A fuel cell vehicle includes a fuel cell, an air compressor configured to draw in and discharge air, a cooler configured to cool air discharged from the air compressor, a humidifier configured to humidify air cooled by the cooler and to supply the humidified air to the fuel cell, and a system frame on which the fuel cell is disposed. The system frame accommodates at least a portion of each of the cooler and the humidifier therein.

In a mounting structure for a fuel cell drive system, a mount member includes a first mount and a second mount. The first mount connects the first end of a stack case to the first frame. The second mount connects the second end of an auxiliary device case to the second frame. The fuel cell drive system includes a first connecting member and a second connecting member. The first connecting member connects the stack case and a motor to each other. The second connecting member connects the auxiliary device case and a speed reducer to each other.

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 method for supplying at least one fuel cell of a fuel cell system of the motor vehicle with fuel includes ascertaining or predicting an indication value which is indicative of the real and/or possible mass flow of the withdrawal of fuel from a pressure-vessel system of the motor vehicle and closing at least one tank shut-off valve when the indication value is equal to or falls below a limiting value.

A power generation amount of a power generator disposed on a vehicle is appropriately controlled by ordering the power generator a required power generation amount so as to control the power generator, driving a drive motor configured to drive a driving wheel of the vehicle using at least part of electric power generated by the power generator according to the required power generation amount, storing at least part of surplus power left in the electric power generated by the power generator in a storage device, detecting a slip of the driving wheel, and, executing reduction processing of a power generation amount for further reducing a required power generation amount that reflects a reduction amount of the electric power for driving the drive motor due to the slip of the driving wheel, if the detected extent of the slip is larger than a predetermined threshold.

A low floor road vehicle, in the form for example of a passenger bus, includes a front module that includes the front load-carrying axle at its front, a rear module including the rear load-carrying axle, a central module having a flat floor and lateral side walls that longitudinally extend beyond both longitudinal ends of the flat floor so as to define front and back module attaching portions, and a roof mounted to both lateral side walls so as to extend beyond the floor both towards the front and back, which brings rigidity to the overall structure. The vehicle being modular, the central module can be configured to a specific application, for example by varying the length thereof, while same configurations of the front and rear modules can be used in all applications. Also, the front axle being located at the front of the front module, the access to the passenger area defined by the flat floor is improved.

A control method for a fuel cell system is provided to prevent freezing in an air exhaust system of the fuel cell system. The method prevents freezing in the exhaust system by specifying a vehicle condition in which possibility of freezing is high and operating the fuel cell system based on different vehicle-specific standards. The performs air supercharging control based on an ambient temperature and a temperature of cooling water, air supercharging control by applying weights based on inclinations of a vehicle, and a forced heating logic using a COD heater.

A regenerative braking control system for a motor-driven vehicle is configured to provide a continuous assistant braking force by continuous reverse torque of an electric motor by enabling surplus electrical energy produced by an electric motor to be easily converted into thermal energy in generative braking, using both of a brake resistor and a heater to convert electrical energy into thermal energy, and being able to obtain an interior heating effect by using thermal energy converted by the brake resistor and the heater as heat source for interior heating without discharging the thermal energy to the outside.

A fuel cell stack includes a cell stack body and a terminal plate and an insulator disposed at an end of the cell stack body in a stacking direction. The cell stack body includes a plurality of stacked power generation cells. Each of the power generation cells includes a membrane electrode assembly and a separator. The terminal plate is disposed between the cell stack body and the insulator. Elastic structure which elastically presses the terminal plate toward the cell stack body is provided between the insulator and the terminal plate.

A fuel cell system includes: a fuel cell unit; first and second supply systems; a switching device; a switching control unit; an open circuit voltage obtaining unit; and a supply system control unit.