A male coupling member detachably couplable to a female coupling member includes an outer coupling body having a first end inserted and fitted into the female coupling member, a second end opposite to the first end, and a passage extending from the first end to the second end. The male coupling member further includes an inner coupling body disposed coaxially with the outer coupling body at a position closer to the first end, and a filtration member detachably attached to the inner coupling body. The inner coupling body is attachable to and detachable from the outer coupling body from the first end. The filtration member is held in the passage when the inner coupling body is attached to the outer coupling body. The filtration member is detachable when the inner coupling body is detached from the outer coupling body.

To suppress the influence of gas on other fuel tanks when the gas is discharged from a fuel tank. A fuel storage device includes: a plurality of fuel tanks, each having a fusible plug valve; a support member that supports the plurality of fuel tanks, while making longitudinal directions of the respective fuel tanks parallel to each other; and a blocking member that blocks at least part of the fuel gas discharged from the fusible plug valves. The plurality of fuel tanks includes a tank group including the plurality of fuel tanks aligned along a first direction and a juxtaposed tank thereto. The blocking member is disposed between the tank group and the juxtaposed tank. The orientations of openings of the fusible plug valves included in blocked tanks are directed toward the blocking member, the blocked tanks being two or more fuel tanks that are continuous in the first direction, among the fuel tanks included in the tank group.

A distance-to-empty presentation apparatus of a fuel cell vehicle includes: a traveling speed acquisition unit configured to acquire a traveling speed of the fuel cell vehicle; a traveling distance acquisition unit configured to acquire a traveling distance of the fuel cell vehicle in a fuel filling period, the fuel filling period is a period from the time when the fuel is filled in the fuel cell vehicle previously to the time when the fuel is filled in the fuel cell vehicle this time; a fuel residual amount acquisition unit configured to acquire a fuel residual amount of the fuel cell vehicle; a fuel consumption amount acquisition unit configured to acquire a fuel consumption amount of the fuel cell vehicle; a fuel efficiency calculation unit configured to calculate fuel filling period fuel efficiency by using the traveling distance in the fuel filling period and a traveling period fuel consumption amount that is the fuel consumption amount during traveling preparation and during traveling in the fuel filling period, wherein the fuel filling period fuel efficiency is fuel efficiency in the fuel filling period; a distance-to-empty calculation unit configured to calculate a distance to empty of the fuel cell vehicle by using the fuel filling period fuel efficiency and the fuel residual amount; and a presentation device configured to present the distance to empty.

A fuel cell vehicle includes a fuel tank module that accommodates a fuel gas, and a rail arranged along a vehicle-width direction of the fuel cell vehicle in a floor part of the fuel cell vehicle, in which the fuel tank module includes a casing that accommodates a fuel tank accommodating the fuel gas, a block unit arranged in a bottom surface of the casing and configured to be attachable to and detachable from the rail and movable along the rail, and a fixation unit that can fix the block unit to the rail and release fixation of the block unit to the rail.

A vehicle includes: a pair of side frames; a mount unit provided between the side frames such that the mount unit is placed at a position overlapping with the side frames when the mount unit is viewed in the vehicle width direction; and a first attachment portion group including a plurality of attachment portions via which a side face of the mount unit is connected to a first side frame. The attachment portions provided in the first attachment portion group include respective elastic portions placed between the first side frame and the mount unit when the respective elastic portions are viewed from above the vehicle. The respective elastic portions included in the attachment portions are placed to overlap each other when the respective elastic portions are viewed in the extending direction of the first side frame.

There is provided a vehicle including a detection sensor used to detect a surrounding condition of the vehicle; a vehicle controller configured to perform drive control of the vehicle by using a signal output from the detection sensor; a fuel cell configured to generate electric power while generating water; an accumulating portion configured to accumulate the generated water discharged from the fuel cell therein as liquid water; and a cleaning portion connected with the accumulating portion, provided with a nozzle that is open to the detection sensor, and configured to eject the liquid water accumulated in the accumulating portion through the nozzle and thereby clean the detection sensor under control of the vehicle controller.

The present invention relates to electric drivetrain kits for converting all-terrain vehicles into hybrid or electric vehicles. In exemplary embodiments, a conversion kit replaces an existing standard single motor and transmission drive system with a dual set-up including a motor for each rear wheel and a split transmission that houses two sets of gear reduction components in a single housing or an all-wheel configuration with two transmission sets (front and rear). Dual output shafts in each transmission set drive the wheels independently to provide the torque needed as required and demanded by each wheel.

A fuel cell system and a fuel cell vehicle that prevent deformation of a fuel cell case when an external force is applied are provided. A fuel cell system includes a fuel cell case configured to contain a fuel cell; and an auxiliary device fixed to a side surface of the fuel cell case. The auxiliary device includes: a first support part fixed to the fuel cell case; a second support part fixed to the fuel cell case at a position spaced apart from the first support part; and a main body part supported by the first support part and the second support part spaced apart from the fuel cell case. The first support part is broken before the second support part is broken when an external force is applied to the main body part in a direction approaching the fuel cell case.

A hydrogen storage system includes: a first hydrogen tank provided in a fuel cell electric vehicle; a second hydrogen tank provided in the fuel cell electric vehicle and configured to store hydrogen independently of the first hydrogen tank; a manifold provided in the fuel cell electric vehicle and connected to the first hydrogen tank and the second hydrogen tank; a hydrogen supply line configured to connect the manifold and a fuel cell stack provided in the fuel cell electric vehicle; and a flow rate adjusting valve configured to adjust a flow rate of the hydrogen to be supplied to the manifold from at least one of the first hydrogen tank or the second hydrogen tank in accordance with a difference in pressure between the first hydrogen tank and the second hydrogen tank, so as to minimize a difference in pressure between the hydrogen tanks to improve safety and reliability.

A truck chassis frame includes a front frame facing a front of a vehicle, a rear frame facing a rear of the vehicle, and a mounting module connected between the front frame and the rear frame, and having a mounting space in which a component is mounted.