A high-pressure vessel mounting structure includes: a plurality of high-pressure vessels arranged on the upper surface of a bottom wall in a front-rear direction of a vehicle body with a vehicle width direction as an axial direction; a plurality of load transmission members each provided between the high-pressure vessels on the bottom wall and extending along the axial direction; a connection member that connects one axial end of each of the high-pressure vessels; and a support member that supports the other axial end of each of the high-pressure vessels, and the support member can move relatively inward in the vehicle width direction with respect to the high-pressure vessel when a load is input from outside in the vehicle width direction.

The present disclosure provides a chassis collision structure of a new energy vehicle, comprising a front lower collision beam assembly, a front sub-frame assembly, a front battery pack bottom fender, a rear battery pack bottom fender, and a rear sub-frame assembly which are arranged sequentially along a direction from a head to a tail of a vehicle, wherein the front lower collision beam assembly is connected to a front end of the front sub-frame assembly; the front battery pack bottom fender is connected to a bottom of the front sub-frame assembly; the rear battery pack bottom fender is connected to a bottom of the rear sub-frame assembly; and connecting parts which are connected with a battery pack are arranged at one end of the front battery pack bottom fender and one end of the rear battery pack bottom fender, which are close to each other, respectively.

A vehicle battery case includes: a housing in which a battery is mounted and which has a side surface part formed to cover the side surface of the battery; a side upper panel coupled to the side surface part of the housing and extending in a longitudinal direction along the side surface part; a side lower panel coupled to the side surface part of the housing while being spaced downward apart from the side upper panel and extending in the longitudinal direction along the side surface part of the housing, an end of the side lower panel being coupled to an end of the side upper panel so as to form an impact absorption space between the side lower panel and the side upper panel; and a reinforcement panel inserted into the impact absorption space and extending in the longitudinal direction along the side surface part of the housing.

A battery enclosure, support beam for the battery enclosure and method of providing structural support to the battery enclosure. The battery enclosure includes a base having a first sidewall and a second sidewall opposite the first sidewall. The support beam extends from the first sidewall to the second sidewall. The support beam includes a body having a first beam end and a through passage. An internal stabilizer disposed within the through passage at the first beam end. The internal stabilizer includes a first stabilizer sidewall extending from a first stabilizer end to a second stabilizer end, a second stabilizer sidewall extending from the first stabilizer end to the second stabilizer end, and a bridge connecting the first stabilizer sidewall to the second stabilizer sidewall at the second stabilizer end.

A protective element (1) named shield element for a battery pack of an electric or hybrid vehicle, wherein the protective element (1) includes a securing device (2) configured to removably secure the shield element (1) both to the battery pack and to a body (11) of the vehicle.

A shaft connection 1 for a longitudinal shaft assembly, has at least a first shaft having a first and second ends, and a second shaft, disposed so as to be coaxial with the first shaft, having first and second ends; the shafts extending axially. The first end forms a hollow portion. The first shaft end forms a first journal having a displacement portion. The first shaft end at least in an initial position of the shaft connection extends through the hollow portion which axially by the displacement portion forms a guide portion and circumferentially forms a form-fitting first connection. In the initial position a mutual axial displacement of the first and second shafts is prevented by an axial securing feature. In a crash the axial securing feature; is releasable by an axial release force. The first shaft is axially displaceable relative to the second shaft.

Energy absorption at the time of load input is improved with high mass efficiency. A hollow member includes: a hollow metal member having a bending induction portion in a portion thereof in a longitudinal direction; and a resin material which is disposed in close contact with the metal member on both sides of the bending induction portion in the longitudinal direction, and is disposed in at least a part of a range of less than ⅚ of a cross-sectional height of the metal member from an end portion of the bending induction portion toward an outside in the longitudinal, in which an amount of the resin material per length in the longitudinal direction is larger on the outside of the bending induction portion than on an inside of the bending induction portion.

A cooling structure of a vehicle battery unit includes: a plurality of battery modules; a plurality of battery cooling units; a supply pipe; a discharge pipe; and a battery case. The supply pipe includes a supply pipe portion which passes between the at least two battery modules arranged in the vehicle width direction and connects the plurality of battery cooling units. The discharge pipe includes a discharge pipe portion which passes between the at least two battery modules arranged in the vehicle width direction and connects the plurality of battery cooling unit. The supply pipe portion and the discharge pipe portion have bellows pipe portions which are made of resin and can be expanded or contracted in the front-rear direction and curved pipe portions which are made of resin and bend in the vehicle width direction.

A battery unit for a vehicle is provided. The battery unit includes a lower case having two battery compartments arranged in a direction toward opposite sides of the vehicle, respectively, and a connecting portion bent to be convex upwardly between the two battery compartments. A reinforcing structure is disposed on the connecting portion. Two battery modules are installed in the two battery compartments, respectively and a power wire is electrically connected to at least one of the two battery modules and extends from one of the two battery compartments to the other one of the two battery compartments through the connecting portion.

A vehicle includes a dash cross member extending along a vehicle width direction, a front side member arranged in front of the dash cross member and joined to the dash cross member, a floor member arranged behind the dash cross member, and a brace joined to the dash cross member and joined to the floor member. A joint between the brace and the dash cross member overlaps a joint between the front side member and the dash cross member in the vehicle width direction. The brace includes an extending portion. The extending portion is joined to the floor member.