The invention relates to a vehicle frame comprising first and second parallel frame rails and multiple cross-members connecting the frame rails, wherein the vehicle frame has at least one cross-member with an integrated fluid tank. The at least one cross-member and fluid tank comprises an intermediate tank section with open end portions, where each end portion comprises a sealing flange; tank end caps attachable to seal opposite end portions of the intermediate tank section; wherein each end cap comprises an end cap sealing flange facing a corresponding tank sealing flange at opposite end portions of the intermediate tank; and wherein each tank end cap is provided with a mounting plate facing away from the intermediate tank section, which mounting plate is arranged to be attached to a frame rail.

The invention relates to a vehicle frame comprising first and second parallel frame rails and multiple cross-members connecting the frame rails, wherein the vehicle frame has at least one cross-member with an integrated fluid tank. The at least one cross-member and fluid tank comprises an intermediate tank section with open end portions, where each end portion comprises a sealing flange; tank end caps attachable to seal opposite end portions of the intermediate tank section; wherein each end cap comprises an end cap sealing flange facing a corresponding tank sealing flange at opposite end portions of the intermediate tank; and wherein each tank end cap is provided with a mounting plate facing away from the intermediate tank section, which mounting plate is arranged to be attached to a frame rail.

A platform structure for an electric vehicle is proposed. More particularly, according to the platform structure for an electric vehicle, a frame configured by coupling pipes to each other to form a lattice structure is installed to have a vertical double structure, and each pipe constituting an upper frame and each pipe constituting a lower frame intersect with each other such that rigidity of the platform structure is secured and the manufacturing period thereof due to easy manufacturing is decreased to reduce manufacturing cost. The platform structure for an electric vehicle includes a frame of the platform structure configured in such a manner that pipes are coupled to each other by brackets to form a lattice structure.

A platform structure for an electric vehicle is proposed. More particularly, according to the platform structure for an electric vehicle, a frame configured by coupling pipes to each other to form a lattice structure is installed to have a vertical double structure, and each pipe constituting an upper frame and each pipe constituting a lower frame intersect with each other such that rigidity of the platform structure is secured and the manufacturing period thereof due to easy manufacturing is decreased to reduce manufacturing cost. The platform structure for an electric vehicle includes a frame of the platform structure configured in such a manner that pipes are coupled to each other by brackets to form a lattice structure.

A rod-end front suspension is provided for an off-road vehicle. The rod-end front suspension comprises a spindle assembly that is pivotally coupled with an upper suspension arm by way of a first rod-end joint and pivotally coupled with a lower suspension arm by way of a second rod-end joint. A steering rod-end joint coupled with the spindle assembly pivotally receives a steering rod. An axle assembly coupled with the spindle assembly conducts torque from a transaxle to a wheel coupled with the spindle assembly. Each of the first and second rod-end joints comprises a ball rotatably retained within a casing. The ball is fastened within a recess between parallel prongs extending from the spindle assembly. A threaded shank extending from the casing is threadably fixated with the suspension arm, such that the spindle assembly may be moved with respect to the casing and the suspension arm.

A rod-end front suspension is provided for an off-road vehicle. The rod-end front suspension comprises a spindle assembly that is pivotally coupled with an upper suspension arm by way of a first rod-end joint and pivotally coupled with a lower suspension arm by way of a second rod-end joint. A steering rod-end joint coupled with the spindle assembly pivotally receives a steering rod. An axle assembly coupled with the spindle assembly conducts torque from a transaxle to a wheel coupled with the spindle assembly. Each of the first and second rod-end joints comprises a ball rotatably retained within a casing. The ball is fastened within a recess between parallel prongs extending from the spindle assembly. A threaded shank extending from the casing is threadably fixated with the suspension arm, such that the spindle assembly may be moved with respect to the casing and the suspension arm.

A cab chassis vehicle and a method of assembling a cab-chassis vehicle are provided. A chassis is sub-assembled by connecting a mounting bracket for a truck body to a frame rail via a fastener, installing a chassis-side vehicle harness, and installing a chassis-side body wiring harness. A cab is sub-assembled by installing a connector plate to cover an aperture on an outer panel of the cab, installing a cab-side body wiring harness, connecting the cab-side body wiring harness to the connector plate, and installing a cab-side vehicle harness. The cab is assembled to the chassis to provide a cab-chassis vehicle by connecting the chassis-side body wiring harness to the connector plate, connecting the chassis-side vehicle harness to the cab-side vehicle harness.

A modular robot with a drive platform including: a first lateral drive module having at least two wheels and at least one motor for driving at least one of the wheels, a second lateral drive module having at least one wheel and at least one motor for driving the at least one wheel, a front crossmember module connecting first ends of the first and the second lateral drive module, and a rear crossmember module connecting first ends of the first and the second lateral drive module. One of the two lateral drive modules has a control unit for controlling the motors of the two lateral drive modules. The two drive modules have first connecting devices at their respective ends and the two crossmember modules have second connecting devices in the region of their respective ends. The first and the second connecting devices have mechanical connections. At least one of the two drive modules has at least one docking device for docking an application unit on the drive platform and the at least one docking device has mechanical and/or electrical connections.

A front bolster and frame connection system for an intermodal chassis including a front bolster, a front gooseneck frame extending from the intermodal chassis having beams, mounting tabs attached to the front bolster, mounting tabs attached to the front gooseneck frame, a front gooseneck frame mounting plate welded to the end of the front end of the front gooseneck frame, and angle braces attached to the mounting tabs. The angle braces connect the bolt on front bolster and the front gooseneck frame. A retrofit kit and an alternate embodiment are also provided. The bolt on front bolster design of the present invention requires minimal cutting or grinding to remove and minimal welding to replace. The bolt on front bolster adds considerable value to operators in the intermodal market by facilitating service and eliminating chronic issues.

At least one machine configuration system provides formation of machines/tools in order to realize different works by means of various components and equipment which can be essentially fixed onto and removed from at least one body having at least one drive element, at least one wheel which is moved by said drive element, and at least one chassis whereon said wheel and the drive element are positioned. The novel side of the machine configuration is that in order to transfer any item from one location to another location, there is essentially at least one platform which is positioned at the upper vicinity of said body.