Fuel cell units having angled offset flow channels

The invention claimed is: 1. A fuel cell system comprising: a plurality of flow plate assemblies disposed in a stack configuration; wherein each flow plate assembly comprises an identical flow plate ( 300 ) and a membrane electrode assembly ( 400 / 401 / 402 ); wherein each flow plate ( 300 ) comprises a corrugated plate having cathode fluid flow channels ( 330 ) on a first face of the corrugated plate and anode fluid flow channels ( 315 ) across a second face of the corrugated plate, wherein the cathode fluid flow channels ( 330 ) and anode fluid flow channels ( 315 ) are arranged to provide fluid flow from a flow plate inlet region ( 310 ) to a flow plate outlet region ( 320 ), and the flow plate further comprises one or more pairs of side seal regions ( 305 ); wherein each membrane electrode assembly ( 400 / 401 / 402 ) is disposed on the first face of the corrugated plate; wherein each flow plate assembly further comprises a fluid manifold periphery plate ( 200 / 800 ) having an inlet manifold portion ( 205 ) configured to engage with the flow plate inlet region ( 310 ), an outlet manifold portion ( 210 ) configured to engage with the flow plate outlet region ( 320 ), and one or more pairs of pass-through manifold portions ( 215 ) configured to engage with the one or more pairs of side seal regions ( 305 ); wherein adjacent flow plate assemblies are disposed at an offset angle. 2. The fuel cell unit of claim 1 , wherein each flow plate assembly further comprises an inter-cell sealing element ( 801 ) disposed on a first surface of the fluid manifold periphery plate ( 200 / 800 ). 3. The fuel cell unit of claim 2 , wherein the inter-cell sealing element ( 801 ) of each flow plate assembly is retained within a sealing retention feature ( 802 ) of the fluid manifold periphery plate ( 200 / 800 ). 4. The fuel cell unit of claim 1 , wherein: each flow plate comprises a square flow field and has one pair of side seal regions ( 305 ); each fluid manifold periphery plate ( 200 / 800 ) has one pair of pass-through manifold portions ( 215 ); the offset angle is 90°; and the fuel cell unit has two flow plate assemblies disposed in a stack configuration. 5. The fuel cell unit of claim 1 , wherein: each flow plate comprises a hexagonal flow field and has two pairs of side seal regions ( 305 ); each fluid manifold periphery plate ( 200 / 800 ) has two pairs of pass-through manifold portions ( 215 ); the offset angle is 60°; and the fuel cell unit has three flow plate assemblies disposed in a stack configuration. 6. The fuel cell unit of claim 1 , wherein: each flow plate comprises an octagonal flow field and has three pairs of side seal regions ( 305 ); each fluid manifold periphery plate ( 200 / 800 ) has three pairs of pass-through manifold portions ( 215 ); the offset angle is 45°; and the fuel cell unit has four flow plate assemblies disposed in a stack configuration. 7. The fuel cell unit of claim 1 , wherein: each flow plate comprises a decagonal flow field and has four pairs of side seal regions ( 305 ); each fluid manifold periphery plate ( 200 / 800 ) has four pairs of pass-through manifold portions ( 215 ); the offset angle is 36°; and the fuel cell unit has five flow plate assemblies disposed in a stack configuration. 8. The fuel cell unit of claim 1 , wherein: the inlet manifold portion ( 205 ) of each fluid manifold periphery plate ( 200 / 800 ) comprises a plurality of anode inlets ( 810 ), a plurality of cathode inlets ( 820 ), and a coolant inlet ( 830 ); the outlet manifold portion ( 210 ) of each fluid manifold periphery plate ( 200 / 800 ) comprises a plurality of anode outlets ( 811 ) and a plurality of cathode outlets ( 821 ); the plurality of anode inlets ( 810 ), the coolant inlet ( 830 ), and the plurality of anode outlets ( 811 ) are fluidly connected to the anode flow channels ( 315 ) of an associated flow plate ( 300 ); and the plurality of cathode inlets ( 820 ) and the plurality of cathode outlets ( 821 ) are fluidly connected to the cathode flow channels ( 330 ) of an associated flow plate ( 300 ). 9. A fuel cell stack comprising: a plurality of identical fuel cell units, the plurality of fuel cell unit of claim 1 , with each identical fuel cell unit aligned with an adjacent fuel cell unit with no offset angle. 10. A fuel cell system comprising the fuel cell stack of claim 9 . 11. The fuel cell system of claim 9 , further comprising: an anode fluid supply containing anode fluid and fluidly connected to the anode inlets ( 810 ) of the fuel cell stack; a cathode fluid supply containing cathode fluid and fluidly connected to the cathode inlets ( 820 ) of the fuel cell stack; and a coolant fluid supply containing coolant fluid and fluidly connected to the coolant inlets ( 830 ) of the fuel cell stack. 12. The fuel cell system of claim 11 , wherein: the anode fluid comprises a fuel; the cathode fluid comprises an oxidant; and the coolant fluid comprises water. 13. The fuel cell system of claim 12 , wherein: the fuel comprises hydrogen gas; and the oxidant comprises oxygen gas. 14. The fuel cell system of claim 12 , wherein: the oxidant comprises air. 15. The fuel cell system of claim 14 , wherein the one or more of the anode fluid supply, the cathode fluid supply, and the coolant fluid supply comprise a pump configured to control the rate of the associated anode fluid delivery, cathode fluid delivery, and coolant fluid delivery into the fuel cell stack. 16. A method of forming a fuel cell unit, the method comprising: forming a plurality of identical flow plates ( 300 ) each comprising a corrugated plate having cathode fluid flow channels ( 330 ) on a first face of the corrugated plate and anode fluid flow channels ( 315 ) across a second face of the corrugated plate; wherein the cathode fluid flow channels ( 330 ) and anode fluid flow channels ( 315 ) are arranged to provide fluid flow from a flow plate inlet region ( 310 ) to a flow plate outlet region ( 320 ), and the flow plate further comprises one or more pairs of side seal regions ( 305 ); forming a plurality of fluid manifold periphery plates ( 200 / 800 ); wherein each fluid manifold periphery plate ( 200 / 800 ) comprises an inlet manifold portion ( 205 ) configured to engage with the flow plate inlet region ( 310 ), an outlet manifold portion ( 210 ) configured to engage with the flow plate outlet region ( 320 ), and one or more pairs of pass-through manifold portions ( 215 ) configured to engage with the one or more pairs of side seal regions ( 305 ); forming a plurality of flow plate assemblies, each flow plate assembly comprising one of the identical flow plates disposed on one of the fluid manifold periphery plates and a membrane electrode assembly ( 400 / 401 / 402 ) disposed on the first face of the corrugated plate; wherein the forming of each flow plate assembly comprises engaging the inlet manifold portion ( 205 ) with the flow plate inlet region ( 310 ), engaging the outlet manifold portion ( 210 ) with the flow plate outlet region ( 320 ), and engaging the one or more pairs of pass-through manifold portions ( 215 ) with the one or more pairs of side seal regions ( 305 ); and forming the fuel cell unit by assembling a plurality of the formed flow plate assemblies into a stack configuration with adjacent flow plate assemblies disposed at an offset angle. 17. The method of forming a fuel cell unit of claim 16 , wherein the forming of each flow plate assembly further comprises disposing an inter-cell sealing