A refuse vehicle includes a chassis having a prime mover, a body assembly coupled to the chassis, a tailgate pivotally coupled to the body assembly, an energy storage device coupled to the tailgate and moveable therewith, at least one of a non-structural conduit, a non-structural raceway, and a non-structural channel configured to contain at least one of wiring and a hydraulic line, and an impact mitigation system including at least one frame member positioned to direct impact loads around the energy storage device. The prime mover is configured to be powered by the energy storage device. The impact mitigation system provides a protected region within which the energy storage device is disposed.

This disclosure describes an assembly for gas (e.g., compressed natural gas) storage. The assembly includes multiple gas storage tanks, with each tank coupled to a separate sub-assembly that includes a pressure gauge, shutoff valve, and pressure relief device (PRD), providing for independent pressure monitoring, shutoff, and pressure relief for each of the tanks.

This disclosure describes an assembly for gas (e.g., compressed natural gas) storage. The assembly includes multiple gas storage tanks, with each tank coupled to a separate sub-assembly that includes a pressure gauge, shutoff valve, and pressure relief device (PRD), providing for independent pressure monitoring, shutoff, and pressure relief for each of the tanks.

A high-pressure hydrogen container is provided that has a simple configuration, requiring less labor for manufacture, achieving reduced manufacturing costs, and ensuring pressure resistance. The high-pressure hydrogen container includes a metal cylinder configured to store high-pressure hydrogen, a pair of lid parts configured to cover both end portions of the metal cylinder, and a plurality of fastening parts configured to fix the pair of lid parts in a state where the metal cylinder is clamped between the pair of lid parts.

An automotive hydrogen storage tank support system for a vehicle includes: a floor; a pair of side sills mounted on lateral edges of the floor, respectively; and a support frame mounted on the floor and supporting a hydrogen storage tank The support frame includes a pair of longitudinal members, and a plurality of transverse members connecting the pair of longitudinal members to each other, at least one transverse member among the plurality of transverse members has a pair of extension portions respectively extending from opposite ends thereof toward the pair of side sills, and each extension portion is joined to a corresponding side sill of the pair of side sills.

An automotive hydrogen storage tank support system for a vehicle includes: a floor; a pair of side sills mounted on lateral edges of the floor, respectively; and a support frame mounted on the floor and supporting a hydrogen storage tank The support frame includes a pair of longitudinal members, and a plurality of transverse members connecting the pair of longitudinal members to each other, at least one transverse member among the plurality of transverse members has a pair of extension portions respectively extending from opposite ends thereof toward the pair of side sills, and each extension portion is joined to a corresponding side sill of the pair of side sills.

A pressure vessel is provided for a motor vehicle, having a fastening apparatus. The fastening apparatus is designed to connect the pressure vessel to a body of the motor vehicle. The fastening apparatus has at least two connecting pins and at least two bearings. In each case, one connecting pin is connected to a bearing at a connecting point. The connecting pins and/or the bearings are each connected to the pressure vessel in a pressure vessel attachment region and extend away from the outer surface of the pressure vessel. The pressure vessel attachment regions exhibit in each case an expansion. The connecting pin and the bearing are, in the connecting point, at least regionally shaped and arranged such that the expansion is kinetically guided with only one translational degree of freedom by way of a movement of the bearing and/or of the connecting pin.

A pressure vessel is provided for a motor vehicle, having a fastening apparatus. The fastening apparatus is designed to connect the pressure vessel to a body of the motor vehicle. The fastening apparatus has at least two connecting pins and at least two bearings. In each case, one connecting pin is connected to a bearing at a connecting point. The connecting pins and/or the bearings are each connected to the pressure vessel in a pressure vessel attachment region and extend away from the outer surface of the pressure vessel. The pressure vessel attachment regions exhibit in each case an expansion. The connecting pin and the bearing are, in the connecting point, at least regionally shaped and arranged such that the expansion is kinetically guided with only one translational degree of freedom by way of a movement of the bearing and/or of the connecting pin.

The invention relates to a system for checking the function and releasing the excess pressure of a cryogenic container on a vehicle roof, the system comprising a vehicle and the cryogenic container which is mounted on the vehicle roof and has an interior volume for receiving cryogenic fluid, wherein the system furthermore comprises a pressure line which is connected to the interior volume of the cryogenic container and is led from the cryogenic container on the vehicle roof to an accessible point on the vehicle side or in the vehicle interior and opens into a pressure gauge there, wherein a valve and a predetermined breaking point are arranged in the pressure line and the valve is arranged between the predetermined breaking point and the interior volume of the cryogenic container and opens at a predetermined first pressure which is greater than a second pressure at which the predetermined breaking point breaks.

The invention relates to a system for checking the function and releasing the excess pressure of a cryogenic container on a vehicle roof, the system comprising a vehicle and the cryogenic container which is mounted on the vehicle roof and has an interior volume for receiving cryogenic fluid, wherein the system furthermore comprises a pressure line which is connected to the interior volume of the cryogenic container and is led from the cryogenic container on the vehicle roof to an accessible point on the vehicle side or in the vehicle interior and opens into a pressure gauge there, wherein a valve and a predetermined breaking point are arranged in the pressure line and the valve is arranged between the predetermined breaking point and the interior volume of the cryogenic container and opens at a predetermined first pressure which is greater than a second pressure at which the predetermined breaking point breaks.