| CPC B02C 19/18 (2013.01) [H02M 7/06 (2013.01); H03K 17/567 (2013.01); B02C 2019/183 (2013.01); H01T 14/00 (2013.01)] | 21 Claims |
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1. An electric pulse fragmentation device comprising:
A step up transformer, a high-voltage pulse transformer, a voltage rectifier, one or more buffer capacitors, a plurality of insulated-gate bipolar transistor (IGBT) modules, a storage capacitor, a spark gap, and a fragmentation chamber, the spark gap being defined by a spark gap first electrode and a spark gap second electrode, the fragmentation chamber comprising a fragmentation chamber first electrode and a fragmentation chamber second electrode;
the one or more buffer capacitors being electrically connected to the voltage rectifier, the voltage rectifier being adapted to convert alternating current input received from the step up transformer to direct current output, the one or more buffer capacitors being structured and arranged to be charged by electrical current received from the voltage rectifier;
the pulse transformer comprising primary and secondary windings structured and arranged to transform an input voltage to an output voltage, the output voltage being greater than the input voltage;
each of the plurality of IGBT modules being adapted to control a respective at least partial discharge of the one or more buffer capacitors such that when a respective IGBT module of the plurality of IGBT modules is in an open configuration, current is permitted to flow from a respective buffer capacitor of the one or more buffer capacitors to the primary windings of the pulse transformer and when the respective IGBT module is in a closed configuration, current is prohibited from flowing from the respective buffer capacitor to the primary windings of the pulse transformer;
each of the plurality of IGBT modules being further adapted to move from the closed configuration to the open configuration for a duration of a control pulse received by each of the plurality of IGBT modules;
each of the plurality of IGBT modules being further adapted to move from the open configuration to the closed configuration upon cessation of the control pulse;
the storage capacitor being adapted to be charged by electrical current from the secondary windings of the pulse transformer;
the storage capacitor being further adapted to discharge current across the spark gap to the spark gap second electrode upon the spark gap first electrode reaching a discharge voltage value;
the spark gap second electrode being electrically connected to the fragmentation chamber first electrode;
the fragmentation chamber being adapted to receive raw material such that portions of the raw material are positioned between the fragmentation chamber first electrode and the fragmentation chamber second electrode;
the fragmentation chamber first electrode and the fragmentation chamber second electrode being structured and arranged to cause a fracture in portions of the raw material upon discharge of the storage capacitor.
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12. An electric pulse fragmentation device comprising:
a pulse transformer, one or more buffer capacitors, one or more resistors; a plurality of insulated-gate bipolar transistor (IGBT) modules, a storage capacitor, a spark gap, and a fragmentation chamber;
the buffer capacitors and the IGBT modules being positioned on a housing of the pulse transformer;
the spark gap being defined by a spark gap first electrode and a spark gap second electrode and being positioned within a discharge tube, the discharge tube being supplied with one or more pressurized gases;
the fragmentation chamber comprising fragmentation chamber first and second electrodes;
the one or more buffer capacitors being electrically connected to a voltage rectifier adapted to convert alternating current input to direct current output, the one or more buffer capacitors being structured and arranged to be charged to a first voltage value by electrical current received from the voltage rectifier;
the pulse transformer comprising primary and secondary windings structured and arranged to transform an input voltage to an output voltage, the output voltage being greater than the input voltage;
the one or more resistors being electrically connected to and positioned between the secondary windings and the storage capacitor
each of the plurality of IGBT modules being adapted to control a respective at least partial discharge of the one or more buffer capacitors such that when a respective IGBT module of the plurality of IGBT modules is in an open configuration, current is permitted to flow from the respective buffer capacitor to the primary windings of the pulse transformer and when the respective IGBT module is in a closed configuration, current is prohibited from flowing from a respective buffer capacitor of the one or more buffer capacitors to the primary windings of the pulse transformer;
each of the plurality of IGBT modules being further adapted to move from the closed configuration to the open configuration for a duration of a control pulse received by each of the plurality of IGBT modules;
each of the plurality of IGBT modules being further adapted to move from the open configuration to the closed configuration upon cessation of the control pulse;
the storage capacitor being adapted to be charged by electrical current from the secondary windings of the pulse transformer;
the storage capacitor being further adapted to discharge current across the spark gap to the spark gap second electrode upon the spark gap first electrode reaching a second voltage value, the second voltage value being a discharge voltage value;
the spark gap second electrode being electrically connected to the fragmentation chamber first electrode;
the fragmentation chamber being adapted to receive raw material such that portions of the raw material are positioned between the fragmentation chamber first electrode and the fragmentation chamber second electrode;
the fragmentation chamber first electrode and the fragmentation chamber second electrode being structured and arranged to cause a fracture in portions of the raw material upon discharge of the storage capacitor.
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17. A method for electrical pulse fragmentation of materials, the method comprising the steps of:
providing a voltage rectifier, a pulse transformer, one or more buffer capacitors, a plurality of insulated-gate bipolar transistor (IGBT) modules, a storage capacitor, a spark gap, and a fragmentation chamber, the spark gap being defined by a spark gap first electrode and a spark gap second electrode, the fragmentation chamber comprising a fragmentation chamber first electrode and a fragmentation chamber second electrode;
positioning raw material within the fragmentation chamber;
using the voltage rectifier, converting alternating current input to direct current output;
using the voltage rectifier, charging the one or more buffer capacitors;
providing a control pulse to the plurality of IGBT modules, and, using the plurality of IGBT modules, controlling a respective at least partial discharge of the one or more buffer capacitors such that when a respective IGBT module of the plurality of IGBT modules is in an open configuration, current is permitted to flow from the respective buffer capacitor to primary windings of the pulse transformer and when the respective IGBT module is in a closed configuration, prohibiting flow from a respective buffer capacitor of the one or more buffer capacitors to the primary windings of the pulse transformer;
each of the plurality of IGBT modules being adapted to move from the closed configuration to the open configuration for a duration of the control pulse;
each of the plurality of IGBT modules being further adapted to move from the open configuration to the closed configuration upon cessation of the control pulse;
using the secondary windings, charging the storage capacitor with electrical current;
upon the storage capacitor reaching a discharge voltage value, automatically discharging the storage capacitor across the spark gap to the fragmentation chamber first electrode and the fragmentation chamber second electrode, the fragmentation chamber first electrode and fragmentation chamber second electrode being separated by a space, a portion of the raw material being positioned within the space;
using the fragmentation chamber first electrode and the fragmentation chamber second electrode, fracturing a portion of the raw material.
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