Mechanisms are disclosed for releasably attaching a wheel to a vehicle in a position where the wheel supports a weight of the vehicle. An illustrative quick connect system is described to include a wheel, a vehicle frame, and a coupling system that releasably attaches the wheel to the vehicle frame. The coupling system, when in a coupled state, may substantially prevent or oppose rotation between a wheel core and the vehicle frame.

Some embodiments are directed to a drive configuration for a skid-steered vehicle that has a pair of traction motors for rotationally driving opposite outputs of the drive configuration. The traction motors are operatively connected to the outputs via respective gearing arrangements for selectively varying gear reduction between each of the traction motors and the corresponding output. The drive configuration also has a steer differential in a torque connection with the first and second outputs of the drive configuration. The drive configuration additional has a steer motor operatively connected to the steer differential for selectively varying the rotational speed of the first and second outputs in use. Also, the traction and steer motors define a volume in which the gearing arrangements and steering differential are at least partially located.

A two wheeled throwable robot comprises an elongate chassis with two ends, a motor at each end, drive wheels connected to the motors, and a tail extending from the elongate chassis. The throwable robot includes an enable/disable arrangement comprising a pair of magnets generating a magnetic field and a magnetic field sensor positioned in proximity to the pair of magnets. The sensor is activated upon the occurrence of a specific modification of the magnetic field. The throwable robot may include a key member formed of a material to modify the magnetic field to enable the robot.

The present invention relates to a new generation dual-handle, adjustable steering console used for steering tracked military land vehicles. The present invention, considering the weight of the console, vehicle's condition on the ground, and the confined volume of the driver's cabinet, particularly relates to a new generation dual-handle steering console that comprises a linear motion lock (40), an angular motion lock (50), and a wrist motion lock (60) that allow for individually adjusting the steering console to the best position for the driver.

Some embodiments are directed to a drive configuration for a skid-steered vehicle that has a pair of traction motors for rotationally driving opposite outputs of the drive configuration. The traction motors are operatively connected to the outputs via respective gearing arrangements for selectively varying gear reduction between each of the traction motors and the corresponding output. The drive configuration also has a steer differential in a torque connection with the first and second outputs of the drive configuration. The drive configuration additional has a steer motor operatively connected to the steer differential for selectively varying the rotational speed of the first and second outputs in use. Also, the traction and steer motors define a volume in which the gearing arrangements and steering differential are at least partially located.

The invention relates to the automation system providing automatic assembly/disassembly of the vehicle subsystems such as wheel, suspension, axle complex, power transfer etc. of the military land vehicles. In particular, the invention relates to the military land vehicles assembly/disassembly automation systems comprising the drive tower (100), which moves on the “X” axis by the tower movement system (133) drive on the rail (500) anchored to the ground, which is connected with the mounting apparatus (111) of the vehicle body (700) and provides that the height on the “Z” axis with the ball screw (120) to be suitable for mounting, the slave tower (150), which moves on the “Y” axis by the tower movement system (133) drive on the rail (500) anchored to the ground, which is connected with the mounting apparatus (111) of the vehicle body (700) and provides that the height in the “Z” axis with the ball screw (120) to be suitable for mounting, the automatically guided vehicle (600), which has heavy tonnage capacity and the ability to move on X, Y and Z axes on which the work piece (800) to be mounted is positioned, controllable on all of the axis (X,Y and Z) except the manual PLC control (program) with the remote control panel (300) and with wireless or vehicle controller (601) on it, and which is rechargeable and has wireless power supply (traction battery) (602), PLC (400) with programmable structure having its own database that controls all moving elements within the automation system and safety systems within the program limits.

An energy storage system for a military vehicle includes a battery housing defining a lower end and an upper end, a battery disposed within the battery housing, a bracket coupled to the battery housing at or proximate the upper end thereof, a lower support supporting the lower end of the battery housing, and an upper connector extending from the bracket. The upper connector is configured to engage a rear wall of a cab of the military vehicle.

A control system for operating a military vehicle according to different modes includes processing circuitry that receives a user input indicating a selected mode of the different modes, and operates a driveline and a front end accessory drive (FEAD) of the military vehicle according to the selected mode. The driveline of the military vehicle includes an engine and an integrated motor generator (IMG) and the FEAD includes multiple accessories and an electric motor-generator. The modes include an engine mode and an electric mode. In the engine mode, the engine drives the FEAD and drives tractive elements of the military vehicle through the IMG for transportation. In the electric mode, the engine is shut off to reduce a sound output of the military vehicle and the IMG drives the tractive elements of the military vehicle for transportation and the electric motor-generator drives the FEAD.

A work vehicle capable of an autonomous travel includes a seat for a driver, a steering manipulator located in front of the seat and a display device configured to display information about the autonomous travel. The display device is located on one side in a left-right direction of the steering manipulator and includes a display that has a display screen configured to display information about the autonomous travel of the work vehicle and a manipulator connected to the display and having a manipulation member to enable operation associated with the autonomous travel.

A military vehicle includes a cab having a rear wall, a bed positioned behind the cab, and an energy storage system. The energy storage system includes a lower support coupled to the bed, a battery supported by the lower support, a bracket coupled to the batter, and an isolator mount coupling the bracket to the rear wall. The isolator mount is configured to provide front-to-back vibration isolation of the battery relative to the rear wall.