Hybrid fuel cell system for load following and backup in a microgrid and method of operating thereof

The invention claimed is: 1. A fuel cell system, comprising: a first fuel cell of a first electrolyte type; a second fuel cell of a second electrolyte type different from the first electrolyte type; a first direct current (DC)/DC converter electrically connected to the first fuel cell via a first DC bus; a second DC/DC converter electrically connected to the second fuel cell via a second DC bus; a DC/alternating current (AC) inverter electrically connected in parallel to the first DC/DC converter and to the second DC/DC converter via a combined DC bus; an electric energy storage system; a third DC/DC converter electrically connected to the electric energy storage system and configured to output DC electric energy from the electric energy storage system to the DC/AC inverter, wherein the DC/AC inverter is electrically connected in parallel to the first DC/DC converter, to the second DC/DC converter, and to the third DC/DC converter via the combined DC bus; and a controller configured with controller executable instructions to perform operations comprising: drawing DC electric energy from the second fuel cell and a base level DC electric energy from the first fuel cell; determining whether a DC voltage at the combined DC bus exceeds a DC voltage threshold; and decreasing drawing the DC electric energy from the second fuel cell to a level such that the DC voltage at the combined DC bus falls short of or equals to the DC voltage threshold and continuing drawing the DC electric energy from the second fuel cell at the level and drawing the base level DC electric energy from the first fuel cell in response to determining that the DC voltage at the combined DC bus exceeds the DC voltage threshold. 2. The fuel cell system of claim 1 , wherein: the first fuel cell is a solid oxide fuel cell located in a solid oxide fuel cell stack; and the second fuel cell is a proton exchange membrane fuel cell located in a proton exchange membrane fuel cell stack. 3. The fuel cell system of claim 2 , wherein: the solid oxide fuel cell stack is fluidly connected to a hydrocarbon fuel source; and the proton exchange membrane fuel cell stack is fluidly connected to at least one of a hydrogen fuel source or an anode exhaust of the solid oxide fuel cell stack. 4. The fuel cell system of claim 3 , wherein the proton exchange membrane fuel cell stack is fluidly connected to the anode exhaust of the solid oxide fuel cell stack. 5. The fuel cell system of claim 4 , wherein the proton exchange membrane fuel cell stack is directly fluidly connected to the anode exhaust of the solid oxide fuel cell stack through an anode exhaust conduit or is indirectly fluidly connected to the anode exhaust of the solid oxide fuel cell stack through a hydrogen buffer tank. 6. The fuel cell system of claim 2 , wherein the solid oxide fuel cell stack and the proton exchange membrane fuel cell stack are fluidly connected to a hydrogen fuel source. 7. The fuel cell system of claim 1 , further comprising a wherein the controller is further configured with controller executable instructions to perform operations comprising: measuring the DC voltage at the combined DC bus; and determining whether the DC voltage at the combined DC bus falls short of the DC voltage threshold, wherein drawing the DC electric energy from the second fuel cell comprises drawing the DC electric energy from the second fuel cell in response to determining that the DC voltage at the combined DC bus falls short of the DC voltage threshold. 8. The fuel cell system of claim 7 , wherein: the measuring the DC voltage at the combined DC bus comprises measuring the DC voltage at the combined DC bus of the base level DC electric energy from the first fuel cell; and the drawing the DC electric energy from the second fuel cell in response to determining that the DC voltage at the combined DC bus falls short of the DC voltage threshold comprises commencing drawing a variable level DC electric energy from the second fuel cell. 9. The fuel cell system of claim 7 , wherein: the measuring the DC voltage at the combined DC bus comprises measuring the DC voltage at the combined DC bus of the base level DC electric energy from the first fuel cell and a variable level DC electric energy from the second fuel cell; and the drawing the DC electric energy from the second fuel cell in response to determining that the DC voltage at the combined DC bus falls short of the DC voltage threshold comprises increasing draw of the variable level DC electric energy from the second fuel cell. 10. The fuel cell system of claim 7 , wherein the controller is further configured with controller executable instructions to perform operations further comprising: determining whether utility grid power is not available to satisfy the load demand or if an emergency condition has occurred; and if the utility grid power is not available to satisfy the load demand or if the emergency condition has occurred, then activating the second fuel cell and drawing DC electric energy from the second fuel cell. 11. The fuel cell system of claim 1 , wherein: the drawing the DC electric energy from the second fuel cell comprises drawing a variable level DC electric energy from the second fuel cell; and the decreasing the drawing of the DC electric energy from the second fuel cell to the level such that the DC voltage at the combined DC bus falls short of or equals to the DC voltage threshold and continuing drawing of the DC electric energy from the second fuel cell at the level in response to determining that the DC voltage at the combined DC bus exceeds the DC voltage threshold comprises decreasing the drawing of the variable level DC electric energy from the second fuel cell in response to determining that the DC voltage at the combined DC bus exceeds the DC voltage threshold. 12. The fuel cell system of claim 11 , wherein the controller is further configured with controller executable instructions to perform operations further comprising: determining whether the DC voltage at the combined DC bus equals the DC voltage threshold; and ceasing draw of the variable level DC electric energy from the second fuel cell in response to determining that the DC voltage at the combined DC bus equals the DC voltage threshold. 13. A method for operating a fuel cell system, comprising: drawing, via a first direct current (DC)/DC converter, a base level DC electric energy from a first fuel cell of a first electrolyte type to a combined DC bus; measuring a DC voltage at the combined DC bus; determining whether the DC voltage at the combined DC bus falls short of a DC voltage threshold; and drawing, via a second DC/DC converter, a variable DC electric energy from a second fuel cell of a second electrolyte type different from the first electrolyte type in response to determining that the DC voltage at the combined DC bus falls short of the DC voltage threshold; determining whether the DC voltage at the combined DC bus exceeds the DC voltage threshold; and decreasing drawing, via the second DC/DC converter, the variable DC electric energy from the second fuel cell to a level such that the DC voltage at the combined DC bus falls short of or equals to the DC voltage threshold and continuing drawing of the DC electric energy from the second fuel cell at the level and drawing the base level DC electric energy from the first fuel cell in response to determining that the DC voltage at the combined DC bus exceeds the DC voltage threshold; drawing, via a third DC/DC converter, DC electric energy from an electric energy storage system in response to determining that the DC voltage at