The present invention makes it possible to integrate and control in one circuit the systems, such as electric power components, a driving motor, a stack, and an AC condenser which have the maximum enthalpy under similar operational temperature and use conditions, by using an integrated radiator. Therefore, it is possible to minimize air-through resistance of the radiator for cooling the stack and the electric power components and ensure smooth and stable cooling performance of the stack, electric power components, and AC condenser while improving fuel efficiency by reducing the condensation pressure of the air conditioner. Further, it is possible to improve cooling efficiency by non-repeatedly arranging heat exchangers, and reduce the weight of a vehicle, volume of the parts, and the manufacturing cost, by avoiding using too many parts, such as a radiator, a water pump, and a reservoir tank.

A driving control method and system of a fuel cell system are provided. The method includes determining, by a controller, a dry state of a fuel cell stack and stopping an air blower, which supplies air to the fuel cell stack, using different processes based on whether the fuel cell stack is in the dry state. Accordingly, the time for which an open circuit voltage (OCV) is maintained is reduced and durability of the fuel cell is improved by preventing dry-out of the fuel cell stack.

A fuel cell two-wheeled vehicle includes an electric machine configured to drive a drive wheel, an air-cooled fuel cell configured to supply electric power to the electric machine, and a fuel gas tank that accumulates fuel gas supplied to the fuel cell. A battery pack is disposed in a space between an intake air inlet and an air intake duct and surrounded by a seat and a vehicle body cover. The intake air inlet is disposed below a front portion of the seat.

A cooling system containing a two-phase refrigerant that comprises a condenser, an evaporator and a conveying device. The evaporator is integrated in a heat source or thermally coupled thereto. Gaseous refrigerant from the evaporator is expanded in an expander, converted into mechanical energy and used to drive a generator for generation of electricity. Furthermore, an aircraft comprising a cooling system, wherein an electrical drive is supplied with electricity from a fuel cell, cooled using the cooling system, and the generator of the cooling system.

A cooling system containing a two-phase refrigerant that comprises a condenser, an evaporator and a conveying device. The evaporator is integrated in a heat source or thermally coupled thereto. Gaseous refrigerant from the evaporator is expanded in an expander, converted into mechanical energy and used to drive a generator for generation of electricity. Furthermore, an aircraft comprising a cooling system, wherein an electrical drive is supplied with electricity from a fuel cell, cooled using the cooling system, and the generator of the cooling system.

A fuel cell device for a vehicle has a fuel cell system comprising a fuel cell stack and has a first cooling circuit for cooling the fuel cell system and a second cooling circuit for cooling an electronic unit and/or an energy storage. The first cooling circuit and the second cooling circuit are thermally connected to each other, wherein only the second cooling circuit has a cooler for cooling the cooling water flowing in the second cooling circuit. A method for cooling a fuel cell device using such components is also provided.

A fuel cell device for a vehicle has a fuel cell system comprising a fuel cell stack and has a first cooling circuit for cooling the fuel cell system and a second cooling circuit for cooling an electronic unit and/or an energy storage. The first cooling circuit and the second cooling circuit are thermally connected to each other, wherein only the second cooling circuit has a cooler for cooling the cooling water flowing in the second cooling circuit. A method for cooling a fuel cell device using such components is also provided.

A humidifier for a fuel cell device has a plurality of flow field frames, between each of which there is arranged a humidifier membrane. A plurality of cooling flow field frames formed identical to the flow field frames, between each of which there is arranged a separating plate, form an integrated intercooler. A motor vehicle having a humidifier with integrated intercooler is also provided.

A humidifier for a fuel cell device has a plurality of flow field frames, between each of which there is arranged a humidifier membrane. A plurality of cooling flow field frames formed identical to the flow field frames, between each of which there is arranged a separating plate, form an integrated intercooler. A motor vehicle having a humidifier with integrated intercooler is also provided.

A system for cooling a battery of an electrified vehicle includes a vehicle air-conditioning system having a first cooling circuit in which a first cooling medium circulates, a second cooling circuit in which a second cooling medium circulates, a cooling unit in thermal contact with the battery, wherein the second cooling medium flows through the cooling unit, and with a heat exchanger through which the first and second cooling media flow in separate channels which are in thermal contact, wherein in the heat exchanger, heat is discharged from the second cooling medium towards the first cooling medium.