Systems, apparatus, and methods for load sharing between isochronous generators and battery energy storage systems in islanded microgrids

What is claimed is: 1. A power distribution system comprising: a plurality of power generating resources and energy storage resources operating within a microgrid, the energy storage resources including a battery energy storage system (BESS) operable in frequency/voltage (F/V) droop mode, and the power generating resources including a fuel based generator operable in isochronous mode; a plurality of power consuming loads within the microgrid; a power transmission network coupling the resources to the loads; and a controller in communication with the resources and configured to control operation of the resources within the microgrid when the microgrid is islanded, wherein the controller is operative to: determine an optimal load balance between the plurality of power generating resources and energy storage resources via a microgrid optimization module within the controller based on load and renewable generation forecast information; transmit load and generation schedules from the microgrid optimization module to a generation controller that operates the resources in accordance with the schedules; calculate a frequency set point for the BESS operating in F/V droop mode in the microgrid based on optimal load balance droop settings of the BESS, a rated power of the BESS, and a rated frequency of the BESS, wherein the optimal load balance droop settings are a non-zero value of power [P] corresponding to a set frequency value or a non-zero value of power [P] corresponding to a voltage value; and control the frequency set point of the BESS to achieve the optimal load balance such that the BESS is providing all necessary power for a load while the fuel based generator is off, wherein the energy storage resources include a plurality of BESS operating in F/V droop mode, the plurality of BESS including the BESS, and wherein the frequency set point (F setpt t) for the BESS is determined based on: F setpt = P desired × Droop bess × F rated P rated + F system wherein F setpt represents the BESS Frequency set point, F system represents a system frequency, Droop bess represents a droop setting of the BESS, F Rated represents a BESS rated frequency, P desired represents a desired power sharing of the BESS, and P Rated represents a rated power of the BESS. 2. The power distribution system of claim 1 wherein the power generating resources include a plurality of fuel based generators operating in isochronous mode, the plurality of fuel based generators including the fuel based generator. 3. The power distribution system of claim 1 wherein the power generating resources include one or more renewable energy generators operating in power/reactive power (P/Q) mode. 4. The power distribution system of claim 1 wherein the controller includes the microgrid optimization module and a generation controller coupled to the plurality of power generating and energy storage resources and in two way communication with the microgrid optimization module. 5. The power distribution system of claim 4 wherein the controller further includes a load and generation forecast module operative to provide the load and renewable generation forecast information to the microgrid optimization module. 6. A method of controlling an islanded microgrid, the method comprising: determining an optimal load balance between a plurality of generation assets and energy storage systems via a microgrid optimization module implemented within a controller based on load and renewable generation forecast information, wherein the optimal load balance includes load and generation schedules, and wherein the energy storage systems include a battery energy storage system (BESS) operable in frequency/voltage (F/V) droop mode, and the generation assets include a fuel based generator operable in isochronous mode; transmitting the load and generation schedules from the microgrid optimization module to a generation controller that operates the plurality of generation assets and energy storage systems in accordance with the schedules; calculating a frequency set point for the BESS operating in F/V droop mode in the microgrid based on optimal load balance droop settings of the BESS, a rated power of the BESS, and a rated frequency of the BESS, wherein the optimal load balance droop settings are a non-zero value of power [P] corresponding to a set frequency value or a non-zero value of power [P] corresponding to a voltage value; and controlling the frequency set point of the BESS to achieve the optimal load balance such that the BESS is providing all necessary power for a load while the fuel based generator is off, wherein determining an optimal load balance between a plurality of generation assets and energy storage systems includes determining an optimal load balance between the generation assets and a plurality of BESS operating in F/V droop mode, the plurality of BESS including the BESS, and wherein calculating a frequency set point for the BESS includes computing the frequency set point (F setpt ) for the BESS based on: F setpt = P desired × Droop bess × F rated P rated + F system wherein F setpt represents the BESS Frequency set point, F system represents a system frequency, Droop bess represents a droop setting of the BESS, F Rated represents a BESS rated frequency, P desired represents a desired power sharing of the BESS, and P Rated represents a rated power of the BESS. 7. The method claim 6 wherein determining an optimal load balance between a plurality of generation assets and energy storage systems includes determining an optimal load balance between the energy storage systems and a plurality of fuel based generators operating in isochronous mode, the plurality of fuel based generators including the fuel based generator. 8. The method claim 6 wherein determining an optimal load balance between a plurality of generation assets and energy storage systems includes determining an optimal load balance between the energy storage systems and one or more renewable energy generators operating in power/reactive power (P/Q) mode. 9. The method of claim 6 wherein controlling the frequency set point of the BESS includes transmitting the