A gutter member has a flow path portion that receives the water dripping from a front windshield and flows the received water in the vehicle width direction and a drain portion that drains the water to a drain member on the inner side in the vehicle width direction of the flow path portion, in which at least a part of the flow path portion overlaps with the drain path in vehicle plan view, the gutter member has guide portions that guide the water dripping from the drain portion to the drain path, and the guide portions, include a cushioning material that absorbs an impact load at least in the vertical direction.

The present disclosure is directed to extrusion for a vehicle component. The vehicle component includes a plurality of flanges that form a periphery of the vehicle component, a cavity that extends through the periphery of the vehicle component, a corner portion that is positioned proximate to a corner defined by a pair of the plurality of flanges, and a channel that is positioned proximate to the corner portion.

Both weight reduction and impact resistance of a center pillar are satisfied while increase in cost is suppressed. A center pillar inner 20 is configured to include: an inner member 21 having an opening 21a to be a place where a retractor of a seat belt is mounted and a side sill mounting portion 21b to be a place where a side sill 30 is mounted; and a CFRP member 22 joined to a surface of the inner member 21, wherein the CFRP member 22 is provided at least between the opening 21a and the side sill mounting portion 21b.

The invention relates to a motor vehicle component 1, in particular a B pillar and similar shaped components. The motor vehicle component 1 has a shaped, in particular hot-formed or cold-formed, base member 2 of sheet steel. The base member 2 has a surface portion 3 which is provided with holes 7. According to the invention, the surface portion 3 has a tensile strength Rm greater than or equal to (≥) 1250 MPa. A hole pattern 6 which comprises at least three holes 7 forms a deformation influence zone 8 in the surface portion 3. The surface portion of the holes 7 in the surface portion 3 is between 7% and 60% and the holes 7 have a diameter d of up to 30p mm.

Rocker structure (R1-R3) for a vehicle comprising a first steel profile (1) and a second steel profile (2) having the longitudinal direction (L) of the vehicle so that a channel (CH) is defined therebetween, the first and second profiles(1, 2) comprising a vertical central section (13), the rocker structure (R1-R3) comprising a first impact absorption element (3) arranged in the channel (CH), wherein the first impact absorption element (3) is a closed steel profile wherein an upper lobe (31) and a lower lobe (32) joined by a central joining section (33) are defined, the upper lobe (31) being located closer to the upper joining flanges (11, 21), the lower lobe (32) closer to the lower joining flanges (21, 22). The invention also relates to a method for obtaining the rocker structure and to vehicles provided with the inventive rocker structure.

A stiffened panel structure includes a panel-shaped component and a wire. The panel-shaped component has a panel body that curves in such a manner as to be convex outward. The wire has a first end portion and a second end portion. The first end portion is bonded to a first point on the inner surface of the panel body. The second end portion is bonded to a second point on the inner surface of the panel body. The wire is strained between the first point and the second point.

A flooring member comprising: a structural member having one or more ducts extending along a length of the flooring member, each of the one or more ducts forming a hollow cavity extending along a length of each duct, the one or more ducts being integrally formed with the flooring member.

A structural reinforcement for an article including a carrier that includes: (i) a mass of polymeric material having an outer surface; and (ii) at least one consolidated fibrous insert (14) having an outer surface and including at least one elongated fiber arrangement having a plurality of ordered fibers arranged in a predetermined manner. The fibrous insert is envisioned to adjoin the mass of the polymeric material in a predetermined location for carrying a predetermined load that is subjected upon the predetermined location (thereby effectively providing localized reinforcement to that predetermined location). The fibrous insert and the mass of polymeric material are of compatible materials, structures or both, for allowing the fibrous insert to be at least partially joined to the mass of the polymeric material. Disposed upon at least a portion of the carrier may be a mass of activatable material.

A shock absorbing member which can increase impact absorption energy and also enables thinning of a steel sheet that is a starting material, a method for producing the shock absorbing member, and a method for producing a steel sheet for cold plastic working are provided. The shock absorbing member includes a ridge portion formed in a curved shape as viewed from a longitudinal direction, and a wall portion extending from the ridge portion. In the wall portion, a ratio σ.sub.5/τ.sub.5 between a tensile stress σ.sub.5 when an elongation in a tensile test is 5% and a shear stress τ.sub.5 when a shear strain in a shear test is 5√3% is 1.70 or less, or a ratio σ.sub.10/τ.sub.10 between a tensile stress σ.sub.10 when an elongation in a tensile test is 10% and a shear stress τ.sub.10 when a shear strain in a shear test is 10√3% is 1.70 or less.

A transporter includes a frame supported on wheels, a cab mounted on a front portion of the frame, and a bed mounted on the rear portion of the frame. The bed includes deck plates and supports mounting the deck plates on the frame. At least a rear end portion of the bed is raiseable and lowerable relative to the frame. The bed is sufficiently lightweight that the transporter has a hauling capacity of at least 10,000 lbs. and a fully loaded gross vehicle weight of no more than 26,000 lbs. At least portions of the bed may be made from high strength steel (HSS) such as ASTM A1011/1011M steel having a grade of 80 or higher. A ramp, which may also be made of HSS, may be attachable to the rear of the bed and may have longitudinally extending supports and slats that may be arranged in a herringbone pattern.