Provided is a protective structure (64) for a fuel pipe (45) extending along the intake side of an engine main body (9) under an intake manifold (20). A protective member (61) is placed in front of the fuel pipe. The protective member includes a pair of legs (64, 65) secured to the intake side of the engine main body, a main body (63) extending from the legs upward in an arcuate manner along a front side of the fuel pipe and bent rearward in an upper part thereof, and an abutting projection (63G) extending from an upper end of the main body and projecting upward and rearward. A fastening member (26, 27) is passed through a flange of the intake manifold, and includes an engagement feature (36) positioned behind a free end of the abutting projection. The protective member minimizes the loading transmitted to the fuel pipe at the time of a vehicle crash.

Provided is a protective structure (64) for a fuel pipe (45) extending along the intake side of an engine main body (9) under an intake manifold (20). A protective member (61) is placed in front of the fuel pipe. The protective member includes a pair of legs (64, 65) secured to the intake side of the engine main body, a main body (63) extending from the legs upward in an arcuate manner along a front side of the fuel pipe and bent rearward in an upper part thereof, and an abutting projection (63G) extending from an upper end of the main body and projecting upward and rearward. A fastening member (26, 27) is passed through a flange of the intake manifold, and includes an engagement feature (36) positioned behind a free end of the abutting projection. The protective member minimizes the loading transmitted to the fuel pipe at the time of a vehicle crash.

A hydrogen fuel supply system 1 comprises a tank 2 which stores liquid hydrogen therein; a supply line 4 which takes the liquid hydrogen out of the tank 2, vaporizes the liquid hydrogen into a hydrogen gas, and supplies the hydrogen gas to a use point 3; and a pressurization line 5 which compresses the hydrogen gas generated by vaporization of the liquid hydrogen inside the tank 2 by use of a compressor 59 so that a pressure of the hydrogen gas is increased, and sends the hydrogen gas with the increased pressure to a gaseous phase part inside the tank 2.

A hydrogen fuel supply system 1 comprises a tank 2 which stores liquid hydrogen therein; a supply line 4 which takes the liquid hydrogen out of the tank 2, vaporizes the liquid hydrogen into a hydrogen gas, and supplies the hydrogen gas to a use point 3; and a pressurization line 5 which compresses the hydrogen gas generated by vaporization of the liquid hydrogen inside the tank 2 by use of a compressor 59 so that a pressure of the hydrogen gas is increased, and sends the hydrogen gas with the increased pressure to a gaseous phase part inside the tank 2.

A vehicle includes a body including a beltline and a rear wheelhouse, an input line assembly packaged about the rear wheelhouse, a component packaged about the rear wheelhouse rearward of the input line assembly, and a spare wheel stowed rearward of the rear wheelhouse. The component is secured by a permanent beltline-side attachment and a semi-permanent rear wheelhouse-side attachment. In response to rear impact, the body is configured to allow forward movement of the spare wheel, under which the spare wheel has a trajectory relative to which the component is between the spare wheel and the input line assembly, and relative displacement between the beltline-side attachment and the rear wheelhouse-side attachment, under which the rear wheelhouse-side attachment breaks against the beltline-side attachment, and the beltline-side attachment thereafter carries the component from between the spare wheel and the input line assembly relative to the trajectory of the spare wheel.

A vehicle includes a body including a beltline and a rear wheelhouse, an input line assembly packaged about the rear wheelhouse, a component packaged about the rear wheelhouse rearward of the input line assembly, and a spare wheel stowed rearward of the rear wheelhouse. The component is secured by a permanent beltline-side attachment and a semi-permanent rear wheelhouse-side attachment. In response to rear impact, the body is configured to allow forward movement of the spare wheel, under which the spare wheel has a trajectory relative to which the component is between the spare wheel and the input line assembly, and relative displacement between the beltline-side attachment and the rear wheelhouse-side attachment, under which the rear wheelhouse-side attachment breaks against the beltline-side attachment, and the beltline-side attachment thereafter carries the component from between the spare wheel and the input line assembly relative to the trajectory of the spare wheel.

A fluid system for a vehicle is provided. The fluid system is configured to couple to a chassis of the vehicle. A frame assembly of the fluid system is configured to couple with the chassis directly or with another component that is coupled, directly or indirectly, with the chassis. A cowling of the fluid system can enclose a fuel pressure vessel and an auxiliary fluid vessel. The auxiliary fluid vessel is configured to be placed in fluid communication with the component powered or operated by the fluid therein.

A fluid system for a vehicle is provided. The fluid system is configured to couple to a chassis of the vehicle. A frame assembly of the fluid system is configured to couple with the chassis directly or with another component that is coupled, directly or indirectly, with the chassis. A cowling of the fluid system can enclose a fuel pressure vessel and an auxiliary fluid vessel. The auxiliary fluid vessel is configured to be placed in fluid communication with the component powered or operated by the fluid therein.

A connector assembly and method of making and ensuring a reliable, fluid-tight connection is provided. The assembly includes a housing a having a wall bounding a bore extending along a central longitudinal axis. The wall has a locking opening, a slot, and a window. A retaining member has a cylindrical wall received in the bore of the housing. The cylindrical wall has a detent received in the locking opening and a locking arm cantilevered by a hinge connection for pivotal movement. The locking arm is spaced from the cylindrical wall by a gap and is received in the slot when the detent is received in the locking opening. A visual indicator attached to the cylindrical wall moves radially outwardly into the window in response to the collar being fully received in the gap to provide visual evidence of a fluid-tight seal between the insertion member and the housing.

A connector assembly and method of making and ensuring a reliable, fluid-tight connection is provided. The assembly includes a housing a having a wall bounding a bore extending along a central longitudinal axis. The wall has a locking opening, a slot, and a window. A retaining member has a cylindrical wall received in the bore of the housing. The cylindrical wall has a detent received in the locking opening and a locking arm cantilevered by a hinge connection for pivotal movement. The locking arm is spaced from the cylindrical wall by a gap and is received in the slot when the detent is received in the locking opening. A visual indicator attached to the cylindrical wall moves radially outwardly into the window in response to the collar being fully received in the gap to provide visual evidence of a fluid-tight seal between the insertion member and the housing.