A two-seater off-road vehicle includes a travel vehicle body that is supported on the ground by a front wheel unit and a rear wheel unit, and a boarding part disposed above a vehicle body frame included in the travel vehicle body. The boarding part includes: a driver seat; a steering operation tool in front of the driver seat; and a passenger seat of a saddle seat type behind the driver seat.

The present invention relates to a basic mobile robot (1) where the weight on the drive wheels (6) can be adjusted in order to achieve the optimal traction and braking performance of the mobile robot (1) for the relevant application. With the inventive design of the bogie arm (4) and the modular traction weights (9), the gravitation forces and resulting friction acting on the drive wheels (6) can be increased by attaching one or more traction weight modules (13) to the bogie arm extensions (12), while due to the cantilever effect, the resulting gravitation forces acting on the (front) caster wheels (7) are decreased. Thus, making it relatively easy to achieve just enough traction on the drive wheels (6) for the intended application, without compromising safety and with a minimum impact on the overall energy efficiency of the mobile robot (1). The mobile robot (1) is configurable for different applications including transportation of goods loaded on top of the mobile robot (1), cart pulling or automated hauling of materials indoors.

The present invention relates to a basic mobile robot (1) where the weight on the drive wheels (6) can be adjusted in order to achieve the optimal traction and braking performance of the mobile robot (1) for the relevant application. With the inventive design of the bogie arm (4) and the modular traction weights (9), the gravitation forces and resulting friction acting on the drive wheels (6) can be increased by attaching one or more traction weight modules (13) to the bogie arm extensions (12), while due to the cantilever effect, the resulting gravitation forces acting on the (front) caster wheels (7) are decreased. Thus, making it relatively easy to achieve just enough traction on the drive wheels (6) for the intended application, without compromising safety and with a minimum impact on the overall energy efficiency of the mobile robot (1). The mobile robot (1) is configurable for different applications including transportation of goods loaded on top of the mobile robot (1), cart pulling or automated hauling of materials indoors.

A military vehicle include 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 first motor is positioned to facilitate selectively driving the plurality of accessories. The second driver includes a second motor electrically coupled to the energy storage system.

A military vehicle include 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 first motor is positioned to facilitate selectively driving the plurality of accessories. The second driver includes a second motor electrically coupled to the energy storage system.

An automated guided vehicle includes a main frame (1) and a sub-frame (2); wherein, a driving wheel assembly (11) is mounted on the main frame (1), a driven wheel assembly (21) or a driving wheel (11) is mounted on the sub-frame (2), and the main frame (1) is hinged to the sub-frame (2).

A magnetorheological damper, wherein the damper comprises a housing that is at least partially filed with a magnetorheological fluid, and a magnetorheological valve disposed within the housing. The valve includes a magnetically permeable core having at least one coil reservoir formed therein, and at least one conductor coil, wherein each conductor coil is disposed around a portion of the core within a respective one of the coil reservoir(s). The valve additionally includes a fluid flow path adjacent the conductor coil(s). The fluid flow path is structured and operable to allow the magnetorheological fluid to flow adjacent the conductor coil(s). The valve further includes at least one coil cover, wherein each coil cover is disposed over a respective one of the coil(s) such that the respective coil is protected from exposure to magnetorheological fluid flowing through the fluid flow path.

A panel includes a standoff formed from a wall extended in a height direction from an exterior surface of the panel. The wall is formed from a first wall section and a second wall section that is offset from the first wall section in a lateral direction of the panel along the exterior surface of the panel. A stopper hole is defined in the panel and extended in the height direction, in parallel with the first wall section and the second wall section, from the exterior surface of the panel. The stopper hole receives a stopper. The stopper hole is interposed between and separates the first wall section and the second wall section along the exterior surface of the panel, or is offset from the wall of the standoff in the lateral direction of the panel along the exterior surface of the panel.

A panel includes a standoff formed from a wall extended in a height direction from an exterior surface of the panel. The wall is formed from a first wall section and a second wall section that is offset from the first wall section in a lateral direction of the panel along the exterior surface of the panel. A stopper hole is defined in the panel and extended in the height direction, in parallel with the first wall section and the second wall section, from the exterior surface of the panel. The stopper hole receives a stopper. The stopper hole is interposed between and separates the first wall section and the second wall section along the exterior surface of the panel, or is offset from the wall of the standoff in the lateral direction of the panel along the exterior surface of the panel.

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.