A sub-frame includes: a main body portion that has a vehicle body support portion supported by a vehicle body; and a reinforcement plate that is attached to a bottom surface of the main body portion. The main body portion includes a torque rod support portion which supports a torque rod coupled to a power unit. The torque rod support portion has a first shaft support portion which supports one end of a shaft supporting the torque rod, a first opening portion into which the torque rod is able to be inserted, and a second opening portion which is formed below the first shaft support portion. The reinforcement plate has a second shaft support portion supporting the other end of the shaft and covers the second opening portion from below.

A sub-frame includes: a main body portion that has a vehicle body support portion supported by a vehicle body; and a reinforcement plate that is attached to a bottom surface of the main body portion. The main body portion includes a torque rod support portion which supports a torque rod coupled to a power unit. The torque rod support portion has a first shaft support portion which supports one end of a shaft supporting the torque rod, a first opening portion into which the torque rod is able to be inserted, and a second opening portion which is formed below the first shaft support portion. The reinforcement plate has a second shaft support portion supporting the other end of the shaft and covers the second opening portion from below.

A vehicle body with a shell-type design includes at least one lateral frame, a tailgate frame which is connected to a node of the vehicle body by the lateral frame, and a reinforcing component which extends from the tailgate frame into the lateral frame. The tailgate frame and the lateral frame are each composed of an upper shell and a lower shell, and the reinforcing component is arranged between the upper and lower shells of the tailgate frame and the lateral frame. A hinge reinforcement for a hinge of a tailgate is formed in the reinforcing component in the region of the tailgate frame.

A vehicle body with a shell-type design includes at least one lateral frame, a tailgate frame which is connected to a node of the vehicle body by the lateral frame, and a reinforcing component which extends from the tailgate frame into the lateral frame. The tailgate frame and the lateral frame are each composed of an upper shell and a lower shell, and the reinforcing component is arranged between the upper and lower shells of the tailgate frame and the lateral frame. A hinge reinforcement for a hinge of a tailgate is formed in the reinforcing component in the region of the tailgate frame.

A work vehicle includes a chassis; a primary wheel carried by the chassis; and a caster assembly carried by the chassis. The caster assembly includes a pivotable swivel structure defining a caster angle; and a caster wheel swivelly linked to the swivel structure and defining a wheelbase relative to the primary wheel. A change in the wheelbase passively causes the swivel structure to pivot and change the caster angle.

In a suspension support bracket including a bracket body including a suspension attachment portion configured such that a shock absorber of a suspension device of a vehicle is attached to the suspension attachment portion, the bracket body is constructed of a single metal plate, and thickness dimensions of a region of the suspension attachment portion of the bracket body and a periphery of the suspension attachment portion are larger than a thickness dimension of another region adjacent to the region of the suspension attachment portion and periphery of the suspension attachment portion.

In one embodiment, a storage system includes one or more platforms to stow compute units of an autonomous or semi-autonomous vehicle in a storage compartment of the vehicle. The platform is configured to support a compute unit of the vehicle to avoid a crumple zone of the vehicle. The crumple zone of the vehicle is designed to crumple when colliding with an object. The storage system also includes one or more shear fasteners configured to fasten the compute unit to the platform. The one or more shear fasteners are configured to break in a predetermined direction in response to a predetermined amount of lateral force. The breakage of the one or more shear fasteners decouples the compute unit from the platform in a controlled direction.

In one embodiment, a storage system includes one or more platforms to stow compute units of an autonomous or semi-autonomous vehicle in a storage compartment of the vehicle. The platform is configured to support a compute unit of the vehicle to avoid a crumple zone of the vehicle. The crumple zone of the vehicle is designed to crumple when colliding with an object. The storage system also includes one or more shear fasteners configured to fasten the compute unit to the platform. The one or more shear fasteners are configured to break in a predetermined direction in response to a predetermined amount of lateral force. The breakage of the one or more shear fasteners decouples the compute unit from the platform in a controlled direction.

A modular frame system for a sugarcane harvester includes a base frame section having a forward end and an aft end, with the base frame section defining a forward interface portion at the forward end. The system also includes a plurality of interchangeable front frame sections configured to be removably coupled to the base frame section, with each front frame section having a unique frame arrangement as compared to the remainder of the interchangeable front frame sections such that each front frame section is adapted to provide a differing harvesting configuration for the sugarcane harvester when selected for installation on the base frame section. Moreover, each front frame section includes a front end and a rear interface end, with the rear interface ends of the interchangeable front frame sections defining a common interface portion configured to be coupled to the forward interface portion of the base frame section.

A modular frame system for a sugarcane harvester includes a base frame section having a forward end and an aft end, with the base frame section defining a forward interface portion at the forward end. The system also includes a plurality of interchangeable front frame sections configured to be removably coupled to the base frame section, with each front frame section having a unique frame arrangement as compared to the remainder of the interchangeable front frame sections such that each front frame section is adapted to provide a differing harvesting configuration for the sugarcane harvester when selected for installation on the base frame section. Moreover, each front frame section includes a front end and a rear interface end, with the rear interface ends of the interchangeable front frame sections defining a common interface portion configured to be coupled to the forward interface portion of the base frame section.