The subject matter of this specification can be embodied in, among other things, a hydrogen fuel cell anode control system including a hydrogen inlet configured to receive pressurized hydrogen, a hydrogen outlet configured to be fluidically coupled to an anode manifold of a hydrogen fuel cell, a recirculation inlet configured to receive overflow hydrogen from the anode manifold, a hydrogen pressure regulator configured to receive pressurized hydrogen from the hydrogen inlet, a hydrogen recirculation module configured to mix hydrogen received from the hydrogen pressure regulator and the recirculation inlet, and provide a hydrogen mixture to the hydrogen outlet, a differential pressure measurement module configured to measure a differential pressure between the anode manifold and a cathode manifold of the hydrogen fuel cell, and a controller configured to control at least one of the hydrogen pressure regulator or the hydrogen recirculation module based on the measured differential pressure.

An apparatus for controlling a moisture content of a fuel cell unit includes: a controller configured to determine a driving condition of a first fuel cell unit comprising a first fuel cell stack, a first compressor configured to compress air flowing into the first fuel cell stack, and a first humidifier positioned on a rear end of the first compressor, determine a driving condition of a second fuel cell unit comprising a second fuel cell stack, a second compressor configured to compress air flowing into the second fuel cell stack, and a second humidifier positioned on a rear end of the second compressor, and control the moisture content such that the first fuel cell unit and the second fuel cell unit are driven at controlled operation temperatures in response to the determined driving conditions of the first fuel cell unit and the second fuel cell unit.

An apparatus for controlling a moisture content of a fuel cell unit includes: a controller configured to determine a driving condition of a first fuel cell unit comprising a first fuel cell stack, a first compressor configured to compress air flowing into the first fuel cell stack, and a first humidifier positioned on a rear end of the first compressor, determine a driving condition of a second fuel cell unit comprising a second fuel cell stack, a second compressor configured to compress air flowing into the second fuel cell stack, and a second humidifier positioned on a rear end of the second compressor, and control the moisture content such that the first fuel cell unit and the second fuel cell unit are driven at controlled operation temperatures in response to the determined driving conditions of the first fuel cell unit and the second fuel cell unit.

The present invention relates to a fuel cell system and a control method for the same, it may be configured to include a plurality of stacks connected in series with each other, and supply moisture from one or more stacks of the plurality of stacks to one or more other stacks according to an operation condition of each of the plurality of stacks, and it has an advantage of improving an operation performance by uniformly forming the humidity condition of each of the plurality of stacks.

An aircraft includes a fuel cell-powered electric engine system configured to power the aircraft and produce water vapor exhaust, and an exhaust system configured to receive the water vapor exhaust, condense the water vapor into ice or water, and expel the ice or water from the aircraft such that water vapor cloud formation is inhibited. A method of powering an aircraft includes operating a fuel cell-powered electric engine system to power the aircraft, condensing water vapor exhaust of the fuel cell-powered electric engine system into ice or water, and expelling the ice or water from the aircraft such that water vapor cloud formation is inhibited.

An ECU of a fuel cell vehicle determines whether the vehicle travels on an uphill road or not. When determining that the vehicle travels on the uphill road, the ECU performs at least one of a temperature reduction control for reducing the temperature of a fuel cell stack and a humidification control for increasing the water content of the fuel cell stack, by the time the vehicle reaches the uphill road.

An ECU of a fuel cell vehicle determines whether the vehicle travels on an uphill road or not. When determining that the vehicle travels on the uphill road, the ECU performs at least one of a temperature reduction control for reducing the temperature of a fuel cell stack and a humidification control for increasing the water content of the fuel cell stack, by the time the vehicle reaches the uphill road.

The invention relates to a method for removing water from a fuel cell system (1) comprising a fuel cell stack (2) having an anode portion (3) and a cathode portion (4), a purge valve (5) downstream of the anode portion (3) for controlling a purge pressure in the anode portion (3), and a back pressure valve (6) downstream of the cathode portion (4) for controlling a back pressure in the cathode portion (4), comprising the steps: increasing the purge pressure in the anode portion (3) to a predefined purge pressure setpoint (AP1) with the purge valve (5) closed, increasing the back pressure in the cathode portion (4) to a predefined back pressure setpoint (KP1) with the back pressure valve (6) closed, and subsequently reducing the increased purge pressure as well as the increased back pressure in pulses by opening the purge valve (5) and the back pressure valve (6). Furthermore, the invention relates to a fuel cell system (1) and a computer program product (10) for carrying out a method according to the invention, as well as a storage means comprising a computer program product (10) stored thereon.

The present disclosure generally relates to systems and methods for using a relative humidity sensor in a cathode exhaust stream of a fuel cell stack to optimize the performance and efficiency of the fuel cell stack.

In a case where each of the temperature, the impedance, and the output current of a fuel cell stack falls within a predetermined range, the output voltage of the fuel cell stack is measured, and the measured output voltage is compared with a reference value to thereby determine the degree of degradation of the fuel cell stack.