Microgrid with power equalizer bus and method of operating same

What is claimed is: 1 . A microgrid system, comprising: a plurality of power module clusters; a plurality of uninterruptable power modules; a plurality of bidirectional direct current (DC)/DC converters; and a DC power bus, wherein: each one of the power module clusters of the plurality of power module clusters is electrically connected in parallel to an uninterruptable power module of the plurality of uninterruptable power modules and a first end of a bidirectional DC/DC converter of the plurality bidirectional DC/DC converters, and a second end of each one of the bidirectional DC/DC converters of the plurality of bidirectional DC/DC converters is electrically connected in parallel to the DC power bus. 2 . The system of claim 1 , wherein the plurality of power module clusters comprises a first power module cluster comprising a plurality of fuel cell power modules, and wherein the first power module cluster is electrically connected in parallel to a first bidirectional DC/DC converter of the plurality bidirectional DC/DC converters and a first uninterruptable power module of the plurality of uninterruptable power modules. 3 . The system of claim 2 , further comprising a controller configured with controller executable instructions configured to cause the controller to implement operations comprising: determining whether an electrical power output of the first power module cluster achieves a power module cluster output threshold; and increasing an electrical power draw from the DC power bus by the first bidirectional DC/DC converter in response to determining that the electrical power output of the first power module cluster does not achieve the power module cluster output threshold. 4 . The system of claim 2 , further comprising a controller configured with controller executable instructions configured to cause the controller to implement operations comprising: receiving a user initiated command to increase a power draw from the first power module cluster; and increasing an electrical power draw from the DC power bus by the first bidirectional DC/DC converter in response to the command to increase a power draw from a first power module cluster. 5 . The system of claim 2 , further comprising a controller configured with controller executable instructions configured to cause the controller to implement operations comprising: determining whether a current DC bus electrical power on the DC power bus achieves a DC bus threshold; and increasing an electrical power draw from the first power module cluster by the first bidirectional DC/DC converter in response to determining that the current DC bus electrical power on the DC power bus does not achieve the DC bus threshold; determining whether an electrical power draw from the first power module cluster exceeds a power module cluster limit threshold; and decreasing the electrical power output of the first power module cluster in response to determining that the electrical power draw from the first power module cluster exceeds the power module cluster limit threshold. 6 . A microgrid system, comprising: a plurality of power module clusters; a plurality of uninterruptable power modules; a plurality of bidirectional direct current (DC)/DC converters; and a plurality of DC power busses, wherein: each one of the power module clusters of the plurality of power module clusters is electrically connected in parallel to an uninterruptable power module of the plurality of uninterruptable power modules and a first end of a bidirectional DC/DC converter of the plurality bidirectional DC/DC converters, and each one of the bidirectional DC/DC converters of the plurality of bidirectional DC/DC converters is electrically connected at the first end to a DC power bus of the plurality of DC power busses and at a second end to another DC power bus of the plurality of DC power busses. 7 . The system of claim 6 , wherein: the plurality of power module clusters comprises a first power module cluster comprising a plurality of fuel cell power modules, and wherein the first power module cluster is electrically connected in parallel to a first bidirectional DC/DC converter of the plurality bidirectional DC/DC converters and a first uninterruptable power module of the plurality of uninterruptable power modules; and the plurality of DC power busses comprises a first DC power bus electrically connected to a second end of the first bidirectional DC/DC converter and a first end of a second bidirectional DC/DC converter of the plurality bidirectional DC/DC converters. 8 . The system of claim 7 , further comprising a controller configured with controller executable instructions configured to cause the controller to implement operations comprising: determining whether an electrical power output of the first power module cluster achieves a power module cluster output threshold; and increasing an electrical power draw from the first DC power bus by the first bidirectional DC/DC converter in response to determining that the electrical power output of the first power module cluster does not achieve the power module cluster output threshold. 9 . The system of claim 7 , further comprising a controller configured with controller executable instructions configured to cause the controller to implement operations comprising: receiving a user initiated command to increase a power draw from the first power module cluster; and increasing an electrical power draw from the first DC power bus by the first bidirectional DC/DC converter in response to the command to increase a power draw from a first power module cluster. 10 . The system of claim 7 , further comprising a controller configured with controller executable instructions configured to cause the controller to implement operations comprising: determining whether a current DC bus electrical power on the first DC power bus achieves a DC bus threshold; and increasing an electrical power draw from the first power module cluster by the first bidirectional DC/DC converter in response to determining that the current DC bus electrical power on the first DC power bus does not achieve the DC bus threshold. 11 . The system of claim 7 , further comprising: a second DC power bus of the plurality of DC power busses electrically connected to a second end of the second bidirectional DC/DC converter and a first end of a third bidirectional DC/DC converter of the plurality bidirectional DC/DC converters; and a controller configured with controller executable instructions configured to cause the controller to implement operations comprising: providing electrical power to the second DC power bus by the third bidirectional DC/DC converter; drawing electrical power from the second DC power bus by the second bidirectional DC/DC converter; providing electrical power to the first DC power bus by the second bidirectional DC/DC converter; and drawing electrical power from the first DC power bus by the first bidirectional DC/DC converter. 12 . A method of managing a microgrid system, comprising: providing electrical power to a direct current (DC) power bus by a plurality of bidirectional DC/DC converters, wherein each bidirectional DC/DC converter of the plurality of bidirectional DC/DC converters is electrically connected to at least one power module cluster of a plurality of power module clusters, and wherein each bidirectional DC/DC converter provides the electrical power from the at least one power module cluster; and drawing electrical power from the DC power bus by a first bidirectional DC/DC converter. 13 . The method of claim 12 , further comprising: d