A military vehicle includes a passenger capsule, a front module coupled to a front end of the passenger capsule, and a rear module coupled to a rear end of the passenger capsule. The passenger capsule has a frame rail-less monocoque hull structure. The front module includes a first longitudinal frame member coupled to the front end of the passenger capsule proximate a first side thereof, a second longitudinal frame member coupled to the front end of the passenger capsule proximate an opposing second side thereof, and an underbody support structure coupled to the front end of the passenger capsule, the first longitudinal frame member, and the second longitudinal frame member. The underbody support structure is positioned beneath the first longitudinal frame member and the second longitudinal frame member.

A military vehicle includes a passenger capsule having a front end and a rear end, a front module coupled to the front end, and a rear module coupled to the rear end. The front module includes a front axle, a front differential, an engine, and a transmission. The front differential is coupled to the front axle. The front differential functions as a structural component of the front module. The front differential defines an engine mount. The engine is at least partially supported by the engine mount of the front differential. The transmission is coupled to the engine. The rear module includes a rear axle and a transaxle. The transaxle includes a housing, a transfercase disposed within the housing, and a rear differential disposed within the housing. The transfercase is coupled to the transmission, the front differential, and the rear differential. The rear differential is coupled to the rear axle.

The present disclosure relates to the field of engineering vehicles, and, a cab frame, a cab and an engineering vehicle. A cab frame provided by the present disclosure includes a support framework, where the support framework includes a bottom frame, a top frame, and a four-upright-column structure supported between the bottom frame and the top frame; the four-upright-column structure includes two front upright columns and two rear upright columns, and an inner dimension of the cab frame increases along the bottom-to-top direction. As the cab frame is configured into a four-upright support structure with a large upper portion and a small lower portion, the cab is provided with a smaller dimension of the lower portion, a larger dimension of the upper portion, and fewer uprights at the same time, which reduces visual field obstruction arising from a baseplate and uprights and provides sufficient movement space for an operator head.

A floor mat arranged in a working machine includes a floor portion, a wall portion arranged on a circumferential portion of the floor portion, and an opening portion arranged on a part of a connecting portion of the wall portion, the connecting portion connecting to the floor portion. The floor mat includes a mat main body arranged on the floor portion, a covering portion configured to cover the opening portion, and an connecting portion configured to connect the covering portion flexibly to a circumferential portion of the mat main body.

A working vehicle includes a position detector to detect a position of a vehicle body based on a signal transmitted from a positioning satellite. A mounting stay pivotally supported by a base stay includes a counter surface that opposes an upper surface of the base stay when the position detector is in a first position. The position detector is movable from the first position to a second position according to rotation of the mounting stay causing the counter surface to face upward. When the position detector is in the second position, a front portion of the mounting stay is higher than an upper end of the roof and a rear portion of the mounting stay is lower than the upper end of the roof.

A position detector is supported to be movable between a first position and a second position lower than the first position. A mounting stay is below the position detector when the position detector is in the first position, and, when the position detector is rotated together with the mounting stay from a state in which the position detector is in the first position, the position detector is moved to the second position and the mounting stay is positioned above the position detector in the second position and covers over the position detector so as to restrain the automatic steering control.

A protection mechanism for a working vehicle includes a roof provided above an operator's seat, a pillar extending upward from a vehicle body and supporting the roof, a camera with a predetermined viewing direction, and a support stay which is connected to the pillar, orients the predetermined viewing direction of the camera sideways, and supports the camera below a peripheral portion of the roof. The protection mechanism includes a front pillar supporting a front portion of the roof and a rear pillar supporting a rear portion of the roof. The support stay is connected to the rear pillar.

A protection mechanism for a working vehicle includes a roof above an operator's seat and including a cutout extending along a top-bottom direction, and an electric device at least partially located in the cutout. The cutout has a dimension along a vehicle-body-width direction that is uniform or substantially uniform along a front-to-rear direction or increases in the front-to-rear direction. The cutout has a thickness along the top-bottom direction that decreases in the front-to-rear direction. The roof include, in an upper surface thereof, a first groove located on an opposite side of the cutout from the electric device and extending in a direction away from the cutout.

A work vehicle includes a link mechanism to be equipped with a work implement, a drive mechanism to drive the link mechanism to ascend and descend the work implement, and a control lever is to be operated to ascend and descend the work implement. The work vehicle includes a first displacement transmission mechanism, an additional operational mechanism, and a second displacement transmission mechanism. The first displacement transmission mechanism links the drive mechanism and the control lever to transmit a displacement of the control lever to the drive mechanism. The additional operational mechanism is configured to operate the control lever at a location apart from a position of the control lever. The second displacement transmission mechanism mechanically links the additional operational mechanism and the control lever without interposing the first displacement transmission mechanism to shift the control lever in accordance with an operation of the additional operational mechanism.

A working machine includes a load transmitting member including: an upper pillar part; an intermediate part extending to circumvent a window from a position above a lower corner of a window edge of the window and outer than the lower corner in a wall width direction to a position below the lower corner and inner than the lower corner in the wall width direction; and a beam part extending so as to be farther away from a wall side edge under the window. The upper pillar part, the intermediate part, and the beam part are continuous in this order so that a load applied to an upper portion of a cabin is transmitted to an upper frame. At least the intermediate part of the load transmitting member is made of a single member.