A fuel cell vehicle includes a fuel cell stack, which is connected to an in-vehicle electric load, a power storage device, which is connected to the fuel cell stack so as to be connected in parallel to the in-vehicle electric load, a state-of-charge sensor, which detects a state of charge of the power storage device, and circuitry that controls the power generated by the fuel cell stack based on the detected state of charge of the power storage device. The in-vehicle electric load includes a driving motor, which is driven based on operation of an operating member. When the state of charge of the power storage device detected by the state-of-charge sensor falls to or below a threshold value, the circuitry executes a restriction process to apply restriction on driving of the driving motor.

Described are power management systems having at least one fuel cell system, a power distribution unit, at least one galley insert, a galley network controller, a control panel, and/or at least one battery pack. The power management system compares a power output from the power distribution unit to a maximum load level and/or to a minimum load level, instructs the galley network controller to cycle the galley insert off and/or set an operation of the galley insert to a lower power consumption level when the power output approaches and/or is above the maximum load level, and instructs the galley network controller to cycle the galley insert on and/or set the operation of the galley insert to a higher power consumption level when the power output approaches and/or is below the minimum load level.

A fuel cell system includes: a solid oxide fuel cell generating power by using, as fuel, air supplied to a cathode and hydrogen-containing gas supplied to an anode; a combustor generating a combustion exhaust gas by combusting anode-off gas and cathode-off gas discharged from the anode and the cathode, respectively; a reformer steam-reforming a material to generate the hydrogen-containing gas supplied to the anode; a first temperature detector detecting temperatures of the combustion exhaust gas and/or the combustor; and a controller performing, if a temperature detected by the first temperature detector is lower than a preset first threshold while the combustor is forming flame, at least one of operations of: increasing a ratio of air consumed to the air supplied in the cathode; decreasing a ratio of hydrogen-containing gas consumed to the hydrogen-containing gas supplied in the anode; and decreasing an amount of water supplied to the reformer.

A fuel cell system of the present disclosure performs a first and a second catalyst activation process, and the first catalyst activation process is performed where a flow rate of the air supplied to the fuel cell by the air compressor is reduced to be less than that before the refresh control is performed while keeping an amount of a current drawn from the fuel cell by the fuel cell converter at the same value as that before the refresh control is performed, and the second catalyst activation process is performed where the value of the current drawn from the fuel cell by the fuel cell converter is increased to be greater than that before the refresh control is performed while keeping the flow rate of the air supplied to the fuel cell by the air compressor at the same value as that before the refresh control is performed.

A method for power control of a fuel cell system in a vehicle is disclosed. The requested fuel cell system power by the vehicle is converted into a power request made of the fuel cell by an expected power of auxiliary drives of the fuel cell system at the requested fuel cell system power being added to the requested fuel cell system power. A media supply of the fuel cell which corresponds to the power request made of the fuel cell is requested. The electrical loading of the fuel cell with current is performed in accordance with a model of the cathode dynamics such that a control variable of the control operation is matched to the media dynamics, and the power release is performed such that the fuel cell is loaded only when the adequate media supply is ensured.

A system and method for controlling power of a fuel cell for a vehicle are provided. The method includes measuring a temperature of the fuel cell and when the measured temperature of the fuel cell is within a high temperature range in which a power threshold value of the fuel cell is reduced based on an increase in temperature of the fuel cell and when the measured temperature of the fuel cell is increased and then is equal to or greater than a predetermined temperature a power threshold value is reduced from a power value at the predetermined temperature. The high temperature range is a range between a third temperature at which the power threshold value starts to be reduced based on the increase in temperature of the fuel cell and a fourth temperature at which the power threshold value is reduced and then reaches the minimum power threshold value.

An apparatus and a method for measuring the internal ohmic resistance of a fuel cell system, in which the resistance can be easily measured through a current interruption method even while the fuel cell system is operated. An interrupter and an external energy consumption device are connected in parallel to each other between a fuel cell and a main energy consumption device such that current to the external energy consumption device is applied and interrupted by switching the interrupter on/off even while the fuel cell system is maintained in operation as is, thereby making it possible to easily measure the internal ohmic resistance of the fuel cell.

A fuel cell vehicle includes a cell stack, a DC level converter, an output unit, a first switching unit disposed between a positive output terminal of the DC level converter and a positive input terminal of the output unit, a second switching unit disposed between a negative output terminal of the DC level converter and a negative input terminal of the output unit, a resistor and a third switching unit connected to each other in series between the positive output terminal of the DC level converter and the negative output terminal of the DC level converter, a fourth switching unit disposed between a contact point between the resistor and the third switching unit and the positive input terminal of the output unit, and a controller for controlling switching operation of the first, second, third and fourth switching units according to an operation mode.

Systems and methods are provided for modularizing a system. Parallel power systems having electronically isolated high voltage systems facilitate modulization. A control system is provided that optimizes the distribution of a power demand and/or a torque request so as to keep the efficiency, durability, drivability and/or safety of the system within an optimum range. In some cases, the distribution of power is uneven, so as to extend the battery life, while in other cases, the power draw on battery systems are kept equal and constant so as to properly manage the state of charge of the parallel power systems. In still other cases, the chosen power distribution keeps the power demand and/or torque request between minimum and maximum levels/capacity, and the power distribution avoids on/off of an individual power system.

An output performance recovering device for a fuel cell includes: a diagnosis unit configured to determine whether it is necessary to recover a catalyst of a fuel cell mounted as a power source for traveling in a vehicle from short-term performance deterioration; a recovery unit configured to control a voltage of the fuel cell and to perform recovery processing for recovering the catalyst from the short-term performance deterioration; a calculation unit configured to calculate a parameter correlated with a predicted output value of the fuel cell which has been predicted to be output on a scheduled traveling route of the vehicle based on a gradient of the scheduled traveling route of the vehicle and a predicted vehicle speed of the vehicle on the scheduled traveling route; and a determination unit configured to determine whether the parameter indicates the predicted output value is greater than a first threshold value.