초록 ▼

Embodiments relate to safing logic and fire set systems with a dual-mode pulse gate driver device and method of use. An aspect includes a device for a circuit having a switch, the device comprising: a gate driver including a trigger input to receive a trigger signal to initiate a test of the circuit

Embodiments relate to safing logic and fire set systems with a dual-mode pulse gate driver device and method of use. An aspect includes a device for a circuit having a switch, the device comprising: a gate driver including a trigger input to receive a trigger signal to initiate a test of the circuit in a first mode or a pulse through the circuit to cause a pyrotechnic chain reaction in a second mode, a power supply input and an output for driving the switch in response to receiving the signal. The device includes a trickle charge capacitor coupled to the power supply input. The device includes a high impedance coupled to the capacitor and input power circuitry, the high impedance trickle charging the capacitor and preventing a high voltage through the switch from being applied to the power circuitry in the first mode for subsequent operation in the second mode.

대표청구항 ▼

1. A device for use with a circuit having a switch, the device comprising: a gate driver including a trigger input to receive a trigger signal to initiate a test of the circuit in a first mode or a pulse through the circuit to cause a pyrotechnic chain reaction in a second mode, a power supply input

1. A device for use with a circuit having a switch, the device comprising: a gate driver including a trigger input to receive a trigger signal to initiate a test of the circuit in a first mode or a pulse through the circuit to cause a pyrotechnic chain reaction in a second mode, a power supply input and an output for driving the switch in response to receiving the trigger signal;a trickle charge capacitor coupled to the power supply input; anda high impedance coupled to the trickle charge capacitor and input power circuitry, the high impedance trickle charging the trickle charge capacitor and preventing a high voltage through the switch from being applied to the input power circuitry in the first mode for subsequent operation in the second mode. 2. The device of claim 1, wherein the gate driver is isolated. 3. The device of claim 2, further comprising an opto-isolator having an input configured to receive the trigger signal and an output coupled to the trigger input of the gate driver. 4. The device of claim 1, wherein a capacitance of the trickle charge capacitor is 100 times larger than a gate capacitance of the switch. 5. The device of claim 1, wherein a current consumption of the gate driver is less than current consumption of the trickle charge capacitor to generate a steady-state voltage from the gate driver to the switch. 6. The device of claim 1, wherein the circuit is coupled to the input power circuitry. 7. The device of claim 1, wherein the switch includes an input and the circuit includes a discharge capacitor coupled to the input of the switch and configured to discharge a pulse; and wherein charging of the discharge capacitor and the trickle charge capacitor coincide. 8. A safing logic and fire set (SLFS) system comprising: a safing logic and fire set (SLFS) circuit with a switch, the SLFS circuit coupled to input power circuitry and being configured to discharge a pulse through the switch; anda dual-mode pulse driver device having a first mode to initiate a test of the circuit and a second mode to initiate a pyrotechnic chain through the circuit, the device comprising: a gate driver including a trigger input to receive a trigger signal in the first mode or the second mode, a power supply input and an output for driving the switch in response to receiving the trigger signal;a trickle charge capacitor coupled to the power supply input; anda high impedance coupled to the trickle charge capacitor and the input power circuitry, the high impedance trickle charging the trickle charge capacitor and preventing a high voltage, through the switch, from being applied to the input power circuitry in response to the test. 9. The system of claim 8, wherein the gate driver is isolated. 10. The system of claim 9, wherein the dual-mode pulse driver device further comprising an opto-isolator having in input configured to receive the test trigger signal and an output coupled to the trigger input of the gate driver. 11. The system of claim 8, wherein a capacitance of the trickle charge capacitor is 100 times larger than a gate capacitance of the switch. 12. The system of claim 8, wherein a current consumption of the gate driver is less than current consumption of the trickle charge capacitor to generate a steady-state voltage from the gate driver to the switch. 13. The system of claim 8, wherein the switch includes a switch input and the circuit includes a discharge capacitor coupled to the switch input; and wherein charging of the discharge capacitor and the trickle charge capacitor coincide. 14. The system of claim 8, wherein the switch is a high voltage switch and the pulse to the switch is at least 1000 Volts. 15. The system of claim 14, wherein the pulse is 1200 Volts. 16. A method for testing a circuit having a switch comprising a switch input, the circuit configured to discharge a pulse through the switch and being coupled to input power circuitry, the method comprising: providing a dual-mode pulse driver device comprising a gate driver including a trigger input to receive a trigger signal to initiate a test of the circuit in a first mode or a pulse through the circuit to cause a pyrotechnic chain reaction in a second mode, a power supply input and an output for driving the switch in the circuit; a trickle charge capacitor coupled to the power supply input; and a high impedance coupled to the trickle charge capacitor and the input power circuitry;trickle charging the trickle charge capacitor via the high impedance;simultaneously during the charging of the trickle charge capacitor, charging a discharge capacitor in the circuit;triggering the gate driver for the test, the discharge capacitor discharging the pulse during the test; andpreventing a high voltage through the switch from being applied to the input power circuitry in response to the test in the first mode for subsequent operation in the second mode. 17. The method of claim 16, further comprising: receiving, by an opto-isolator, the test trigger signal; andcommunicating, by the opto-isolator, the received test trigger signal to the gate driver. 18. The method of claim 16, wherein a capacitance of the trickle charge capacitor is 100 times larger than a gate capacitance of the switch. 19. The method of claim 16, wherein during the test, current consumption of the gate driver is less than current consumption of the trickle charge capacitor to generate a steady-state voltage from the gate driver to the switch. 20. The method of claim 16, wherein the switch is a high voltage switch and the pulse discharge applied to the switch is at least 1000 Volts.