An energy absorbing side rail including an inner rail, an outer rail fixedly coupled to the inner rail defining a cavity, the outer rail defining triggers extending along at least a portion of the outer rail, and at least one energy absorber housed in the cavity, wherein at least one energy absorber is positioned in-line with the triggers.

An electric vehicle includes a first rocker and a second rocker spaced from each other. A first slider is slideably engaged with the first rocker, and a second slider is slideably engaged with the second rocker. A first pyrotechnic actuator is supported by the first rocker and is configured to slide the first slider relative to the first rocker. A second pyrotechnic actuator is supported by the second rocker and is configured to slide the second slider relative to the second rocker. A cable extends from the first slider to the second slider.

Methods and systems are provided for a powertrain mount assembly. The assembly comprises a tether configured to block movement of a powertrain component relative to a support frame in the event of a vehicle collision.

An embodiment vehicle impact energy absorption system includes a dash panel, a pair of front side members extending toward a front of the dash panel, a front subframe disposed below the pair of front side members, and an electric motor mounted on the front subframe, wherein a front edge of the electric motor is pivotally connected to the front subframe, and a rear edge of the electric motor is pivotally connected to the dash panel.

A battery housing for a traction battery may include a first housing part and a second housing part fixed removably to each other. Battery modules of the traction battery may be fixable on the first housing part. The housing may also include a reinforcing structure having a plurality of reinforcing ribs reinforcing the first housing part, and a ducted structure with a plurality of coolant ducts for a coolant fixed on the first housing part. The plurality of coolant ducts may each be connectable to a respective temperature-control unit of a battery module in a coolant-conducting fashion. At least one of the coolant ducts may be at least partially embedded in one of the reinforcing ribs.

A vehicle body structure for an electric vehicle includes: a battery disposed at a center lower portion of a vehicle body; a side sill being hollow and extending in a vehicle body front-rear direction outside in a vehicle width direction of the battery; a bridge beam member being hollow, disposed below the side sill and outside in the vehicle width direction of the battery, extending in the vehicle body front-rear direction, and having a cross section perpendicular to the vehicle body front-rear direction formed as a closed cross section; and at least one bridge pier member made of steel, extending in the vehicle width direction from the battery toward the bridge beam member, and having a cross section perpendicular to the vehicle width direction forming at least a part of a closed cross-sectional shape.

A propeller shaft as a power transmission shaft is provided between vehicle-side first second shaft parts, and a first tube as a first shaft member is connected to the first shaft part through a first joint member and to the second shaft part through a second joint member. The first tube is connected to the first joint member through a first collar member and to the second joint member through a second collar member. The first collar member includes a first main body part exposed from a first end portion of the first tube, and a first insertion part inserted into the inside of the first end portion. In at least the first collar member, the maximum value of the outer diameter of the first main body part is set to be no greater than the maximum value of the outer diameter of the first insertion part.

An embodiment is directed to a contact plate configured to establish electrical bonds between battery cells in a battery module, including at least one primary conductive layer, and a set of bonding connectors that are configured to provide direct electrical bonds between the contact plate and terminals of a group of battery cells, the set of bonding connectors being configured to connect the group of battery cells in parallel with each other, wherein at least one bonding connector in the set of bonding connectors is configured with a higher fuse rating than each other bonding connector in the set of bonding connectors so as to contain arcs among the set of bonding connectors to the at least one bonding connector.

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 bracket for a cooling module in a front end structure of a vehicle includes forward crash-box connection means, cooling module connection means, a rigid arm extending between the forward crash-box connection means at a forward side and the cooling module connection means at a rearward side; rear crash-box connection means; and a break-away arm extending from the rearward side of the rigid arm and the rear crash-box connection means.