Abstract: An apparatus and method for controlling a purge valve of a fuel cell vehicle are provided to reduce a consumption amount of hydrogen and improve fuel efficiency. In particular, whether oxygen concentration in a channel of an anode of a fuel cell stack exceeds a reference value is estimated while restarting the vehicle after the vehicle is parked. Then, an open time of a purge valve is adjusted based on a parking time of a vehicle when the hydrogen concentration is greater than the reference value.

Abstract: A perceiving method and system of a stack state for a fuel cell system is provided. The method includes determining whether a vehicle provided with the fuel cell system is started and calculating a time until first condensate water is discharged through a condensate water discharging valve provided in the fuel cell system after the vehicle starts. Then, an average time until the first condensate water is discharged after the vehicle starts, at the previous starting of the vehicle is calculated over a predetermined number of times. The two calculated times are compared to determine the state of the stack or cathode of the fuel cell system without requiring additional separate components.

Abstract: An apparatus for controlling a fuel cell stack includes: a map storage storing a target relative humidity map in which a target relative humidity corresponding to a vapor pressure of the fuel cell stack and a coolant temperature of the fuel cell stack is recorded; a pressure sensor measuring an outlet pressure of the fuel cell stack; a current sensor measuring a current generated by the fuel cell stack; a water temperature sensor measuring a coolant temperature of the fuel cell stack; and a fuel cell controller configured to determine a state of the fuel cell stack using a relative humidity of the fuel cell stack based on the target relative humidity map, and to set an amount of airflow or a coolant temperature according to the state of the fuel cell stack.

Abstract: A fuel cell purging control method for controlling hydrogen purge of a fuel cell including a stack having an anode and a cathode, an air supply device having an air supply line supplying air to the cathode of the stack, a back pressure adjusting valve adjusting back pressure of the air supply device, and a hydrogen supply device supplying hydrogen to the anode of the stack, includes steps of: determining hydrogen purge of the fuel cell while the fuel cell is being normally operated, reducing back pressure of the air supply line of the fuel cell when the hydrogen purge is determined, and purging hydrogen in the anode of the fuel cell for a preset period of time after the step of reducing the back pressure.

Abstract: A system and method of controlling fuel cell system is provided that simultaneously drains condensation and purges hydrogen via single valve. In particular, condensate water is drained by opening a drain-purge valve at a point in time at which a production amount of the condensate water exceeds a capacity of a water trap. An opening time of the drain-purge valve is then determined depending on a hydrogen concentration of an anode side and a target hydrogen concentration after the draining the condensate water. Hydrogen is then purged by maintaining the drain-purge valve in a state in which it is opened for the determined opening time.

Abstract: Disclosed is a fuel cell system and a method for controlling the fuel cell system. In the method, an external air temperature and a fuel cell temperature are monitored. When a vehicle having the fuel cell system mounted therein is keyed on, a shut-off duration of the fuel cell system, a maximum external air temperature for the shut-off duration and a maximum fuel cell temperature for the shut-off duration are calculated. A gas composition of a fuel cell at a key-on time is estimated using the shut-off duration, the maximum external air temperature and the maximum fuel cell temperature. An ignition condition of the fuel cell system is set based on the estimated gas composition. Ignition of the fuel cell system is performed based on the set ignition condition.

Abstract: A fuel cell purging method is provided to effectively prevent fuel cell deterioration and degradation of durability of the fuel cell by performing hydrogen purging at a point in time at which negative pressure of an anode peaks after a fuel cell vehicle is stopped. The fuel cell purging method includes stopping the driving of a fuel cell vehicle and continuously measuring pressure of an anode of a fuel cell after the fuel cell vehicle is stopped. Additionally, hydrogen is supplied to the anode when the measured pressure of the anode reaches a negative pressure peak time point.

Abstract: An apparatus and method for controlling a purge valve of a fuel cell vehicle are provided to reduce a consumption amount of hydrogen and improve fuel efficiency. In particular, whether oxygen concentration in a channel of an anode of a fuel cell stack exceeds a reference value is estimated while restarting the vehicle after the vehicle is parked. Then, an open time of a purge valve is adjusted based on a parking time of a vehicle when the hydrogen concentration is greater than the reference value.

Abstract: A perceiving method and system of a stack state for a fuel cell system is provided. The method includes determining whether a vehicle provided with the fuel cell system is started and calculating a time until first condensate water is discharged through a condensate water discharging valve provided in the fuel cell system after the vehicle starts. Then, an average time until the first condensate water is discharged after the vehicle starts, at the previous starting of the vehicle is calculated over a predetermined number of times. The two calculated times are compared to determine the state of the stack or cathode of the fuel cell system without requiring additional separate components.

Abstract: A control method and system of a fuel cell system is provided. The control method includes detecting, by a controller, a voltage of a fuel cell stack when power generation of a fuel cell is stopped while a fuel cell vehicle is being driven. In addition, hydrogen supply pressure at an anode side is adjusted based on a variation in the detected voltage.

Abstract: The present disclosure relates to a method of controlling an air flow in a fuel cell, capable of periodically supplying air to a cathode and alleviating a rate at which a hydrogen concentration of an anode is decreased in an Idle stop state in which air supply to the cathode of a stack is stopped in order to suppress dry phenomenon of the fuel cell.

Abstract: A system for a fuel cell vehicle is provided. The system includes an electrolytic cell installed to react residual hydrogen or oxygen within a stack when a fuel cell starts up and is shut down instead of an auxiliary resistor mounted on an exterior of a stack, thereby increasing stack durability. Particularly, the system for the fuel cell vehicle includes a stack unit of a fuel cell and an electrolytic cell unit configured to store energy in the form of hydrogen or oxygen.

Abstract: Disclosed is a fuel cell system and a method for controlling the fuel cell system. In the method, an external air temperature and a fuel cell temperature are monitored. When a vehicle having the fuel cell system mounted therein is keyed on, a shut-off duration of the fuel cell system, a maximum external air temperature for the shut-off duration and a maximum fuel cell temperature for the shut-off duration are calculated. A gas composition of a fuel cell at a key-on time is estimated using the shut-off duration, the maximum external air temperature and the maximum fuel cell temperature. An ignition condition of the fuel cell system is set based on the estimated gas composition. Ignition of the fuel cell system is performed based on the set ignition condition.

Abstract: A system and method of controlling a performance of a fuel cell stack is provided. In particular, the output performance of the fuel cell stack is determined by comparing the difference between an initial voltage and a voltage after a predetermined time lapses with the difference between the initial voltage and a preset minimum voltage.

Abstract: A system and method of controlling fuel cell system is provided that simultaneously drains condensation and purges hydrogen via single valve. In particular, condensate water is drained by opening a drain-purge valve at a point in time at which a production amount of the condensate water exceeds a capacity of a water trap. An opening time of the drain-purge valve is then determined depending on a hydrogen concentration of an anode side and a target hydrogen concentration after the draining the condensate water. Hydrogen is then purged by maintaining the drain-purge valve in a state in which it is opened for the determined opening time.

Abstract: A method for recovering performance of a fuel-cell stack is provided. When hydrogen used as fuel of the fuel-cell stack is contaminated, air is supplied to an anode instead of hydrogen to remove impurities and recover the performance of the fuel-cell stack. The method includes supplying air to an anode of the fuel-cell stack in an operation stop state of the fuel-cell stack to decrease a stack voltage.

Abstract: The present invention provides a humidification system for a fuel cell, in which a plurality of membrane humidifiers employing hollow fiber membranes of different kinds having different diameters and pore sizes, or having different numbers of hollow fiber membranes is selectively used according to the amount of current generated from a fuel cell stack or a vehicle output, thus adjusting the humidification amount for dry air to be supplied to a fuel cell stack, and preventing the flooding phenomenon caused at a cathode and the starvation phenomenon in which the air supply is insufficient at the cathode.