A frame system for a vehicle including a high-voltage component that includes a pair of spaced apart primary rails that extend from a front of the vehicle toward a rear of the vehicle and a pair of longitudinally extending sills. An impact support rail extends outward from each of the primary rails, and connects each respective primary rail to one of the sills. A cross-member extends outward from each of the primary rails, and connects each respective primary rail to one of the sills, and a laterally extending frame support member extends between the sills at a location between the impact support rails and the cross-members. A pocket is collectively formed between each primary rail, the respective impact support rail, the respective sill, the respective cross-member, and the laterally extending frame support member, and the pocket is configured for receipt and protection of the high-voltage component.

An apparatus for locking chassis frames includes a locking assembly configured to be positioned at one end of a first chassis frame; and a receiving unit configured to be positioned in a second chassis frame corresponding to the first chassis frame in a longitudinal direction, and configured such that at least a part of the locking assembly is configured to be inserted into the receiving unit. The locking assembly includes a cylinder housing configured to be positioned in the first chassis frame, a locking unit moved in the cylinder housing, and a first switch part positioned at one end of the cylinder housing, and configured to drive a fluid pressure unit when the second chassis frame comes into contact with the first chassis frame.

In a vehicle body structure configured to place a battery in a lower part of a cabin, the loading of a frontal crash and a rear end crash that may be applied to the battery is minimized. The vehicle body structure (1), comprises a pair of side sills (3) extending in a fore and aft direction on either side of a vehicle (2), a pair of front side frames (4) extending in the fore and aft direction along either side of a front part of the vehicle, and connected to front ends of the side sills at rear ends thereof, respectively, a pair of rear side frames (71) extending in the fore and aft direction along either side of a rear part of the vehicle, and connected to rear ends of the side sills at front ends thereof, respectively, a front subframe (6) attached to the front side frames, a rear subframe (72) attached to the rear side frames, and a battery (140) positioned in a region surrounded by the side sills, the front subframe and the rear subframe in plan view.

In a vehicle body structure configured to place a battery in a lower part of a cabin, the loading of a frontal crash and a rear end crash that may be applied to the battery is minimized. The vehicle body structure (1), comprises a pair of side sills (3) extending in a fore and aft direction on either side of a vehicle (2), a pair of front side frames (4) extending in the fore and aft direction along either side of a front part of the vehicle, and connected to front ends of the side sills at rear ends thereof, respectively, a pair of rear side frames (71) extending in the fore and aft direction along either side of a rear part of the vehicle, and connected to rear ends of the side sills at front ends thereof, respectively, a front subframe (6) attached to the front side frames, a rear subframe (72) attached to the rear side frames, and a battery (140) positioned in a region surrounded by the side sills, the front subframe and the rear subframe in plan view.

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 center upper frame nodal connection fabrication comprising a top surface, a bottom surface opposite the top surface, two side surfaces, a front surface having a plurality of integral planes oriented at angles relative to each other, and a rear surface opposite the front surface. The top surface, the bottom surface, and the two side surfaces can be weldably attached to each other and the front and rear surfaces to form a structure of the center upper frame nodal connection fabrication. The integral planes of the front surface are configured to weldably attach to respective elongate support members of a space frame. The rear surface is configured to weldably attach to a center upper frame connection casting of the space frame.

A center upper frame nodal connection fabrication comprising a top surface, a bottom surface opposite the top surface, two side surfaces, a front surface having a plurality of integral planes oriented at angles relative to each other, and a rear surface opposite the front surface. The top surface, the bottom surface, and the two side surfaces can be weldably attached to each other and the front and rear surfaces to form a structure of the center upper frame nodal connection fabrication. The integral planes of the front surface are configured to weldably attach to respective elongate support members of a space frame. The rear surface is configured to weldably attach to a center upper frame connection casting of the space frame.

An on-board electronics system of an aerial work platform moves the wheels between a retracted and extended position by pivoting a respective arm. The method comprises the following successive steps: a) orienting each wheel tangentially to the pivoting path of the corresponding arm, b) moving the wheel by pivotally actuating the corresponding arm, and c) reorienting the wheel so as to enable another translation of the aerial work platform. The steps are performed in different orders between the wheels so that at any time at least one of the following conditions is complied with: —the brake system of at least one wheel is active, —at least one wheel is rotated by a motorised drive, —the orientation of the wheels relative to one another prevents any translation of the aerial work platform (1) on the ground as a result of gravitational force.

An on-board electronics system of an aerial work platform moves the wheels between a retracted and extended position by pivoting a respective arm. The method comprises the following successive steps: a) orienting each wheel tangentially to the pivoting path of the corresponding arm, b) moving the wheel by pivotally actuating the corresponding arm, and c) reorienting the wheel so as to enable another translation of the aerial work platform. The steps are performed in different orders between the wheels so that at any time at least one of the following conditions is complied with: —the brake system of at least one wheel is active, —at least one wheel is rotated by a motorised drive, —the orientation of the wheels relative to one another prevents any translation of the aerial work platform (1) on the ground as a result of gravitational force.