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A switching system for switching between phases in a multi-phase power distribution system includes a switch for selectively connecting a lateral line to feeder conductors of different phases in a multi-phase power distribution system. Feeder terminals of the switch are configured to connect to feed

A switching system for switching between phases in a multi-phase power distribution system includes a switch for selectively connecting a lateral line to feeder conductors of different phases in a multi-phase power distribution system. Feeder terminals of the switch are configured to connect to feeder conductors of the multi-phase power distribution system. At least one output terminal of the switch is configured to connect to the lateral line. The feeder terminals are spaced about the body of the switch. A shaft and a rotatable contact member extending radially from the shaft are configured for rotating within the switch body to selectively connect the at least one output terminal to any one or more of the feeder terminals. At least one controller operates the switch to selectively change connection of the lateral line between the feeder conductors.

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1. A switching system for topology control and switching between phases in a multi-phase power distribution system, the switching system comprising: a first switch for selectively connecting a first lateral line to feeder conductors of different phases in a multi-phase power distribution system, the

1. A switching system for topology control and switching between phases in a multi-phase power distribution system, the switching system comprising: a first switch for selectively connecting a first lateral line to feeder conductors of different phases in a multi-phase power distribution system, the first switch comprising a plurality of feeder terminals configured to connect to the feeder conductors of the multi-phase power distribution system, the first switch further comprising at least one output terminal configured to connect to the first lateral line, and the first switch further comprising a switch body, wherein the feeder terminals are spaced about the switch body, the first switch further comprising a shaft and a rotatable contact member extending radially from the shaft for rotating within the switch body and selectively connecting the at least one output terminal to any one or more of the feeder terminals;a first controller for operating the first switch to selectively change connection of the first lateral line between the feeder conductors of the multi-phase power distribution system, wherein the first lateral line is connected to a prosumer that consumes and produces energy and the first switch connects the first lateral line to a first feeder conductor of the plurality of feeder conductors;a second switch for selectively connecting a second lateral line to the feeder conductors of different phases in the multi-phase power distribution system, the second switch comprising a plurality of feeder terminals configured to connect to the feeder conductors of the multi-phase power distribution system, the second switch further comprising at least one output terminal configured to connect to the second lateral line, wherein the second lateral line is connected to a plurality of loads that consume energy and the second switch connects the second lateral line to a second feeder conductor of the plurality of feeder conductors; anda second controller for operating the second switch to selectively change connection of the second lateral line between the feeder conductors of the multi-phase power distribution system, wherein the second controller determines that the first lateral line has excess energy to supply and communicates with the first controller to effect switching of the first lateral line to the second feeder conductor. 2. The switching system of claim 1 wherein the rotatable contact member is configured for bi-directional rotation within the switch body. 3. The switching system of claim 2 wherein the multiphase power distribution system comprises a three-phase power distribution system and wherein the rotatable contact member is configured to selectively change the connection of the at least one output terminal of the first switch with any one of the feeder terminals to any of the other feeder terminals without making connection with an intermediate feeder terminal. 4. The switching system of claim 1 wherein the at least one output terminal of the first switch is a single output terminal connected to the rotatable contact member. 5. The switching system of claim 4 wherein the single output terminal is connected to the shaft via a brush assembly. 6. The switching system of claim 1 wherein the at least one output terminal of the first switch comprises a plurality of output terminals, each being paired with a respective one of the feeder terminals of the first switch, wherein the rotatable contact member includes an elongated end portion for shorting output terminal-feeder terminal pairs and for moving in response to input from the at least one controller to short different output terminal-feeder terminal pairs. 7. The switching system of claim 6 wherein the elongated end portion has an arcuate profile conforming to a path in the switch body within which the elongated end portion rotates. 8. The switching system of claim 7 wherein the elongated end portion is bisected by a radially extending portion of the rotatable contact member and has a span sufficient to short an output terminal-feeder terminal pair. 9. The switching system of claim 6 wherein the first switch includes a plurality of semiconductor devices connected across each combination of feeder and output terminals, wherein the semiconductor devices maintain an electrical connection between a combination of feeder and output terminals when the rotatable contact member moves to open a connection between the combination of feeder and output terminals and wherein the semiconductor devices turn off before the rotatable contact member creates a connection between another combination of feeder and output terminals. 10. The switching system of claim 9 wherein the semiconductor devices each comprise at least one thyristor. 11. The switching system of claim 1 wherein the first controller is local to the first switch for determining whether to control the first switch to switch connection of the at least one output terminal of the first switch between the feeder terminals of the first switch based on sensor data received by the first controller. 12. The switching system of claim 11 wherein the first controller is configured to communicate with peer local controllers associated with switches other than the first switch to determine whether to switch connection of the at least one output terminal of the first switch between the feeder terminals of the first switch. 13. The switching system of claim 11 comprising a remote controller for communicating with the first controller regarding the determination as to whether to switch connection of the at least one output terminal of the first switch between the feeder terminals of the first switch. 14. The switching system of claim 1 wherein the first controller is configured to determine whether to switch connection of the at least one output terminal of the first switch between the feeder terminals of the first switch based on one of: relative phase loading, overloading, volt/var optimization, maintenance, phase reconfiguration, loss minimization, feeder optimization, outages, feeder faults, and load faults. 15. The switching system of claim 1 wherein the first switch and the first controller are configured to operate at a medium voltage level where the voltage levels on the first lateral line and the feeder conductors are equal. 16. The switching system of claim 1 wherein the feeder terminals of the first switch are located in the same axial plane. 17. The switching system of claim 1 wherein at least some of the feeder terminals of the first switch are located in different axial planes. 18. A method for topology control and switching between phases in a multi-phase power distribution system, the method comprising: connecting a first lateral line to a first feeder terminal of a first phase of a multi-phase power distribution system via a first switch, the first switch comprising a plurality of feeder terminals configured to connect to the feeder conductors of the multi-phase power distribution system, the first switch further comprising at least one output terminal configured to connect to the first lateral line, and the first switch further comprising a switch body, wherein the feeder terminals are spaced about the switch body, the first switch further comprising a shaft and a rotatable contact member extending radially from the shaft for rotating within the switch body and selectively connecting the at least one output terminal to any one or more of the feeder terminals;operating the first switch to selectively change connection of the first lateral line between the feeder conductors of the multi-phase power distribution system, wherein the first lateral line is connected to a prosumer that consumes and produces energy and wherein operating the first switch includes using a first controllercontrolling, using a second controller, a second switch for selectively connecting a second lateral line to the feeder conductors of different phases in the multi-phase power distribution system, the second switch comprising a plurality of feeder terminals configured to connect to the feeder conductors of the multi-phase power distribution system, the second switch further comprising at least one output terminal configured to connect to the second lateral line, wherein the second lateral line is connected to a plurality of loads that consume energy and the second switch connects the second lateral line to a second feeder conductor of the plurality of feeder conductors; andoperating, using the second controller, the second switch to selectively change connection of the second lateral line between the feeder conductors of the multi-phase power distribution system, wherein the second controller determines that the first lateral line has excess energy to supply and communicates with the first controller to effect switching of the first lateral line to the second feeder conductor. 19. The method of claim 18 wherein the first controller is local to the first switch and wherein operating the first switch includes utilizing the first controller for determining whether to control the first switch to switch connection of the at least one output terminal between the feeder terminals based on sensor data received by the first controller. 20. The method of claim 18 wherein operating the first switch comprises utilizing first controller local to the first switch configured communicate with peer local controllers associated with switches other than the first switch to determine whether to switch connection of the at least one output terminal of the first switch between the feeder terminals of the first switch. 21. The method of claim 19 wherein operating the first switch comprises utilizing a remote controller for communicating with the first controller regarding the determination as to whether to switch connection of the at least one output terminal of the first switch between the feeder terminals of the first switch. 22. The method of claim 18 wherein operating the first switch comprises determining whether to switch connection of the output terminal of the first switch between the feeder terminals of the first switch based on one of: relative phase loading, overloading, volt/var optimization, maintenance, phase reconfiguration, loss minimization, feeder optimization, outages, feeder faults, and load faults. 23. A non-transitory computer readable medium having stored therein executable instructions that when executed by the processor of a computer control the computer to perform steps comprising: connecting a first lateral line to a first feeder terminal of a first phase of a multi-phase power distribution system via a first switch, the first switch comprising a plurality of feeder terminals configured to connect to the feeder conductors of the multi-phase power distribution system, the first switch further comprising at least one output terminal configured to connect to the first lateral line, and the first switch further comprising a switch body, wherein the feeder terminals are spaced about the switch body, the first switch further comprising a shaft and a rotatable contact member extending radially from the shaft for rotating within the switch body and selectively connecting the at least one output terminal to any one or more of the feeder terminals;operating the first switch to selectively change connection of the first lateral line between the feeder conductors of the multi-phase power distribution system, wherein the first lateral line is connected to a prosumer that consumes and produces energy and wherein operating the first switch includes using a first controllercontrolling, using a second controller, a second switch for selectively connecting a second lateral line to the feeder conductors of different phases in the multi-phase power distribution system, the second switch comprising a plurality of feeder terminals configured to connect to the feeder conductors of the multi-phase power distribution system, the second switch further comprising at least one output terminal configured to connect to the second lateral line, wherein the second lateral line is connected to a plurality of loads that consume energy and the second switch connects the second lateral line to a second feeder conductor of the plurality of feeder conductors; andoperating, using the second controller, the second switch to selectively change connection of the second lateral line between the feeder conductors of the multi-phase power distribution system, wherein the second controller determines that the first lateral line has excess energy to supply and communicates with the first controller to effect switching of the first lateral line to the second feeder conductor.