A fuel cell vehicle includes a fuel cell frame including an outer frame and an inner frame disposed inside the outer frame, an upper structure disposed on the fuel cell frame, and a lower structure disposed under the fuel cell frame. The inner frame is formed in the shape of a partition dividing an inner space surrounded by the outer frame into a plurality of hollows.

A fuel cell vehicle includes a fuel cell frame including an outer frame and an inner frame disposed inside the outer frame, an upper structure disposed on the fuel cell frame, and a lower structure disposed under the fuel cell frame. The inner frame is formed in the shape of a partition dividing an inner space surrounded by the outer frame into a plurality of hollows.

A driving control system of a fuel cell vehicle includes a fuel cell configured to receive hydrogen and air and generate power by a reaction between hydrogen and oxygen, a driving determiner configured to determine a driving state of a vehicle equipped with the fuel cell, a power calculator configured to calculate required power required to be supplied from the fuel cell, and a supply controller configured to control supply of air supplied to the fuel cell based on the driving state determined by the driving determiner and the required power calculated by the power calculator.

A driving control system of a fuel cell vehicle includes a fuel cell configured to receive hydrogen and air and generate power by a reaction between hydrogen and oxygen, a driving determiner configured to determine a driving state of a vehicle equipped with the fuel cell, a power calculator configured to calculate required power required to be supplied from the fuel cell, and a supply controller configured to control supply of air supplied to the fuel cell based on the driving state determined by the driving determiner and the required power calculated by the power calculator.

A single powertrain carrier assembly is provided for mounting or removing multiple fuel cell assemblies in or from an engine bay compartment of a heavy duty truck at the same time. The powertrain carrier assembly can be mounted in new heavy duty trucks, or retrofit into preexisting heavy duty trucks, for example, replacing a diesel engine. The assembly may be provided with a three point mounting system for securing it to a chassis frame, including one front and two angled rear attachment points. In one aspect, the assembly includes a frame structure defining a carrier platform and with lower brackets to secure a first fuel cell assembly below the carrier platform, and upper brackets to secure a second fuel cell assembly above the carrier platform. In another aspect, the assembly includes a frame structure defining lower and upper cavity portions to retain the first and second fuel cell assemblies.

A single powertrain carrier assembly is provided for mounting or removing multiple fuel cell assemblies in or from an engine bay compartment of a heavy duty truck at the same time. The powertrain carrier assembly can be mounted in new heavy duty trucks, or retrofit into preexisting heavy duty trucks, for example, replacing a diesel engine. The assembly may be provided with a three point mounting system for securing it to a chassis frame, including one front and two angled rear attachment points. In one aspect, the assembly includes a frame structure defining a carrier platform and with lower brackets to secure a first fuel cell assembly below the carrier platform, and upper brackets to secure a second fuel cell assembly above the carrier platform. In another aspect, the assembly includes a frame structure defining lower and upper cavity portions to retain the first and second fuel cell assemblies.

An open cabin vehicle is equipped with a fuel cell unit having a hydrogen tank for storing hydrogen to be used as fuel and has a simple structure. An upper end of each of a hydrogen tank, a fuel cell stack, and a hydrogen supply pipe is located farther upward than a floor in a state in which the hydrogen tank, the fuel cell stack, and the hydrogen supply pipe are disposed in a fuel-cell-unit arrangement space which is provided below a space being present farther backward than at least a part of the floor in a vehicle-body inner space, and which borders the vehicle-body inner space, thereby being connected to a vehicle-body outer space which is a space around the open cabin vehicle, via the vehicle-body inner space.

An open cabin vehicle is equipped with a fuel cell unit having a hydrogen tank for storing hydrogen to be used as fuel and has a simple structure. An upper end of each of a hydrogen tank, a fuel cell stack, and a hydrogen supply pipe is located farther upward than a floor in a state in which the hydrogen tank, the fuel cell stack, and the hydrogen supply pipe are disposed in a fuel-cell-unit arrangement space which is provided below a space being present farther backward than at least a part of the floor in a vehicle-body inner space, and which borders the vehicle-body inner space, thereby being connected to a vehicle-body outer space which is a space around the open cabin vehicle, via the vehicle-body inner space.

The power system includes a fuel cell stack, a system accessory, a battery, and a control device. The control device executes, based on a state of a vehicle and the battery, one of the following processes: a normal power generation process during which the control device makes a net output greater than 0; a first idling stop process during which the control device makes the net output equal to or less than 0 while continuing operation of the system accessory and power generation by the stack; a second idling stop process during which the control device makes the net output less than 0 by stopping the power generation while continuing the operation of the system accessory; and a third idling atop process during which the control device makes the net output equal to 0, by stopping both the operation of the system accessory and the power generation.

The power system includes a fuel cell stack, a system accessory, a battery, and a control device. The control device executes, based on a state of a vehicle and the battery, one of the following processes: a normal power generation process during which the control device makes a net output greater than 0; a first idling stop process during which the control device makes the net output equal to or less than 0 while continuing operation of the system accessory and power generation by the stack; a second idling stop process during which the control device makes the net output less than 0 by stopping the power generation while continuing the operation of the system accessory; and a third idling atop process during which the control device makes the net output equal to 0, by stopping both the operation of the system accessory and the power generation.