A system and method for controlling an output of a dynamic fuel cell is provided. A dynamic fuel cell has a membrane wherein a dimension of the membrane is variable during operation of the dynamic fuel cell in response to a control signal from an intelligent controller. By varying the dimension of the membrane, the output voltage of the dynamic fuel cell can be altered. An intelligent controller is provided that can measure a number of outputs and input parameters of the dynamic fuel cell and approximate input parameters using the measured values to adjust the input of the dynamic fuel cell to the approximated values.

A system and method for controlling an output of a dynamic fuel cell is provided. A dynamic fuel cell has a membrane wherein a dimension of the membrane is variable during operation of the dynamic fuel cell in response to a control signal from an intelligent controller. By varying the dimension of the membrane, the output voltage of the dynamic fuel cell can be altered. An intelligent controller is provided that can measure a number of outputs and input parameters of the dynamic fuel cell and approximate input parameters using the measured values to adjust the input of the dynamic fuel cell to the approximated values.

A fuel cell system includes a stacked assembly, a resonance determining unit, and a controller. The stacked assembly includes a plurality of unit cells stacked together. Each of the unit cells includes an electrolyte membrane, and a pair of electrodes between which the electrolyte membrane is sandwiched. The resonance determining unit is configured to determine whether vibration of the stacked assembly which occurs during running of a vehicle is within a resonance region of the stacked assembly. The controller is configured to change a natural frequency of the stacked assembly such that the vibration of the stacked assembly falls outside the resonance region, if the resonance determining unit determines that the vibration of the stacked assembly is within the resonance region.

A fuel cell system includes a stacked assembly, a resonance determining unit, and a controller. The stacked assembly includes a plurality of unit cells stacked together. Each of the unit cells includes an electrolyte membrane, and a pair of electrodes between which the electrolyte membrane is sandwiched. The resonance determining unit is configured to determine whether vibration of the stacked assembly which occurs during running of a vehicle is within a resonance region of the stacked assembly. The controller is configured to change a natural frequency of the stacked assembly such that the vibration of the stacked assembly falls outside the resonance region, if the resonance determining unit determines that the vibration of the stacked assembly is within the resonance region.

A fuel cell includes: a stack having a manifold in which a fluid flows and having a plurality of flowing spaces which communicate with the manifold through openings; a shielding part having a plurality of shielding strips arranged in a stacked direction of the stack and selectively moving along the manifold to shield at least some of the plurality of flowing spaces; and a driver coupled with the shielding part to move the shielding part.

A fuel cell includes: a stack having a manifold in which a fluid flows and having a plurality of flowing spaces which communicate with the manifold through openings; a shielding part having a plurality of shielding strips arranged in a stacked direction of the stack and selectively moving along the manifold to shield at least some of the plurality of flowing spaces; and a driver coupled with the shielding part to move the shielding part.

Methods and apparatus are provided for a fuel cell including a fuel desulfurization system. The fuel cell system includes a source of fuel and a fuel desulfurization system fluidly coupled to the source of fuel to receive the fuel in a liquid phase. The fuel desulfurization system includes a vacuum system that depressurizes the fuel to convert at least a portion of the fuel from the liquid phase to a gaseous phase. The fuel cell system also includes a fuel cell stack fluidly coupled to the fuel desulfurization system to receive fuel from the fuel desulfurization system in the gaseous phase.

Methods and apparatus are provided for a fuel cell including a fuel desulfurization system. The fuel cell system includes a source of fuel and a fuel desulfurization system fluidly coupled to the source of fuel to receive the fuel in a liquid phase. The fuel desulfurization system includes a vacuum system that depressurizes the fuel to convert at least a portion of the fuel from the liquid phase to a gaseous phase. The fuel cell system also includes a fuel cell stack fluidly coupled to the fuel desulfurization system to receive fuel from the fuel desulfurization system in the gaseous phase.

A fuel cell stack assembly has a plurality of cells each having a fluid coolant conduit. A coolant feed manifold has a first inlet and a second inlet and is coupled to each fluid coolant conduit for distribution of fluid coolant within each cell. A pump is coupled for delivery of fluid coolant to the coolant feed manifold through the first and second inlets. A flow control assembly is configured to periodically modify the relative flow rates of fluid coolant through the first and second inlets so that stagnant regions in the coolant feed manifold are avoided. The flow control assembly may also be adapted to periodically interrupt the flow path between the pump and the manifold such that the fluid coolant is delivered to the manifold intermittently, thereby enabling low water flows below a minimum set point of the pump.

The present invention provides a fuel cell system and a startup and shutdown method therefor for avoiding carbon corrosion. The fuel cell system includes at least one fuel cell reaction module with at least one anode chamber to contain an anode reaction fluid. The method includes steps of: (a) executing a shutdown mode, (b) conducting and connecting a first load to the fuel cell reaction module so as to consume the anode reaction fluid remained in the anode chamber, (c) providing a buffer fluid to the anode chamber and disconnecting the first load from the anode chamber; (d) maintaining the fuel cell system shutdown, (e) executing a startup mode, (f) providing the anode reaction fluid to the anode chamber, and (g) conducting and connecting a second load to the fuel cell reaction module and maintaining the fuel cell system operated continuously.