Closed loop restoration

What is claimed is: 1. A method for restoring power in a closed-loop power distribution network, said network including at least two power sources, at least one feeder and a plurality of switching devices positioned along the at least one feeder and being in communications with each other, said network being represented by a plurality of teams where each team includes one side of adjacent switching devices and loads and power line sections therebetween, said method comprising: determining that there is a power loss in the network and one or more of the sections is not receiving power; performing a radial restoration process for restoring power to the network where any section only receives power from one power source; determining that at least one of the sections is still not receiving power after the radial restoration process has been performed; estimating load flow and additional capacity at each of the switching devices connected to a power source by the radial restoration process; selecting a first unpowered section to be reconnected to a power source; identifying possible solutions for closing the switching devices connected to the first unpowered section to provide power to the first unpowered section; selecting one of the possible solutions as a best solution; determining if the best solution connects more than one additional power source to the network; accepting the solution if only one additional power source is connected to the network; updating the estimate of the load flow and additional capacity at each of the switching devices connected to the power source; creating a virtual network of the network if more than one additional power source is connected to the network; calculating power flow through the virtual network; determining if the selected solution is valid based on the power flow calculations; removing the solution if it is not valid; updating the solution if it is valid; and selecting a second unpowered section to be reconnected to the power source and repeating the steps of identifying possible solutions, selecting one of the possible solutions, and determining if the best solution connects more than one additional power source. 2. The method according to claim 1 wherein estimating the load flow and additional capacity includes using a breadth first search (BFS). 3. The method according to claim 1 wherein selecting a first unpowered section to be reconnected is based on a user defined priority including load size and total capacity available to the section. 4. The method according to claim 1 wherein selecting one of the possible solutions as a best solution includes selecting the solution with the fewest number of required switching operations for the switching devices. 5. The method according to claim 1 wherein determining if the solution is valid includes determining if the solution meets predetermined requirements of source capacity, line ampacity and voltage constraints. 6. The method according to claim 1 wherein performing a radial restoration process includes determining a plurality of possible power restoration solutions that identify what teams each of the power sources that are available to provide power can provide power to based on a power capacity of the sources and a load requirement of the teams, where each team only receives power from one power source, and applying predetermined selection criteria to the plurality of possible solutions to determine which of the possible solutions is an optimal solution. 7. The method according to claim 6 wherein determining a plurality of possible power restoration solutions includes performing a depth first search (DFS) from each team including an available power source outward to other connected teams. 8. The method according to claim 1 wherein applying selection criteria to the plurality of possible solutions includes determining which of the possible solutions has predesignated high priority loads, which of the possible solutions requires the fewest number of switching operations and which of the possible solutions has the best power source balancing. 9. The method according to claim 1 wherein the method is performed in one of the switching devices. 10. The method according to claim 1 wherein the at least one feeder includes a primary feeder and at least one secondary feeder coupled to the primary feeder, and wherein two of the power sources are at ends of the primary feeder and one of the sources is at an end of the at least one secondary feeder opposite to where it is connected to the primary feeder, and wherein switching devices on the primary and secondary feeders proximate where the secondary feeder is coupled to the primary feeder include two or more neighbor switching devices on one side. 11. The method according to claim 1 wherein the switching devices are reclosers, sectionalizers or circuit breakers. 12. The method according to claim 1 wherein determining that there is a power loss in the network includes determining that there is a fault in the network. 13. A method for restoring power in a closed-loop power distribution network, said network including at least two power sources, at least one feeder and a plurality of switching devices positioned along the at least one feeder and being in communications with each other, said network being represented by a plurality of teams where each team includes one side of adjacent switching devices and loads and power line sections therebetween, said method comprising: determining that there is a power loss in the network and one or more of the sections is not receiving power; performing a radial restoration process for restoring power to the network where any section only receives power from one power source; determining that at least one of the sections is not receiving power after the radial restoration process has been performed; estimating power flow through each switching device; determining an available power capacity from each switching device; determining if the unpowered sections can be powered from any non-neighbor switching devices; virtually closing the switching devices to power the unpowered sections; and updating the estimation of power flow through each switching device and determination of available power capacity from each switching device. 14. The method according to claim 13 wherein determining the power flow and available power capacity includes using a breadth first search (BFS). 15. The method according to claim 13 wherein determining if the unpowered sections can be powered from any non-neighbor switching devices is based on a user defined priority including load size and total capacity available to the section. 16. The method according to claim 13 further comprising selecting a possible restoration solutions as a best solution by selecting a solution with the fewest number of required switching operations for the switching devices. 17. A system for restoring power in a closed-loop power distribution network, said network including at least two power sources, at least one feeder and a plurality of switching devices positioned along the at least one feeder and being in communications with each other, said network being represented by a plurality of teams where each team includes one side of adjacent switching devices and loads and power line sections therebetween, said system comprising: means for determining that there is a power loss in the network and one or more of the sections is not receiving power; means performing a radial restoration process for restoring power to the network where