An automated vehicle includes a vehicle body defining a storage area located rearward of a rearmost vehicle seat in a front-rear direction of the automated vehicle. An interior structure is located in the storage area. The interior structure defines a storage compartment for housing an electronic component of the automated vehicle. The interior structure includes a removable floor panel overlying the storage compartment and a wall panel extended upward from the floor panel in a height direction of the automated vehicle. The storage compartment includes a dedicated space for the electronic component, the dedicated space located forward of a forward edge portion of the floor panel in the front-rear direction and between the wall panel and the rearmost vehicle seat in the front-rear direction.

The disclosure provides a car body panel structure. The car body panel structure includes multiple beads disposed on the car body panel and separated by multiple ridges formed on the car body panel. Each of the beads is formed in a zigzag shape. The beads are all not in contact with the ridges.

A vehicle includes an electrical device, a frame member configured to hold the electric device, and a bracket connecting a vehicle structural member and the frame member. The frame member includes: a frame main body having an electrical device accommodation portion configured to accommodate the electrical device and a bracket attachment portion to which the bracket is attached; and an upper frame which is attached to the frame main body and covers the electric device accommodated in the electric device accommodation portion. The bracket attachment portion is attached to the bracket in a direction from the bottom to the top. The upper frame is attached to the frame main body in a direction from the top to the bottom.

A lower vehicle-body structure of an electric vehicle to increase resistance to lateral collision and also improve front-end collision load transfer performance of a tunnel. The lower vehicle-body structure of an electric vehicle includes a floor having a tunnel formed in a front part at a middle in a vehicle-width direction; and a floor cross member spanning, above the floor, between side sills disposed on opposite sides of the floor. Also, a rear end of the tunnel is located directly in front of the floor cross member, and reinforcing brackets are provided extending from the tunnel toward an upper end of the floor cross member and connected to the upper end of the floor cross member.

A front vehicle-body structure is provided that is lightweight and reduces an impact load transmitted to lower limbs of an occupant. Embodiments include a transmission disposed in a vehicle front portion, a dash lower panel dividing an inside from an outside of a vehicle cabin in a vehicle rear of the transmission, and an organ type accelerator pedal disposed on a vehicle-width-direction inner side of the dash lower panel opposed to the transmission. The dash lower panel includes a panel rear portion in which the accelerator pedal is arranged, a panel front portion extending from the panel rear portion to a vehicle front upper side, and a fragile portion extending in a vehicle width direction along a boundary between the panel rear portion and the panel front portion, which is fragile compared to the panel rear portion and the panel front portion.

A vehicle body structure includes a forecabin crossbeam and two front longitudinal beams disposed at intervals along a left-right direction. The forecabin crossbeam and the two front longitudinal beams are integrally formed and are at least partially located at the bottom of the front longitudinal beam.

A structural panel joining part for a vehicle having an underbody hold-down panel, a floor panel, a dash panel, and a cowl side panel includes an underbody coupling first portion configured to couple to at least one of the underbody hold-down panel and the floor panel, a dash panel coupling second portion configured to couple to the dash panel, and a cowl side coupling third portion configured to couple to the cowl side panel. The structural panel joining part maintains structural integrity between the underbody hold-down panel, the floor panel, the dash panel, and the cowl side panel to provide structural reinforcement during small overlap rigid barrier impacts to facilitate reducing structural intrusion into an occupant compartment of the vehicle.

A vehicle body structure and a vehicle are provided. The vehicle body structure includes a front longitudinal beam, a front compartment crossbeam, and a dash panel. The front longitudinal beam includes a left front longitudinal beam and a right front longitudinal beam that are disposed at an interval in a transverse direction. The front compartment crossbeam is mounted on the left front longitudinal beam and the right front longitudinal beam, and is located in front of the dash panel. A projection area of the front compartment crossbeam on the dash panel in an X direction at least partially covers a projection of a preset area surrounding a pedal center point on the dash panel in the X direction.

A lower vehicle-body structure allows miniaturization of an undercover and prevents an increase in minimum ground clearance. In the lower vehicle-body structure, a vehicle body floor includes step-up portions connected to a floor tunnel on opposite sides of the floor tunnel in a vehicle width direction at least in regions where first and second cross members are disposed on the vehicle body floor. The lower vehicle-body structure includes a mount member that faces the floor tunnel and connects the step-up portions on the opposite sides of the floor tunnel, and includes first and second undercovers that cover a lower side of the mount member so as to be continuous with a bottom surface of the vehicle body floor on outer sides of the step-up portions in the vehicle width direction.

A control arm includes a wheel side end, a body side end, a first connecting member extending between the wheel side end and the body side end, a second connecting member extending between the wheel side end and the body side end, and having a reduced section portion, and a fracture zone extending through the first and second connecting members in a substantially fore-aft direction of the vehicle, the reduced section portion being within the fracture zone. A thickness of the reduced section portion is tunable to establish a controlled fracturing during a small overlap rigid barrier impact event where: (i) an initial fracture of the first connecting member occurs within the fracture zone, and (ii) a secondary fracture of the second connecting member occurs within the fracture zone at the reduced section portion, to thereby provide a desired rearward trajectory of the wheel assembly during the impact event.