A hydraulic-electric drive assembly for a work vehicle has a hydraulic pump drive including a manifold housing, a power input interface configured to couple with a prime mover for receiving rotational input power, and a plurality of power output interfaces coupled to the power input interface to transmit the input power from the prime mover mechanically at a first drive speed. At least one hydraulic pump is mounted to at least one of the power output interfaces to be driven by the input power from the prime mover. At least one electric generator is coupled to at least one of the power output interfaces to be driven by the input power from the prime mover. The at least one electric generator is configured to convert the input power from the prime mover into electric power.

A hydraulic-electric drive assembly for a work vehicle has a hydraulic pump drive including a manifold housing, a power input interface configured to couple with a prime mover for receiving rotational input power, and a plurality of power output interfaces coupled to the power input interface to transmit the input power from the prime mover mechanically at a first drive speed. At least one hydraulic pump is mounted to at least one of the power output interfaces to be driven by the input power from the prime mover. At least one electric generator is coupled to at least one of the power output interfaces to be driven by the input power from the prime mover. The at least one electric generator is configured to convert the input power from the prime mover into electric power.

A system for converting an internal combustion engine vehicle having an arrangement of vehicle accessories into an electric vehicle. The system includes an accessory plate having a series of openings for coupling the vehicle accessories to the accessory plate. The openings are arranged corresponding to the arrangement of the vehicle accessories in the internal combustion engine vehicle such that the vehicle accessories are supported in the same configuration in the electric vehicle as in the internal combustion engine vehicle.

A drive mechanism includes a pair of driven axles, a center section and a pump and a motor rotatably disposed on one side of the center section. A clutch mechanism is located adjacent an opposite side of the center section to drive the pair of axles. The clutch includes at least one clutch fork disposed adjacent to the center section and being rotatable along an axis of rotation that is perpendicular to the axes of rotation of the pump input shaft and motor output shaft, and also perpendicular to the axis of rotation of the axles.

A drive mechanism includes a pair of driven axles, a center section and a pump and a motor rotatably disposed on one side of the center section. A clutch mechanism is located adjacent an opposite side of the center section to drive the pair of axles. The clutch includes at least one clutch fork disposed adjacent to the center section and being rotatable along an axis of rotation that is perpendicular to the axes of rotation of the pump input shaft and motor output shaft, and also perpendicular to the axis of rotation of the axles.

In order to secure a driving performance of an electric vehicle while stably supporting a fuel cell stack, a fuel cell stack generating electric power, a motor generator, and an electrical adjuster are accommodated in an accommodation compartment formed at a front side of a passenger compartment in a vehicle length direction. The electric motor and the electrical adjuster are housed in a common, bottom casing and the bottom casing is arranged at a bottom of the accommodation compartment. A stack support surface which is flat and extends in substantially a horizontal direction is formed at a top of the casing. The fuel cell stack is arranged above the casing and is supported by the casing through mounts arranged on the stack support surface.

In order to secure a driving performance of an electric vehicle while stably supporting a fuel cell stack, a fuel cell stack generating electric power, a motor generator, and an electrical adjuster are accommodated in an accommodation compartment formed at a front side of a passenger compartment in a vehicle length direction. The electric motor and the electrical adjuster are housed in a common, bottom casing and the bottom casing is arranged at a bottom of the accommodation compartment. A stack support surface which is flat and extends in substantially a horizontal direction is formed at a top of the casing. The fuel cell stack is arranged above the casing and is supported by the casing through mounts arranged on the stack support surface.

An electromagnetically operated powertrain system is provided. The system includes a plurality of cylinder assemblies arranged in parallel at least partially along a vehicle. Each of the cylinder assemblies may include one or more cylinders, one or more electromagnetic devices secured to at least one of the ends of each cylinder, one or more pistons reciprocatingly received in the cylinders, and a piston rod coupled to the pistons. Each of the pistons includes a permanent magnet that creates a magnetic field interacting with an electromagnetic field generated by each of the electromagnetic devices. A pulling and/or pushing force may be selectively generated by the magnetic field and the electromagnetic field to enable the pistons to reciprocate within the cylinders. A crankshaft is coupled to the piston rods of the plurality of cylinder assemblies and directly coupled to at least one of front and rear axles of a vehicle.

An electromagnetically operated powertrain system is provided. The system includes a plurality of cylinder assemblies arranged in parallel at least partially along a vehicle. Each of the cylinder assemblies may include one or more cylinders, one or more electromagnetic devices secured to at least one of the ends of each cylinder, one or more pistons reciprocatingly received in the cylinders, and a piston rod coupled to the pistons. Each of the pistons includes a permanent magnet that creates a magnetic field interacting with an electromagnetic field generated by each of the electromagnetic devices. A pulling and/or pushing force may be selectively generated by the magnetic field and the electromagnetic field to enable the pistons to reciprocate within the cylinders. A crankshaft is coupled to the piston rods of the plurality of cylinder assemblies and directly coupled to at least one of front and rear axles of a vehicle.

A drive unit mounting structure of a vehicle includes a front cross member disposed on a front side of a drive unit and elongated in a transverse direction of the vehicle; a mounting hole formed in the front cross member such that a front end of the drive unit can be inserted therein; and a mounting bush mounted in the mounting hole and installed to support the front end of the drive unit.