Disclosed are a chassis of an automated guided vehicle and an automated guided vehicle. The chassis includes a front frame (1) and a rear frame (2) that are engaged with each other in a hinged joint manner, so as to allow a relative folding between the rear frame (2) and the front frame (1). The relative folding enables the driving wheels and the driven wheels to touch the ground on a sunken road at the same time to prevent that only the driven wheels (10) touch the ground while the driving wheels (9) slip, and increases the approach angle of the chassis on a convex road to prevent the front end of the chassis from touching any obstacle, which improve the safety of the vehicle. Moreover, the damping device (3) restricts the folding angle of the front frame (1) and the rear frame (2) to prevent that the relative folding angle of the front frame (1) and the rear frame (2) is too large to realize the transport function, and damps the folding angle for reducing vibration.

Disclosed are a chassis of an automated guided vehicle and an automated guided vehicle. The chassis includes a front frame (1) and a rear frame (2) that are engaged with each other in a hinged joint manner, so as to allow a relative folding between the rear frame (2) and the front frame (1). The relative folding enables the driving wheels and the driven wheels to touch the ground on a sunken road at the same time to prevent that only the driven wheels (10) touch the ground while the driving wheels (9) slip, and increases the approach angle of the chassis on a convex road to prevent the front end of the chassis from touching any obstacle, which improve the safety of the vehicle. Moreover, the damping device (3) restricts the folding angle of the front frame (1) and the rear frame (2) to prevent that the relative folding angle of the front frame (1) and the rear frame (2) is too large to realize the transport function, and damps the folding angle for reducing vibration.

In accordance with the disclosure provision is made for a vehicle. The vehicle is characterized in that a vehicle chassis of this vehicle includes a roughly tubular frame, a gearbox housing and underbody paneling. The frame, the gearbox housing and the underbody paneling are connected in such a manner that they form the vehicle chassis and hence a load-bearing frame for engine, bodywork and/or payload.

A base frame for a reach truck includes a wheel arm subassembly with two wheel arms each having a front end and an opposing rear end. A load wheel receiver is positioned on each rear end and a counterweight is positioned at the front end of the wheel arms and coupled to the wheel arm subassembly by a plurality of screw connections. The plurality of screw connections comprise a first portion of screw connections and a second portion of screw connections. The first portion of screw connections each extend in a first direction and the second portion of the screw connections each extend in a second direction which is different from the first direction.

A chassis for a lift device includes a base, an arm coupled to the base and configured to support a tractive element, and a plate extending from the arm at an upward angle. The arm includes a steering actuator interface configured to support an end of a steering actuator for the tractive element. The plate is configured to extend past the steering actuator.

A chassis for a lift device includes a base, an arm coupled to the base and configured to support a tractive element, and a plate extending from the arm at an upward angle. The arm includes a steering actuator interface configured to support an end of a steering actuator for the tractive element. The plate is configured to extend past the steering actuator.

A track system for a vehicle has an attachment assembly mountable to a chassis of a vehicle and defining an attachment-assembly-pivotable connector pivot axis; a track assembly including a support frame disposed laterally outward from the attachment assembly, the support frame including a leading frame assembly and a trailing frame assembly, each frame assembly including a frame member connectable to the attachment assembly pivotable connector and a frame-suspension pivotable connector; at least one wheel-load-bearing connector, and at least one idler wheel being at least indirectly connected to the frame member via the at least one wheel-load-bearing connector. The track system further has a sprocket wheel, an endless track, and a suspension assembly having a forward suspension pivotable connector, a rearward suspension pivotable connector, and leading and trailing suspension members pivotably connected to the forward suspension pivotable connector and to the rearward suspension pivotable connector, and to a link.

Disclosed is an automobile chassis, which includes a chassis main beam, a chassis cross beam and a support cross beam. The quantity of the chassis main beams is two. The two chassis main beams are arranged in parallel. A section shape of the chassis main beam is “”, and the openings of the two chassis main beams are arranged opposite. The quantity of the support cross beams is more than one. All the support cross beams are arranged between the two chassis main beams. A length direction of the support cross beam is perpendicular to a length direction of the chassis main beam. The chassis cross beam is arranged at an end of the chassis main beam, and both ends of the chassis cross beam are respectively connected and fixed with the two chassis main beams.

A fire fighting vehicle comprising a frame member, a catch coupled with the frame member, and a rear assembly coupled to the frame member. The fire fighting vehicle further includes a cab rotatably coupled with the frame member and supported by a forward portion of the frame member. The cab includes a cab frame member coupled with the frame member, a cab cross-member coupled with the cab frame member, the cab cross-member extending laterally from the cab frame member, and a pin coupled with the cab cross-member. The fire fighting vehicle includes the catch coupled with the frame member rearward relative to the pin, and where in response to a force being applied to a front portion of the cab, the cab is configured to rotate about a lateral axis and the pin is configured to engage the catch.

A fire fighting vehicle comprising a frame member, a catch coupled with the frame member, and a rear assembly coupled to the frame member. The fire fighting vehicle further includes a cab rotatably coupled with the frame member and supported by a forward portion of the frame member. The cab includes a cab frame member coupled with the frame member, a cab cross-member coupled with the cab frame member, the cab cross-member extending laterally from the cab frame member, and a pin coupled with the cab cross-member. The fire fighting vehicle includes the catch coupled with the frame member rearward relative to the pin, and where in response to a force being applied to a front portion of the cab, the cab is configured to rotate about a lateral axis and the pin is configured to engage the catch.