A DC power distribution system and method includes a solid state remote power controller that connects a switching power source to a DC bus when the DC bus is switching power sources thereby providing a nearly uninterrupted power supply to the DC bus.
대표청구항▼
1. A method for minimal interruption power source switching comprising the steps of: disconnecting a first power source from a DC bus, thereby removing power from said DC bus;connecting a second power source to said DC bus, thereby providing power to said DC bus;monitoring at least one power charact
1. A method for minimal interruption power source switching comprising the steps of: disconnecting a first power source from a DC bus, thereby removing power from said DC bus;connecting a second power source to said DC bus, thereby providing power to said DC bus;monitoring at least one power characteristics of the DC bus and a plurality of DC bus inputs;determining if a fault condition is present on the DC bus by comparing a DC bus voltage to a low voltage threshold, comparing a DC bus input current to a high current threshold, and determining that a fault condition exists in said DC bus when the DC bus voltage is under the low voltage threshold and the DC bus input current is over the high current threshold; andactivating a solid state remote power controller (SSRPC) during the step of disconnecting the first power source and deactivating the SSRPC during the step of connecting the second power source, thereby providing power to said DC bus during a time period between performance of the steps of disconnecting the first power source from said DC bus and connecting the second power source to said DC bus. 2. The method of claim 1, wherein the step of activating the solid state remote power controller (SSRPC) during the step of disconnecting the first power source and deactivating the SSRPC during the step of connecting the second power source comprises the steps of: activating the SSRPC when at least one of said power characteristics falls below a threshold and no fault is present on the DC bus; anddeactivating the SSRPC when the at least one of said power characteristics exceeds the threshold and no fault is present on the DC bus. 3. The method of claim 1, wherein said step of monitoring power characteristics of a DC bus comprises the steps of: monitoring a DC bus voltage using a controller; andmonitoring a DC bus input current from each of multiple DC sources connected to said DC bus. 4. The method of claim 3, wherein the step of monitoring the DC bus input current comprises receiving at least one Hall effect sensor reading. 5. The method of claim 1, further comprising the step of rerouting power from a primary power source to a secondary power source when the DC bus voltage falls below a low voltage threshold and no fault is present in the DC bus. 6. The method of claim 1, wherein the step of activating the SSRPC comprises switching on the SSRPC, thereby connecting a switching power source to said DC bus. 7. The method of claim 1, further comprising the step of opening each of a plurality of contactors connecting DC sources to said DC bus when a fault is detected. 8. The method of claim 7, further comprising the step of broadcasting a fault inhibit command, thereby preventing other controllers from closing said plurality of contactors. 9. The method of claim 1, wherein said steps of activating the SSRPC and deactivating the SSRPC result in said DC bus being disconnected from a voltage source for a duration less than 10 milliseconds. 10. The method of claim 9, wherein said duration is less than 2 milliseconds. 11. The method of claim 1, wherein the method is performed using a field programmable gate array (FPGA). 12. The method of claim 1, wherein the method is performed using an application specific integrated circuit (ASIC). 13. The method of claim 1, further comprising the steps of opening a closed DC bus contactor when said at least one of said power characteristics falls below a threshold and no fault is present on the DC bus, thereby disconnecting a primary power source from said DC bus; and closing an open DC bus contactor when said at least one of said power characteristics falls below a threshold and no fault is present on the DC bus, thereby connecting an alternate power source to said DC bus. 14. A minimally interruptible power source comprising: a DC power bus;a controller, coupled to said DC power bus, said controller being capable of controlling power functions of said DC power bus, wherein the controller includes a DC bus voltage measurement input and at least one DC source current input, and wherein the controller is operable to detect a fault when the DC bus voltage input is below a low voltage threshold and at least one DC source current input is above a high current threshold;a solid state remote power controller (SSRPC) connecting said DC power bus to a switching power source;a plurality of electrical contactors, each of said contactors connecting one of a plurality of primary power sources to said controller; anda communication line for connecting said controller to at least one other controller within a power system. 15. The minimally interruptible power source of claim 14, wherein said controller comprises a field programmable gate array (FPGA). 16. The minimally interruptible power source of claim 14, wherein said controller comprises an application specific integrated circuit (ASIC). 17. The minimally interruptible power source of claim 14, further comprising a DC bus voltage sensor connected to said DC power bus and said controller, thereby allowing said controller to measure a voltage on said DC power bus. 18. The minimally interruptible power source of claim 14, further comprising a plurality of DC input current sensors, each of said input current sensors being connected to a power source input, thereby allowing said controller to measure a DC input current associated with each power source. 19. A DC power distribution system comprising: a plurality of DC power buses, each of said DC power buses having a controller capable of controlling power functions of said DC power bus, a solid state remote power controller (SSRPC) connecting said DC power bus to a switching power source, a plurality of electrical contactors, each of said contactors connecting one of a plurality of primary power sources to said controller, a communication line for connecting said controller to at least one other controller within a power system;a plurality of power generators, each of said power generators being capable of providing power to at least one of said plurality of DC power buses; andwherein each of said controllers includes a DC bus voltage input and at least one DC source current input and wherein each of said controllers is operable to detect a fault when the DC bus voltage input is below a low voltage threshold and at least one DC source current input is above a high current threshold. 20. The minimally interruptible power source of claim 14, wherein the controller further comprises a non-transitory memory storing the low voltage threshold and the high current threshold. 21. The DC power distribution system of claim 19, wherein each of said controllers further comprises a non-transitory memory storing the low voltage threshold and the high current threshold.
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이 특허에 인용된 특허 (14)
Aiello, Frank Joseph, Algorithm for detecting faults on electrical control lines.
Hale,Christopher L.; Hornsby,Rodney M.; Maxwell, Jr.,John M.; Schwarz,Charles R., System and method for remotely detecting and locating faults in a power system.
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