A drive assembly for a mining vehicle includes a frame, a housing coupled to the frame, and a motor positioned in the housing. The motor includes a motor frame with a first axial end and a second axial end opposite the first axial end. The drive assembly also includes a transmission that is positioned at least partially within the frame. The transmission is coupled to the motor frame at the first axial end. The drive assembly further includes a support assembly that couples the second axial end of the motor frame to the housing.

In at least some implementations, a system for a vehicle differential having multiple gears includes a coil of wire, a drive member movable in response to a magnetic field generated by application of electricity to the coil between a first position and a second position, and a lock member coupled to the drive member for movement with the drive member throughout a range of movement of the drive member. The lock member is adapted to engage a gear of the differential when the drive member is in the second position and the lock member is adapted to be disengaged from the gear when the drive member is in the first position. In this way, the differential may be selectively locked.

A system and method using a mount assembly for attaching a powertrain to a structural member of a vehicle. The mount assembly includes a first compliant member, a second compliant member, a first fluid chamber, a second fluid chamber, a pressure compliant membrane, electro-magnetorheological switch and a magnetorheological fluid. A fluid conduit interconnects the first fluid chamber with the second fluid chamber to allow a fluid to pass from the first fluid chamber to the second fluid chamber. The pressure compliant membrane seals the aperture in the second fluid chamber. The electro-magnetorheological switch is activated to generate an electric field in the fluid conduit to change the viscosity of the magnetorheological fluid to achieve a first stiffness profile of the mount assembly. The electro-magnetorheological switch is deactivated to remove the electric field in the fluid conduit to change the viscosity of the magnetorheological fluid to achieve a second stiffness profile of the mount assembly.

A system and method using a mount assembly for attaching a powertrain to a structural member of a vehicle. The mount assembly includes a first compliant member, a second compliant member, a first fluid chamber, a second fluid chamber, a pressure compliant membrane, electro-magnetorheological switch and a magnetorheological fluid. A fluid conduit interconnects the first fluid chamber with the second fluid chamber to allow a fluid to pass from the first fluid chamber to the second fluid chamber. The pressure compliant membrane seals the aperture in the second fluid chamber. The electro-magnetorheological switch is activated to generate an electric field in the fluid conduit to change the viscosity of the magnetorheological fluid to achieve a first stiffness profile of the mount assembly. The electro-magnetorheological switch is deactivated to remove the electric field in the fluid conduit to change the viscosity of the magnetorheological fluid to achieve a second stiffness profile of the mount assembly.

A gearbox housing includes a set of ribs on an inner surface of a wall portion of the housing. During a fire event, heat received at the outside of the gearbox is transferred to the ribs, which transfer the heat away from the wall portion, in turn resisting the fire. The ribs may transfer the heat to oil, which may flow toward an oil drain. In addition or alternatively, the ribs may transfer the heat to a heat sink of the housing to which they are connected. The ribs may allow a thin region surrounding the ribs to a have a minimum thickness that is thinner than required to pass a fire test, thereby allowing for lighter weight gearbox houses that are still fire resistant.

A low-profile vehicle chassis comprising at least one chassis section comprising an upper side, a lower side spaced from the upper side and a cavity defined between the upper and lower sides of the chassis. At least one drivetrain and/or power component of the vehicle is contained within the cavity. Also, a vehicle comprising such a chassis. Also provided is a drivetrain module for an electric vehicle, the drivetrain module comprising a housing, at least one electric motor within the housing, a gearbox within the housing and having an input connected to the at least one electric motor to receive drive from the at least one electric motor, and at least one drive shaft connected to an output of the gearbox to transmit mechanical drive from the gearbox.

A low-profile vehicle chassis comprising at least one chassis section comprising an upper side, a lower side spaced from the upper side and a cavity defined between the upper and lower sides of the chassis. At least one drivetrain and/or power component of the vehicle is contained within the cavity. Also, a vehicle comprising such a chassis. Also provided is a drivetrain module for an electric vehicle, the drivetrain module comprising a housing, at least one electric motor within the housing, a gearbox within the housing and having an input connected to the at least one electric motor to receive drive from the at least one electric motor, and at least one drive shaft connected to an output of the gearbox to transmit mechanical drive from the gearbox.

A dual-power-source dual driving assembly for a vehicle, includes two driving units that are symmetrically provided and connected to a same one set of vehicle axle half shaft. Each driving units is provided with a power source and an automatic transmission that are each connected to one half shaft of the vehicle axle half shaft. Moreover, each automatic transmission is provided with an input shaft, an intermediate shaft and an output shaft that are parallel. The three shafts have multiple gear stages with different transmission ratios, the power source is connected to the input shaft, and the output shaft is connected to a left or right half shaft of the vehicle axle half shaft. The dual driving assembly provides a transmission with two speed ratios, which results in flexible transmission modes, and shortens the axial dimension of the driving assembly.

A drive and control system for a lawn tractor includes one or more sensors configured to detect an operational parameter of an aspect of the vehicle, and one or more controllers for controlling one or more components of the vehicle and for receiving data output from the one or more sensors. The controller communicates with the one or more sensors and one or more vehicle modules configured to control one or more vehicle components via a CAN Bus network. The controller may be coupled to an IMU mounted on the vehicle for dynamically controlling the vehicle on sloped terrain, for example. The controller may be accessible from a remote device over a wireless network for communicating setup, diagnostic, and performance data to and from the vehicle.

A controller drives a shifting actuator to move a first engagement member from an original position of a first engagement portion in one direction along a relative motion path and acquires first position information representing a first position, the first position being a position where the first engagement portion moved in the one direction contacts a second engagement portion. The controller drives the shifting actuator to move the first engagement member from the original position in the other direction along the relative motion path and acquires second position information representing a second position where the first engagement portion moved in the other direction contacts the second engagement portion. The controller calculates a center position of the first engagement portion on the relative motion path from the acquired first position information and the acquired second position information, compares the calculated center position to the original position.