Power management in fuel cell system based microgrids

The invention claimed is: 1. A microgrid, comprising: a plurality of direct current (DC) power sources; a plurality of voltage source inverters, wherein a DC end of each of the plurality of voltage source inverters is electrically connected to a respective DC power source of the plurality of DC power sources; a microgrid side bus, wherein an alternating current (AC) end of each of the plurality of voltage source inverters is electrically connected to the microgrid side bus, and the microgrid side bus is configured to be electrically connected to a load; a plurality of current source inverters, wherein a DC end of each of the plurality of current source inverters is electrically connected to a respective DC power source of the plurality of DC power sources; a grid side bus, wherein an AC end of each of the plurality of current source inverters is electrically connected to the grid side bus; a transfer switch configured to control a selective electrical connection of the grid side bus to an electric utility power grid or to the microgrid side bus; and a transmission bus electrically connected between the microgrid side bus and the grid side bus. 2. The microgrid of claim 1 , wherein the plurality of direct current (DC) power sources comprise a plurality of fuel cell stacks. 3. The microgrid of claim 2 , wherein: the plurality of voltage source inverters are configured to output approximately equal amounts of AC voltage to the microgrid side bus, wherein a maximum output of AC voltage of each of the plurality of voltage source inverters is based on a lowest generation capacity of any of the plurality of fuel cell stacks; and the plurality of current source inverters are configured to output an AC current to the grid side bus from DC current generated by any of the plurality of fuel cell stacks in excess of the lowest generation capacity. 4. The microgrid of claim 1 , further comprising: a rectifier electrically connected to the grid side bus via the transmission bus; and an additional current source inverter located on the transmission bus and electrically connected to the rectifier at its DC end, and electrically connected to the microgrid side bus at its AC end. 5. The microgrid of claim 4 , wherein the rectifier and the additional current source inverter are configured to use a first AC current from the grid side bus to provide a second AC current to the microgrid side bus when the transfer switch selectively electrically connects the grid side bus to the electric utility power grid. 6. The microgrid of claim 1 , further comprising: a motor electrically connected to the grid side bus via the transmission bus; and a generator electrically connected to the motor and driven by the motor, and electrically connected to the microgrid side bus via the transmission bus. 7. The microgrid of claim 6 , wherein the motor and the generator are configured to use a first AC current from the grid side bus to provide a second AC current to the microgrid side bus when the transfer switch selectively electrically connects the grid side bus to the electric utility power grid. 8. The microgrid of claim 1 , further comprising: an electric contactor configured to selectively electrically complete a circuit along the transmission bus between the grid side bus and the microgrid side bus, and configured to selectively electrically interrupt the circuit along the transmission bus between the grid side bus and the microgrid side bus; and a control device electrically connected to the transmission bus and configured to detect current flow and to signal the electric contactor to complete or interrupt the circuit in response to detecting a flow of current from the microgrid side bus to the grid side bus. 9. The microgrid of claim 8 , wherein the transfer switch and the electric contactor are interlocked such that when the transfer switch selectively electrically connects the grid side bus to the microgrid side bus in response to the electric utility power grid being unavailable, the electric contactor selectively electrically interrupts the circuit along the transmission bus between the grid side bus and the microgrid side bus, and when the electric contactor selectively electrically interrupts the circuit along the transmission bus between the grid side bus and the microgrid side bus in response to a flow of a reverse current from the microgrid side bus to the grid side bus, the transfer switch selectively electrically connects the grid side bus to the microgrid side bus. 10. The microgrid of claim 1 , wherein: the transfer switch is further configured to selectively electrically connect of the grid side bus to the microgrid side bus and selectively electrically disconnect the grid side bus from the electric utility power grid in response to the electric utility power grid being unavailable; and the plurality of current source inverters are configured to output AC current to the microgrid side bus via the grid side bus when the transfer switch selectively electrically connects the grid side bus to the microgrid side bus. 11. A method of operating a microgrid, comprising: providing electric energy from each of a plurality of DC power sources to a respective one of a plurality of voltage source inverters and to a respective one of a plurality of current source inverters; outputting a voltage by the plurality of voltage source inverters to the microgrid side bus such that each of the plurality of voltage source inverters outputs approximately equal amounts of voltage to the microgrid side bus, wherein a maximum output of voltage of each of the plurality of voltage source inverters is based on a lowest generation capacity of one of the plurality of DC power sources; outputting a first current by the plurality of current source inverters to a grid side bus based on an amount of current generated by the plurality of DC power sources in excess of the lowest generation capacity; and using the first current output to the grid side bus to provide a second current to the microgrid side bus. 12. The method of claim 11 , further comprising: determining whether the voltage satisfies a load demand; and in response to determining that the voltage does not satisfy the load demand: drawing the first current from the grid side bus by a rectifier; outputting a third current from the rectifier to an additional current source inverter; and outputting the second current from the additional current source inverter to the microgrid side bus. 13. The method of claim 12 , further comprising: determining whether an electric utility power grid is available; and selectively electrically connecting the grid side bus to the electric utility power grid in response to determining that the electric utility power grid is available, wherein drawing the first current from the grid side bus and outputting the second current to the microgrid side bus occur in response to the grid side bus being selectively electrically connected to the electric utility power grid. 14. The method of claim 11 , wherein using the first current output to the grid side bus to provide the second current to the microgrid side bus comprises: determining whether the voltage satisfies a load demand; and in response to determining that the voltage does not satisfy the load demand: drawing the first current from the grid side bus to drive a motor; driving a generator using the motor; and outputting the second current from the generator to the microgrid side bus. 15. The method of claim 14 , further comprising: determining whether an electric utility power grid is ava