A safety cabin for a mobile home or motor home includes walls of the safety cabin including at least one layer of a fibre-reinforced plastic woven fabric and/or non-woven fabric. A layer includes plies arranged consecutively along a transverse direction with different fibre orientations. A layer is provided in the lateral external walls in each of a front region and rear region of the cabin. An intermediate wall at a transition from the front region of the cabin to the rear region of the cabin is arranged transversely to a longitudinal direction of the cabin, with the intermediate wall preferably comprising a layer including three to nine plies. Similarly, the invention relates to a manufacturing method for the safety cabin according to the invention.

A vehicle body reinforcement structure includes an elongated hollow structure formed by jointing an outer panel and an inner panel with each other, and a reinforcement member configured to partition the hollow structure into a lower closed cross section and an upper closed cross section. At inside of at least one of the lower closed cross section and the upper closed cross section, at least a pair of bulkheads extending so as to cross the closed cross section are disposed so as to be separated with each other in a direction in which the closed cross section is extending. A space between the pair of bulkheads is made as a filler chamber which is filled with filler. A filling opening for the filler is provided on the inner panel so that the filling opening is in communication with the filler chamber.

A rocker panel molding includes an outer panel including a front integral hinge that is bendable along a first straight line extending along a vehicle length on a lower end of a front portion of the outer panel and a rear integral hinge that is bendable along a second straight line extending along the vehicle length on a lower end of a rear portion of the outer panel, a front foldable panel configured to be folded at the front integral hinge and fixed to a rocker panel, and a rear foldable panel configured to be folded at the rear integral hinge and fixed to the rocker panel.

An automotive vehicle has a skateboard platform and a vehicle body that is attached to the skateboard platform or chassis. The sides of the vehicle body are formed using a structural frame, made up of multiple structural sub-frames that give structural integrity to the sides of the vehicle body and to which body panels are attached. Each structural sub-frame is directly attached to the skateboard platform or chassis.

An automotive vehicle has a skateboard platform and a vehicle body that is attached to the skateboard platform or chassis. The sides of the vehicle body are formed using a structural frame, made up of multiple structural sub-frames that give structural integrity to the sides of the vehicle body and to which body panels are attached. Each structural sub-frame is directly attached to the skateboard platform or chassis.

A structural mount assembly for a roof panel of a vehicle. The structural mount assembly includes an exterior bracket and a plurality of interior brackets. The exterior bracket is secured to an exterior surface of the roof panel. The exterior bracket includes a plurality of stanchions for mounting a sensor structure. The plurality of interior brackets are disposed on an interior surface of the roof panel and being secured to the exterior bracket through the roof panel.

A front pillar substructure that enables reduction in deformation of a front pillar. One embodiment of the present disclosure provides a front pillar substructure including a front pillar, and a rocker being joined to the front pillar. The front pillar includes an inner panel located inside with respect to the rocker, and an outer panel arranged so as to interpose the rocker between the inner panel and the outer panel. The outer panel includes an upper panel, and a lower panel overlapped with and joined to the upper panel, the lower panel extending downward with respect to the upper panel. The upper panel or the lower panel includes a bent section bending in the width direction when viewed from the front-rear direction, the bent section being located inside with respect to a joint region where the upper panel and the lower panel are joined.

A structural assembly for use in an electric vehicle having a lower body frame and a battery pack secured within the lower body frame. The structural assembly includes a subframe rear mount, a battery cage longitudinal member, a rocker, a hinge pillar, and a rail torque unit. The battery cage longitudinal member is secured to the subframe rear mount. The rocker extends along and is secured to the battery cage longitudinal member. The hinge pillar includes a lower portion that is secured to the rocker. The rail torque includes an s-brace and an inner rail. The s-brace is secured to the hinge pillar at one end and to the inner rail at another end. The inner rail is secured to the hinge pillar at one end and is configured to extend around a wheel of the electric vehicle and form a portion of a wheel well.

A vehicle-body structure of an electric automotive vehicle comprises floor-side cross members attached to a floor panel and extending in a vehicle width direction along the floor panel and battery-side cross members provided at a battery case and extending in the vehicle width direction. The floor-side cross members and the battery-side cross members are offset from each other in a vehicle longitudinal direction in a vehicle side view.

A vehicle-body structure comprises right-and-left front side frames and right-and-left frame members respectively extending forward from a vehicle-front portion of a battery case below the right-and-left front side frames. Plural right-side connection portions to connect the right-side frame member to the right-side front side frame are provided to be spaced apart from each other in a vehicle longitudinal direction.