A fiber-reinforced resin composite configured to be to be used for a vehicle body structure has a cylindrical shape and a longitudinal direction. The fiber-reinforced resin composite includes first fibers and second fibers. The first fibers are disposed along an axial direction of the cylindrical shape. The second fibers are wound over an entire circumferential surface along a direction intersecting the axial direction of the cylindrical shape. The number of the first fibers per unit area in a tensile surface that is to mainly receive tensile stress upon a collision of a vehicle body is larger than the number of the first fibers per unit area in a compressive surface that is to mainly receive compressive stress upon the collision of the vehicle body.

The present invention relates generally to a cavity filling system for e.g. noise reduction, sealing and/or stiffening. The cavity is part of an automotive vehicle structure. The present invention further relates to an automotive vehicle structure with a multitude of cavities and a filling system.

This disclosure details vehicle static body structure mounted side view mirror assemblies. The exemplary side view mirror assemblies may include features for supporting vehicle off-roading, such as a pivoting and telescoping mirror section, a wind wing, lighting features, snorkel features, and/or accessory mounts, etc. The exemplary side view mirror assemblies may also include features for supporting improved vehicle security, such as mirror mounted radar sensors capable of establishing a security protection zone about the vehicle.

A body structure for a vehicle has at least one side door sill that is made up of a door sill outer part on the outer side of the vehicle and a door sill inner part on the inner side of the vehicle, in the vehicle transverse direction, which delimit a door sill cavity that extends in the vehicle longitudinal direction between a front closing profile that closes off the door sill cavity in the direction of the front wheel housing, and a rear closing profile that closes off the door sill cavity in the direction of the rear wheel housing, wherein a reinforcement element, designed as an insert part, which extends in the vehicle longitudinal direction and acts as a side collision reinforcement is situated in the door sill cavity, and wherein in the event of a head-on collision the reinforcement element is acted on by a collision force directed toward the rear of the vehicle, in particular with load on at least one connecting point at which the reinforcement element is connected to the door sill. According to the invention, to relieve load on the connecting point, the reinforcement element is spaced apart from the rear closing profile by a longitudinal clearance space. A jacking point sheet metal part extends in the vertical vehicle direction, transversely through the longitudinal clearance space, and, in a head-on collision, the jacking point sheet metal part acts as a longitudinal stop by means of which longitudinal shifting of the reinforcement element is prevented.

A profile includes two end wing portions with substantially a transversal direction (Y), two lateral wall portions having substantially a height direction-(Z), a frontal wall portion having substantially a transversal direction (Y), two curved transition zones (R1, R2) disposed between the lateral wall portions and the frontal wall portion, and two curved transition zones (R3, R4) disposed between the end wing portions and the lateral wall portions. A specific portion of each curved transition zones (R1, R2) between the lateral wall portions and the frontal wall portion has a tensile strength lower than the tensile strength of the rest of the cross-section. This configuration also relates to a longitudinal beam, a cross-member, a pillar, a B-Pillar or a C-Pillar having the profile, and to a vehicle provided thereof.

A metal extrusion and nodes based structure is provided. The structure comprises one or more arc members connected by one or more node members, wherein the arc comprises (i) a wing feature which is configured to mate with one or more non-structural components, (ii) an internal passage feature which is configured to be inserted into a connecting feature of the corresponding node member, and (iii) one or more keying features formed from a mating interface with the corresponding node member.

A metal extrusion and nodes based structure is provided. The structure comprises one or more arc members connected by one or more node members, wherein the arc comprises (i) a wing feature which is configured to mate with one or more non-structural components, (ii) an internal passage feature which is configured to be inserted into a connecting feature of the corresponding node member, and (iii) one or more keying features formed from a mating interface with the corresponding node member.

The disclosure aims to provide a structural member made of an extruded material that effectively helps to reduce weight while ensuring strength and rigidity. The structural member has a varied wall thickness along an extrusion direction.

The disclosure aims to provide a structural member made of an extruded material that effectively helps to reduce weight while ensuring strength and rigidity. The structural member has a varied wall thickness along an extrusion direction.

A structural reinforcement for a vehicle comprising: a) a carrier having a base wall from which a plurality of projections extend, the plurality of projections including at least one first projection and at least one second projection and the at least one first projection having a height greater than a height of the at least one second projection; b) an activatable material which is heat activatable and affixed to the carrier, configured to secure the carrier in a cavity of the vehicle; wherein in event of an impact, the at least one first projection and second projection are configured to deform toward the base wall and/or in a direction of an impact load in response to the impact load; and the at least one first projection is configured to receive the impact load and deform before the at least one second projection receives the impact load and deforms.