In a vehicle to which the present joining structure of vehicle steel plates is applied, a third welded portion is set between a first welded portion and a second welded portion, wherein at the first welded portion, a pillar outer rear flange, an SM outer rear flange, a pillar inner rear flange are joined to one another; and at the second welded portion, the pillar outer rear flange and the pillar inner rear flange are joined to each other. At the third welded portion, the pillar outer rear flange and the SM outer rear flange are joined to each other. Accordingly, a tensile load F acting on the pillar outer rear flange is distributed toward the SM outer rear flange side.

A vehicle lower body structure can include: a side sill that forms a first closed cross section extending in a body front-rear direction; and a reinforcing member provided in the first closed cross section to reinforce a front end portion of the side sill. The reinforcing member can have: a front-end reinforcing section that supports a collision load applied to the front end portion of the side sill and directed rearward in a vehicle body; a deformation permission section that permits deformation of the side sill directed inward in a vehicle width direction and rearward at the time when the collision load directed inward in the vehicle width direction and rearward is applied to the front end portion of the side sill; and a deformation suppression section suppressing deformation of the side sill after the deformation of the side sill directed inward in the vehicle width direction and rearward.

A module carrier assembly for positioning between the A-pillars of a motor vehicle body comprising a transverse carrier configured as a hollow body profile and at least one steering column holder connected to the transverse carrier and supported at the outer side of the transverse carrier in the x-direction. The at least one steering column holder is configured as an angle piece and is supported by a support surface provided by a first limb at a first outer wall of the transverse carrier. The steering column holder has a further limb extending below the transverse carrier. The steering column holder carries a support projection which extends through the outer wall of the transverse carrier adjoining the support surface of the steering column holder and up to at least the opposite wall of the transverse carrier. The support projection is connected in a vibration-coupled manner to this opposite wall.

A joining structure includes a first member, a second member of a material different from that of the first member, and a separation mechanism provided between the first member and the second member and that separates the first member and the second member from each other, wherein a resin is filled into the space between the edge of at least one member among the first member and the second member, and the other member.

Unit with longitudinal beam and front plate for a motor-vehicle front structure, comprising a longitudinal beam in the form of a hollow profile and a front plate rigidly connected to a front end of said longitudinal beam. The longitudinal beam comprises a first beam element defining an upper wall, a lower wall and a first side wall of the longitudinal beam and a second beam element having a wall defining a second side wall of the longitudinal beam. The front plate has a rear face facing towards the longitudinal beam to which there are welded a first flange and a second flange which are separate from each other, for connecting the front end of the longitudinal beam. The first flange is a C-shaped bracket with an upper wall, a lower wall and a side wall respectively welded to the upper wall, the lower wall and the first side wall defined by said first beam element. The second flange is an L-shaped bracket, with a first wall welded to the rear face of the front plate and a second wall facing towards said second side wall defined by said second beam element. The above mentioned welds are electric spot welds. The two flanges may have different thickness.

The invention provides a method of assembling a roof of a cargo body. A plurality of sidewalls are provided, each comprising a side panel and an upper rail coupled to the side panel. A roof panel is located above the plurality of sidewalls adjacent the upper rails. A roof bow extends between the upper rails below the roof panel. The roof bow is fixed to a track of one of the upper rails with a fastener.

A method for manufacturing a unitary body side structural frame for a vehicle is provided. The method comprises providing a plurality of blanks, joining the blanks to each other to form a composite blank wherein joining the blanks includes forming one or more overlapping regions formed by partially overlapping two blanks and deforming the composite blank to form the unitary body side structural frame. A unitary body side structural frame as obtained by any of the methods herein described is also provided.

A body for a passenger car has a body-in-white structure which is located behind a wheel well for a front wheel of the passenger car and which has a transverse member that extends on the outside of a longitudinal beam of the body-in-white structure in front of a front end wall of the body-in-white structure in the vehicle transverse direction. The transverse member has a catch element which is designed to catch a rim of the front wheel that has moved backwards in the vehicle longitudinal direction in the event of an accident and is turning in rearward towards the vehicle center. The body-in-white structure has an A-pillar located behind the catch element, a lateral sill located behind the catch element, and a support element which is located in the A-pillar and via which the catch element that has moved backwards in the event of an accident and, via the catch element, the rim that has moved backwards in the event of an accident, can be supported towards the rear on the lateral sill.

A vehicle front portion structure includes: a battery case that is installed beneath a floor of a vehicle; front side members that extend in a vehicle longitudinal direction further toward a vehicle front side than the battery case; side rails that structure portions of a suspension member that is disposed further toward the vehicle front side, and that extend in the vehicle longitudinal direction; first connecting members that connect the battery case and the front side members; and second connecting members that connect a vehicle longitudinal direction front end portion of the battery case and vehicle longitudinal direction rear ends of the side rails, that face the battery case in the vehicle longitudinal direction as seen in a plan view and in a side view, and that face the side rails in the vehicle longitudinal direction as seen in a plan view and in a side view.

The present teachings generally relate to a structural reinforcement, a body member comprising the structural reinforcement, and a method of using the structural reinforcement. The structural reinforcement comprises a first wall, a second wall extending from a first side of the first wall. Spacer legs extend from a second side of the first wall and define a first channel Spacer legs extend from a second side of the second wall and define a second channel The structural reinforcement is configured to reinforce a joint.