There is provided a fuel cell system comprising a first fuel stack, a first temperature gauge configured to measure a first temperature value, a power generation voltage meter configured to measure a power generation voltage, a cell voltage meter and a controller configured to control a temperature regulating mechanism such as to perform a temperature rise of the fuel cell stack. The controller is further configured to start the temperature rise of the fuel cell stack when a cell voltage is lower than a predetermined voltage value. When at least one of a plurality of time measurement conditions is satisfied after the first temperature value has reached a first reference temperature after a start of the temperature rise, the controller measures a time duration during which a voltage difference by subtracting the cell voltage from an average voltage of cells is maintained to be not greater than a predetermined voltage difference. When the measured time duration has reached a first reference time, the controller terminates the temperature rise. The plurality of time measurement conditions are conditions that predetermined time periods have elapsed since termination of a warm-up operation, since termination of an intermittent operation, since termination of regenerative braking and since a shift of the state of the fuel cell stack to a power generation capable state.

A fuel cell vehicle has both left-hand drive specifications and right-hand drive specifications. A first converter is placed at a same position whichever of the left-hand drive specifications or the right-hand drive specifications are applied. A second converter is placed on a selected one of the left-hand side and the right-hand side of the center line of the fuel cell vehicle for the left-hand drive specifications, while, for the right-hand drive specifications, placed on the other side of the center line of the fuel cell vehicle opposite to the selected one side for the left-hand drive specifications. A first wire harness to be used as the wire harness for the left-hand drive specifications and a second wire harness to be used as the wire harness for the right-hand drive specifications are equal in length to each other.

A fuel cell vehicle has both left-hand drive specifications and right-hand drive specifications. A first converter is placed at a same position whichever of the left-hand drive specifications or the right-hand drive specifications are applied. A second converter is placed on a selected one of the left-hand side and the right-hand side of the center line of the fuel cell vehicle for the left-hand drive specifications, while, for the right-hand drive specifications, placed on the other side of the center line of the fuel cell vehicle opposite to the selected one side for the left-hand drive specifications. A first wire harness to be used as the wire harness for the left-hand drive specifications and a second wire harness to be used as the wire harness for the right-hand drive specifications are equal in length to each other.

A fuel cell system for a vehicle for preventing intrusion of water in a relief valve without providing a casing or a waterproof sheet for the relief valve is provided. The fuel cell system comprises a fuel cell stack placed in a front room of a vehicle, a power control unit to perform output control of the fuel cell stack, a hydrogen supply path for supplying hydrogen gas to the fuel cell stack, and the relief valve provided in half way of the hydrogen supply path. The relief valve is placed above the fuel cell stack in the front room and includes an exhaust port. The exhaust port is placed facing an upper surface of a casing of the power control unit with a clearance such that the hydrogen gas is ejected downward through the exhaust port in the direction of gravity.

A fuel cell system for a vehicle for preventing intrusion of water in a relief valve without providing a casing or a waterproof sheet for the relief valve is provided. The fuel cell system comprises a fuel cell stack placed in a front room of a vehicle, a power control unit to perform output control of the fuel cell stack, a hydrogen supply path for supplying hydrogen gas to the fuel cell stack, and the relief valve provided in half way of the hydrogen supply path. The relief valve is placed above the fuel cell stack in the front room and includes an exhaust port. The exhaust port is placed facing an upper surface of a casing of the power control unit with a clearance such that the hydrogen gas is ejected downward through the exhaust port in the direction of gravity.

A fuel cell system includes: a flow sensor configured to measure an actual flow rate of air which is introduced into an oxidizing gas supply passage via a compressor when a fuel cell generates electric power; and a wind speed deriving unit configured to acquire a flow rate of air measured by the flow sensor in a state in which air flows from the oxidizing gas supply passage to an oxidizing gas discharge passage via the compressor and a bypass flow passage and to derive an actual wind speed of wind which is received by the fuel cell system, when the compressor stops.

A fuel cell system includes: a flow sensor configured to measure an actual flow rate of air which is introduced into an oxidizing gas supply passage via a compressor when a fuel cell generates electric power; and a wind speed deriving unit configured to acquire a flow rate of air measured by the flow sensor in a state in which air flows from the oxidizing gas supply passage to an oxidizing gas discharge passage via the compressor and a bypass flow passage and to derive an actual wind speed of wind which is received by the fuel cell system, when the compressor stops.

A fuel cell device that can prevent exposure of a cell stack to the outside of a stack case, and a vehicle with the same mounted thereon. The fuel cell device includes a cell stack, end plates disposed at opposite ends of the cell stack in a stacking direction of fuel cells, and a stack case housing the cell stack and end plates. The stack case has a bottom surface portion, end plate facing portions facing the respective end plates, side surface portions extending in the stacking direction, and mount portions disposed near corner portions between the respective side surface portions and end plate facing portions and on outer walls of the respective side surface portions such that the mount portions are positioned in a pair across the bottom surface portion. The bottom surface portion has rib portions disposed thereon that each extends between a pair of the mount portions.

A fuel cell device that can prevent exposure of a cell stack to the outside of a stack case, and a vehicle with the same mounted thereon. The fuel cell device includes a cell stack, end plates disposed at opposite ends of the cell stack in a stacking direction of fuel cells, and a stack case housing the cell stack and end plates. The stack case has a bottom surface portion, end plate facing portions facing the respective end plates, side surface portions extending in the stacking direction, and mount portions disposed near corner portions between the respective side surface portions and end plate facing portions and on outer walls of the respective side surface portions such that the mount portions are positioned in a pair across the bottom surface portion. The bottom surface portion has rib portions disposed thereon that each extends between a pair of the mount portions.

A high-voltage unit casing 10 for on-vehicle use to house therein a plurality of devices includes: a first side face 20; a second side face 21 opposed to the first side face; and a connecting portion 22 for structurally connecting the first side face and the second side face to each other. The connecting portion includes a partitioning portion 50 which is fixed to the first side face at a fixing portion and which extends from the fixing portion toward the second side face, the partitioning portion being located at a position separate from an upper surface and a lower surface of the high-voltage unit casing in an inner surface of the first side face. Spaces for placing at least one device included in the plurality of devices are formed on both upper and lower sides, respectively, of the partitioning portion.