A vehicle-body structure for suppressing deformation of a lift gate opening is provided. Embodiments include a vehicle having a rear annular framework formed from a cross member, side braces, connecting members, and a rear header; a rear suspension on lower surfaces of side pillars in the same position as the cross member in a vehicle front-rear direction; and wheel well inner portions on the vehicle rear side with respect to the cross member, each having an upper end having a damper supporting portion for mounting a suspension damper. The side braces each connect a place near the cross member and a place near the damper supporting portion to each other in a vehicle up-down direction; and the connecting members each connect a place near each end portion of the rear header in a vehicle width direction and the place near the damper supporting portion to each other.

A vehicle-body structure for suppressing deformation of a lift gate opening is provided. Embodiments include a vehicle having a rear annular framework formed from a cross member, side braces, connecting members, and a rear header; a rear suspension on lower surfaces of side pillars in the same position as the cross member in a vehicle front-rear direction; and wheel well inner portions on the vehicle rear side with respect to the cross member, each having an upper end having a damper supporting portion for mounting a suspension damper. The side braces each connect a place near the cross member and a place near the damper supporting portion to each other in a vehicle up-down direction; and the connecting members each connect a place near each end portion of the rear header in a vehicle width direction and the place near the damper supporting portion to each other.

A system for protecting the body and frame of a vehicle from flying debris, particularly during a tire blowout includes a mounting apparatus configured to secure a protective shield, which may be a protective plate and/or fender, to an axle of a vehicle. In embodiments, the protective plate may be mounted to the axel via a mounting apparatus, and the fender may further be mounted to the mounting apparatus and/or protective plate. In some embodiments, the protective plate may be mounted directly to the axel, and the fender may further be mounted to the protective plate, whereby the plate may serve as the mounting apparatus.

A wheel-well closure system for a motor vehicle has a wheel-arch delimiting a wheel-well and a wheel mounted in the wheel-well, the system comprising: a support structure connected to the wheel-arch; and a cover connected to the support structure and covering the wheel-well; wherein the cover is made of a flexible material and is secured to the wheel arch; wherein the system comprises a continuous annular part secured to the wheel facing the cover and rotating with the wheel about a horizontal axis; and wherein the support structure comprises an arm extending radially in front of the continuous annular part and against the cover, a steering movement of the wheel about a vertical axis causing the continuous annular to push the support structure and stretch the cover outside the wheel-well.

A wheel-well closure system for a motor vehicle has a wheel-arch delimiting a wheel-well and a wheel mounted in the wheel-well, the system comprising: a support structure connected to the wheel-arch; and a cover connected to the support structure and covering the wheel-well; wherein the cover is made of a flexible material and is secured to the wheel arch; wherein the system comprises a continuous annular part secured to the wheel facing the cover and rotating with the wheel about a horizontal axis; and wherein the support structure comprises an arm extending radially in front of the continuous annular part and against the cover, a steering movement of the wheel about a vertical axis causing the continuous annular to push the support structure and stretch the cover outside the wheel-well.

A fender for a lawn mower having tire and wheel assemblies that are mounted to a yoke of a swivel caster assembly, whereby the yoke pivots through 360 degrees of rotation, includes an arcuate fender body. The fender body is attached to the yoke by a bracket so that it is rotatably carried by the rotating yoke. As such, the fender body is maintained at an optimal position relative to the mower tire and thereby provides desirable deflection of lawn clippings and other debris from the various operational components provided upon the mower deck. This prevents the premature wear of such operational components, thereby decreasing down time and reducing maintenance costs of the mower.

A method of forming a vehicle panel includes deforming a sheet metal workpiece between stamping tools to form a first and second edges that converge at a corner of the workpiece's main surface. The first edge is defined by a junction of the main surface and a first flange. The second edge is defined the main surface and a second flange. Forming the first and second edges includes deforming the workpiece so that the second flange has a first region bent to a first angle relative to the main surface and an unwinding region bent to an angle that unwinds from the first region as the second flange approaches the corner. The method includes deforming the workpiece between a second set of stamping tools that deform the first flange and the unwinding region of the second flange until the first and second flanges are bent greater than 90°.

A method of forming a vehicle panel includes deforming a sheet metal workpiece between stamping tools to form a first and second edges that converge at a corner of the workpiece's main surface. The first edge is defined by a junction of the main surface and a first flange. The second edge is defined the main surface and a second flange. Forming the first and second edges includes deforming the workpiece so that the second flange has a first region bent to a first angle relative to the main surface and an unwinding region bent to an angle that unwinds from the first region as the second flange approaches the corner. The method includes deforming the workpiece between a second set of stamping tools that deform the first flange and the unwinding region of the second flange until the first and second flanges are bent greater than 90°.

A mud flap mounting assembly and system is disclosed. A vehicle body and mud flap are provided as part of the overall system. Advantageously, a toollessly-operated mud flap clamp assembly is provided. The mud flap clamp assembly includes a plurality of mud flap clamp units installed on the vehicle body. Each of the plurality of mud flap clamp units includes a flap clamp bracket, a flap pressure plate, and a flap clamp. Each flap clamp bracket selectively engages a first side of the mud flap, and each flap pressure plate selectively engages a second side of the mud flap. Each flap clamp is operable to a first position such that a clamping force is applied to each respective flap pressure plate and such that the mud flap is frictionally engaged with and retained by each respective flap clamp bracket and each respective flap pressure bracket.

A vehicle includes a fender, a storage compartment, and a first retaining wall. The fender has an inner surface, an outer surface, and a through hole connecting the inner surface and the outer surface. The storage compartment has a bottom plate. The bottom plate of the storage compartment is located at a side of the outer surface of the fender and at least covers the through hole. The fender is located below the storage compartment in a top-bottom direction of the vehicle. The first retaining wall is disposed on the outer surface of the fender and surrounds at least a portion of the through. A portion of the first retaining wall is closer to a front of the vehicle than the through hole in a front-rear direction of the vehicle.