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 drive system of an electric vehicle is disclosed. The vehicle has an arrangement optimized for characteristics of a hydrogen electric truck so as to ensure an available space inside vehicle body frames, thereby allowing a battery, high-voltage electric parts, a hydrogen tank, and the like to be arranged inside the vehicle body frames and increasing space utilization in the vehicle. The drive system includes a motor configured to drive the vehicle, a reducer or a transmission connected to an output side of the motor so as to change a rotational speed of the motor, and a rear axle configured to transmit rotating power output from the reducer or the transmission to vehicle wheels. The motor and the reducer or the transmission together with the rear axle are mounted on a suspension.

A drive system of an electric vehicle is disclosed. The vehicle has an arrangement optimized for characteristics of a hydrogen electric truck so as to ensure an available space inside vehicle body frames, thereby allowing a battery, high-voltage electric parts, a hydrogen tank, and the like to be arranged inside the vehicle body frames and increasing space utilization in the vehicle. The drive system includes a motor configured to drive the vehicle, a reducer or a transmission connected to an output side of the motor so as to change a rotational speed of the motor, and a rear axle configured to transmit rotating power output from the reducer or the transmission to vehicle wheels. The motor and the reducer or the transmission together with the rear axle are mounted on a suspension.

A motor driving control method for controlling a motor speed so that a speed measured value of a motor follows a speed command value is provided. The method includes driving the motor by repeating an on section where a torque is generated in the motor and an off section where a torque is not generated in the motor at a regular period, based on the speed command value, wherein the driving includes applying a phase voltage to only one of multiple phases of the motor in the on section by a pulse width modulation scheme.

A motor driving control method for controlling a motor speed so that a speed measured value of a motor follows a speed command value is provided. The method includes driving the motor by repeating an on section where a torque is generated in the motor and an off section where a torque is not generated in the motor at a regular period, based on the speed command value, wherein the driving includes applying a phase voltage to only one of multiple phases of the motor in the on section by a pulse width modulation scheme.

A container holding mechanism is applied to a fuel cell vehicle including a driving mechanism capable of driving rear wheels and disposed on a side of the rear wheels. The container holding mechanism includes a first hydrogen gas, a second hydrogen gas, a third hydrogen gas container, and a moving unit. The first hydrogen gas container is disposed behind a rear drive shaft. The second hydrogen gas container is disposed in front of the rear drive shaft. The third hydrogen gas container disposed in parallel with the second hydrogen gas container in front of the rear drive shaft. The moving unit is configured to move the driving mechanism pushed out by the first hydrogen gas container in collision in such a manner that the driving mechanism avoids the second hydrogen gas container and the third hydrogen gas container.

A container holding mechanism is applied to a fuel cell vehicle including a driving mechanism capable of driving rear wheels and disposed on a side of the rear wheels. The container holding mechanism includes a first hydrogen gas, a second hydrogen gas, a third hydrogen gas container, and a moving unit. The first hydrogen gas container is disposed behind a rear drive shaft. The second hydrogen gas container is disposed in front of the rear drive shaft. The third hydrogen gas container disposed in parallel with the second hydrogen gas container in front of the rear drive shaft. The moving unit is configured to move the driving mechanism pushed out by the first hydrogen gas container in collision in such a manner that the driving mechanism avoids the second hydrogen gas container and the third hydrogen gas container.

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.