the voltage pulse. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
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10. A pulse generator that generates a voltage pulse that is applied to a load, the pulse generator comprising:
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a plurality of voltage cells connected in series, each voltage cell comprising; a first capacitor; a second capacitor; a main switch in series with the first and second capacitors; a first diode connected between the first and second capacitor, wherein a charging current charges the first and second capacitor in series; a return switch that provides a return path for current that charges the first and second capacitors when the main switch is off; a plurality of diodes arranged with the first and second capacitors such that the first and second capacitors charge in series when the main switch is off and discharge in parallel when the main switch is on; an isolation diode connected across the return switch, wherein the isolation diode provides a discharge path for a discharge current of a voltage pulse when the voltage cell is defective such that the voltage pulse is delivered to the load; and
a ringing circuit that includes;an inductor in series with the first and second capacitors; and a ringing capacitor in parallel with the inductor, wherein the ringing capacitor charges to twice a value of the first and second capacitors and provides droop compensation to the voltage pulse; wherein capacitors in the plurality of voltage cells are connected in series when the main switches are on and, when the main switches are on and the capacitors are connected in series and are discharging to the load, the isolation diodes enable delivery of the voltage pulse by providing the discharge path around defective voltage cells. - View Dependent Claims (11, 12, 13, 14)
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15. A voltage pulse generator for generating a voltage pulse, the voltage pulse generator comprising:
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a plurality of first voltage cells each having a main switch and a capacitor in series such that each main switch and each capacitor is in series with other main switches and other capacitors in other first voltage cells when the main switches are on, wherein the capacitors are isolated from each other until the main switches are turned on such that the serially connected capacitors deliver a voltage pulse without using transformers; a diode string connected with the plurality of first voltage cells; a plurality of first return switches included in the plurality of first voltage cells, wherein a charging current passes through the first return switches and the diode string such that the capacitors in the plurality of first voltage cells are charged in parallel; a plurality of isolation diodes, each isolation diode connected with a particular return switch such that a discharge path is provided for a discharge current when a corresponding voltage cell is inoperative and that prevents discharge of the corresponding capacitor of the corresponding voltage cell during normal operation; and a second voltage cell comprising; a second main switch; at least a pair of capacitors in series with the main switch and connected using a plurality of diodes such that the pair of capacitors charge in series and such that the pair of capacitors charge in parallel with respect to the capacitors in the plurality of first voltage cells, wherein the plurality of diodes are arranged such that the pair of capacitors discharge in parallel when the second main switch is on; and a ringing circuit connected to the pair of capacitors, wherein the ringing circuit rings when the pair of capacitors discharge to generate a half sine wave voltage that provides droop compensation to the voltage pulse, the ringing circuit including an inductor in series with the pair of capacitors and a third capacitor across the pair of capacitors. - View Dependent Claims (16)
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Specification