A control method controls a series hybrid vehicle in which a drive motor and an internal combustion engine are supported in a vehicle body via a plurality of mount members in an integrated state. The control method using a controller generates electric power using an electric power generation motor, and drives the electric power generation motor using motive power of the internal combustion engine. The control method drives a drive wheel with the drive motor using the generated electric power, and causes the drive motor to generate regenerative torque during deceleration. In the control method, the regenerative torque is generated by the drive motor such that an upper limit of the regenerative torque is restricted to a magnitude at which an engine rotational speed where resonance occurs on the vehicle body floor.

A hybrid vehicle includes a planetary gear mechanism, a first electric motor, an internal combustion engine, first drive wheels, an inter-element clutch, a second electric motor, and second drive wheels. The planetary gear mechanism is configured to transmit motive power among first to third rotary elements. The first electric motor is coupled to the first rotary element in a power transmittable manner. The internal combustion engine is coupled to the second rotary element in a power transmittable manner. The first drive wheels are coupled to the third rotary element in a power transmittable manner. The inter-element clutch is configured to switch between coupling and uncoupling two of the first to third rotary elements. The second electric motor is configured to perform power running operation using power generated by the first electric motor. The second drive wheels are coupled to the second electric motor in a power transmittable manner.

A hybrid vehicle includes a planetary gear mechanism, a first electric motor, an internal combustion engine, first drive wheels, an inter-element clutch, a second electric motor, and second drive wheels. The planetary gear mechanism is configured to transmit motive power among first to third rotary elements. The first electric motor is coupled to the first rotary element in a power transmittable manner. The internal combustion engine is coupled to the second rotary element in a power transmittable manner. The first drive wheels are coupled to the third rotary element in a power transmittable manner. The inter-element clutch is configured to switch between coupling and uncoupling two of the first to third rotary elements. The second electric motor is configured to perform power running operation using power generated by the first electric motor. The second drive wheels are coupled to the second electric motor in a power transmittable manner.

An energy storage system for a military vehicle includes a lower support, a battery supported on the lower support, a bracket coupled to the battery, and an upper isolator mount coupled between the bracket and a wall. The upper isolator mount is configured to provide front-to-back vibration isolation of the battery relative to the wall.

An energy storage system for a military vehicle includes a lower support, a battery supported on the lower support, a bracket coupled to the battery, and an upper isolator mount coupled between the bracket and a wall. The upper isolator mount is configured to provide front-to-back vibration isolation of the battery relative to the wall.

A military vehicle includes a chassis, a front axle coupled to the chassis, a rear axle coupled to the chassis, and a driveline. The driveline includes a first driver including an engine, an energy storage system, an accessory drive coupled to the engine, a transmission coupled to at least one of the front axle or the rear axle, and a second driver coupled to the engine and the transmission. The accessory drive includes a plurality of accessories and a first motor. The first motor is electrically coupled to the energy storage system. The second driver includes a second motor electrically coupled to the energy storage system.

A military vehicle includes a chassis, a front axle coupled to the chassis, a rear axle coupled to the chassis, and a driveline. The driveline includes a first driver including an engine, an energy storage system, an accessory drive coupled to the engine, a transmission coupled to at least one of the front axle or the rear axle, and a second driver coupled to the engine and the transmission. The accessory drive includes a plurality of accessories and a first motor. The first motor is electrically coupled to the energy storage system. The second driver includes a second motor electrically coupled to the energy storage system.

A hybrid-drive motorcycle comprising an endothermic engine, a rear wheel connected to a carrier structure through a swingarm, a gearbox connected to the endothermic engine through a primary transmission and to the rear wheel through a secondary transmission, and a reversible electric machine, wherein an auxiliary transmission connects the electric machine to an input shaft of the secondary transmission, and wherein the electric machine is mounted on the carrier structure below the swingarm.

This patent application is directed to thermal management systems of vehicles with an electric powertrain. More specifically, the battery system and one or more powertrain components and/or cabin climate control components of a vehicle share the same thermal circuit as the battery module through which heat can be exchanged between the battery module and one or more powertrain or climate control components as needed.

This patent application is directed to thermal management systems of vehicles with an electric powertrain. More specifically, the battery system and one or more powertrain components and/or cabin climate control components of a vehicle share the same thermal circuit as the battery module through which heat can be exchanged between the battery module and one or more powertrain or climate control components as needed.