The disclosure provides a fuel cell system for a vehicle. The fuel cell system includes a fuel cell stack disposed in a front room of a vehicle; and a converter assembly. The converter assembly disposed above or below the fuel cell stack includes: a converter; a first connector section; and a second connector section. The second connector section connects the converter assembly and a second electrical instrument which uses a high voltage. The second connector section is disposed behind the first connector section in a front-rear direction of the vehicle, and when the first connector section and the second connector section are seen from the front-rear direction of the vehicle, the first connector section and at least a portion of the second connector section are overlapped each other.

A vehicle mount structure for includes a stack case and a boss. The stack case accommodates a fuel cell stack. The stack case includes a bottom panel to be provided on a bracket member of a vehicle. The bottom panel includes a lower plate and an intermediate member. The lower plate is opposite to and below an upper plate in a height direction of the vehicle. The lower plate has an opening to surround a bearing surface of the bracket member. The intermediate member is disposed between the upper plate and the lower plate. The intermediate member has a thickness thicker than a thickness of the upper plate and a thickness of the lower plate. The boss is disposed on the intermediate member and includes a rib. The boss with the rib protrudes toward the bracket member to pass through the opening.

A fuel cell vehicle includes: a stack frame providing a fuel cell stack, the stack frame being placed in front of a vehicle cabin; and a fuel tank placed behind the stack frame. The stack frame includes a central member, a right member joined to the central member, a left member joined to the central member, and a front cross member. The front cross member is joined to front edge portions of the central member, the right member, and the left member. A front-end portion of a first joining portion between the central member and the right member and a front-end portion of a second joining portion between the central member and the left member overlap with a third joining portion of the front cross member with the front edge portions of the central member, the right member, and the left member.

A fuel cell vehicle includes: a stack frame providing a fuel cell stack, the stack frame being placed in front of a vehicle cabin; and a fuel tank placed behind the stack frame. The stack frame includes a central member, a right member joined to the central member, a left member joined to the central member, and a front cross member. The front cross member is joined to front edge portions of the central member, the right member, and the left member. A front-end portion of a first joining portion between the central member and the right member and a front-end portion of a second joining portion between the central member and the left member overlap with a third joining portion of the front cross member with the front edge portions of the central member, the right member, and the left member.

A fuel cell vehicle includes a battery disposed in a first space, a radiator disposed in a second space formed adjacent to the first space in a second direction intersecting a first direction, which is a direction in which the vehicle travels, and at least one fuel cell unit disposed in a third space formed adjacent to the first space in the second direction while being spaced apart from the second space in the second direction, with the first space interposed therebetween.

A fuel cell vehicle includes a battery disposed in a first space, a radiator disposed in a second space formed adjacent to the first space in a second direction intersecting a first direction, which is a direction in which the vehicle travels, and at least one fuel cell unit disposed in a third space formed adjacent to the first space in the second direction while being spaced apart from the second space in the second direction, with the first space interposed therebetween.

A transport vehicle configured to run on electricity generated by a fuel cell includes: a body having a cargo space for freight; a chassis frame located below the body and supporting the body; and a tank unit including a plurality of tanks that stores fuel gas to be used for power generation by the fuel cell and a connecting portion connecting the tanks, the tank unit being located between the cargo space and the chassis frame.

A battery power management system for vehicles and vessels requiring switching devices to disconnect mounted batteries from unit loads utilizing rules based logic. The battery power management system controls the switching devices to prevent over-discharging and over-charging of the batteries and to prevent excessive current drain. The battery power management system utilizes various timing parameters to coordinate connection and disconnection attempts and provides status information regarding the current state of protection of the batteries.

A battery power management system for vehicles and vessels requiring switching devices to disconnect mounted batteries from unit loads utilizing rules based logic. The battery power management system controls the switching devices to prevent over-discharging and over-charging of the batteries and to prevent excessive current drain. The battery power management system utilizes various timing parameters to coordinate connection and disconnection attempts and provides status information regarding the current state of protection of the batteries.

Systems and methods for fueling (or charging) communication, for example between a hydrogen fueling station and a hydrogen powered vehicle (or an electric vehicle and charging station) may utilize near field communication as well as vehicle to infrastructure communication. Safety information, fueling or charging information, payment information, and other information may be transmitted, and the redundant nature of the communication permits fault recovery and improved process monitoring. In this manner, fueling and/or recharging is made safer, faster, and more efficient.