A machine is adapted for operation powered by any one of a plurality of interchangeable power sources. The machine may include an undercarriage configured for supporting ground engagement members that propel the machine and an upper structure rotatably supported on the undercarriage. The upper structure may include a swing frame, with the swing frame supporting an operator cab, any one of the plurality of interchangeable power sources, hydraulic components, electrical components, and a counterweight disposed at a first end of the swing frame. The counterweight may include a hollowed out portion facing toward the swing frame. The hollowed out portion of the counterweight may be centrally aligned with a center core portion of the swing frame configured for supporting any one of the plurality of interchangeable power sources, with the one power source being partially accommodated within the hollowed out portion of the counterweight.

A electric vehicle including a plurality of ground engaging members, a frame assembly supported by the plurality of ground engaging members, the frame assembly including a front frame assembly, a middle frame assembly, and a rear frame assembly, a seating area supported by the middle frame assembly, electric powertrain components supported by the frame assembly to provide power to at least one ground engaging member, and a shrouding assembly.

In this vehicle mounting structure of a contactless power reception device, a power reception-side coil that configured to be mounted on a bottom surface of a vehicle body and that has an electrically conductive wire wound with the vehicle longitudinal direction as the coil axis is attached to the vehicle body by means of a fastening member made of a magnetic body. The fastening member is disposed to the outside of the power reception-side coil in a direction perpendicular to the coil axis.

The invention provides a powertrain for an electric vehicle, and an electric vehicle as such. The powertrain has an electric motor and a drivetrain for transmitting rotary power from the electric motor to at least one of the vehicle wheels. A mechanical rotary transmission is provided in association with a flywheel. The mechanical rotary transmission is controllable to transmit power in a direction from the vehicle wheels to the flywheel and further transmit power in the reverse direction. Power from both the electric motor and the flywheel is concurrently used to accelerate the vehicle. The vehicle kinetic energy is recovered and stored at the flywheel during vehicle deceleration. The motor vehicle has at least one battery unit to supply the electric motor. The battery unit is removable from the vehicle, without tools, and is portable so that it is carried away from the vehicle for charging.

Disclosed herein is an electric vehicle including a power source, an electric motor adapted to be supplied with electric power from the power source for vehicle driving, a sheet-shaped solar battery for electric power generation, a storing portion for storing the sheet-shaped solar battery in its nonoperating condition, and a connecting unit for allowing the supply of electric power from the sheet-shaped solar battery to at least one of the electric motor and the power source, wherein when the sheet-shaped solar battery is used to perform electric power generation, the sheet-shaped solar battery is taken out of the storing portion and then spread to effect photovoltaic power generation.

An electric power distribution system and method for an electric mining machine is described. In one embodiment, a method for electric power distribution includes receiving information associated with a state of charge of a first battery pack that supplies electric power to a front electric motor configured to drive a front axle of an electric mining machine. The method also includes receiving information associated with a state of charge of a second battery pack that supplies electric power to a rear electric motor configured to drive a rear axle of the electric mining machine. The method includes comparing the state of charge of the first battery pack and the second battery pack and, upon determining that the state of charge of the second battery pack is greater than the state of charge of the first battery pack, increasing electric power to the rear electric motor of the electric mining machine.

An electric vehicle disclosed by the present specification, includes an inverter arranged outside frame members in a vehicle width direction, in a front compartment. An inner side of the inverter in the vehicle width direction is fixed to one of the frame members. An outer side of the inverter in the vehicle width direction is fixed to a cabin outer plate. Furthermore, a fixation strength of the inner side of the inverter is lower than a fixation strength of the outer side of the inverter.

A fuel cell vehicle includes a high voltage apparatus for a fuel cell, a compressor for an air conditioner disposed under the high voltage apparatus for the fuel cell and constituting a module integrated with the high voltage apparatus for the fuel cell, and a power control unit separated from the high voltage apparatus for the fuel cell, disposed at a vehicle body over the compressor and configured to control an operation of a motor. The compressor and the high voltage apparatus for the fuel cell are connected by a single power wiring.

An encasement of an electric machine of an electrified vehicle is provided. The encasement may include a base sidewall, an inner sidewall, and an outer sidewall. The inner sidewall may extend in a circular pattern about the base sidewall. The outer sidewall may extend from the base sidewall and may be spaced apart from the inner sidewall to define a coolant channel at least partially surrounding end windings of a stator of the electric machine. The base sidewall may define features between the sidewalls to promote turbulence of coolant flowing through the coolant channel. The base sidewall may define a meandering trough between the sidewalls to form a predetermined coolant path relative to a location of the end windings.

A battery pack mounting system includes, among other things, an outboard bracket connecting a battery pack to a vehicle underbody, a first inboard bracket connecting the battery pack to the vehicle underbody, and a second inboard bracket connecting the battery pack to a tunnel of the vehicle underbody.