System and method for controlling fuel cell system

What is claimed is: 1. A method for controlling a fuel cell system, the method comprising: calculating, by a processor, a fuel cell demand current based on a driver demand current calculated from a driver demand torque; calculating, by the processor, a first target flow rate of air to be supplied to a fuel cell stack based on the fuel cell demand current and a target stoichiometric ratio (SR) of air; calculating, by the processor, a calculated SR based on an air flow rate and a fuel cell current; compensating, by the processor, for the first target flow rate using the target SR and the calculated SR, wherein the target SR is calculated according to a relative humidity value of the fuel cell stack and is preset to increase proportionally based on the relative humidity and the calculated SR is equal to the air flow rate divided by the fuel cell current time a constant; and calculating, by the processor, a revolutions per minute (RPM) command value of an air blower based on a compensated second target flow rate and the amount of air currently measured and controlling the operation of the air blower based on the calculated RPM command value. 2. The method of claim 1 , wherein calculating the driver demand current includes: calculating a driver demand torque based on an accelerator pedal signal according to a driver's operation of an accelerator pedal and a vehicle running speed; calculating a drive demand current based on the driver demand torque, the vehicle speed, a bus voltage, and an efficiency of a motor or inverter; and calculating a final fuel cell demand current based on the driver demand current. 3. The method of claim 2 , wherein calculating the final fuel cell demand current based on the driver demand current includes: calculating a cell demand current based on the driver demand current, a vehicle auxiliary demand current, a fuel cell system balance of plant (BOP) demand current, and a battery assist current; and compensating for the fuel cell demand current by a fuel cell compensation current including at least one of a compensation current for a fuel cell abnormal state and a compensation current for reactivity control during fuel cell restart-up. 4. The method of claim 1 , wherein compensating for the first target flow rate using the target SR includes: calculating an SR ratio of the calculated SR of air to the target SR; determining whether the calculated SR ratio is a value between a predetermined minimum value and a predetermined maximum value; and setting the first target flow rate to a second target flow rate without compensation if the SR ratio is not a value between the minimum value and the maximum value and calculating the second target flow rate by compensating the first target flow rate by the following equation (E1) if the SR ratio is a value between the minimum value and the maximum value: Second target flow rate=First target flow rate/( SR Ratio×Compensation coefficient). E1: 5. The method of claim 4 , wherein the compensation coefficient is set to a value based on the SR ratio. 6. The method of claim 1 , further comprising: calculating, by the processor, an air flow rate-based fuel cell current limit value based on the target SR and an air flow rate currently measured; determining, by the processor, a minimum value between the air flow rate-based fuel cell current limit value and a maximum fuel cell current limit value as a final fuel cell current limit value; and limiting, by the processor, the current output of a fuel cell based on the final fuel cell current limit value. 7. The method of claim 6 , wherein the air flow rate-based fuel cell current limit value is calculated from a value obtained by dividing the air flow by a current limit reference SR, the current limit reference being determined as a difference between the target SR and a predetermined offset value, and the offset value being set to a value that increases in proportion to an increase in the target SR and calculated from the target SR. 8. The method of claim 1 , wherein the target SR is set to a value that increases in proportion to an increase in an estimated relative humidity (RH) value in the fuel cell stack and calculated from the estimated RH value in the fuel cell stack. 9. A non-transitory computer readable medium containing program instructions executed by a processor, the computer readable medium comprising: program instructions that calculate a fuel cell demand current based on a driver demand current calculated from a driver demand torque; program instructions that calculate a first target flow rate of air to be supplied to a fuel cell stack based on the fuel cell demand current and a target stoichiometric ratio (SR) of air; program instructions that calculated a calculated SR based on an air flow rate and a fuel cell current; program instructions that compensate for the first target flow rate using the target SR and the calculated SR, wherein the target SR is calculated according to a relative humidity value of the fuel cell stack and is preset to increase proportionally based on the relative humidity and the calculated SR is equal to the air flow rate divided by the fuel cell current time a constant; and program instructions that calculate a revolutions per minute (RPM) command value of an air blower based on a compensated second target flow rate and the amount of air currently measured and controlling the operation of the air blower based on the calculated RPM command value. 10. The non-transitory computer readable medium of claim 9 , wherein program instructions that calculate the driver demand current include: program instructions that calculate a driver demand torque based on an accelerator pedal signal according to a driver's operation of an accelerator pedal and a vehicle running speed; program instructions that calculate a drive demand current based on the driver demand torque, the vehicle speed, a bus voltage, and an efficiency of a motor or inverter; and program instructions that calculate a final fuel cell demand current based on the driver demand current. 11. The non-transitory computer readable medium of claim 10 , wherein the program instructions that calculate the final fuel cell demand current based on the driver demand current include: program instructions that calculate the fuel cell demand current based on the driver demand current, a vehicle auxiliary demand current, a fuel cell system balance of plant (BOP) demand current, and a battery assist current; and program instructions that compensate for the fuel cell demand current by a fuel cell compensation current including at least one of a compensation current for a fuel cell abnormal state and a compensation current for reactivity control during fuel cell restart-up. 12. The non-transitory computer readable medium of claim 9 , wherein the program instructions that compensate for the first target flow rate using the target SR include: program instructions that calculate an SR of air based on a measured fuel cell current and an air flow rate; program instructions that calculate an SR ratio of the calculated SR of air to the target SR; program instructions that determine whether the calculated SR ratio is a value between a predetermined minimum value and a predetermined maximum value; and program instructions that set the first target flow rate to a second target flow rate without compensation if the SR ratio is not a value between the minimum value and the maximum value and calculating the second target flow rate by compensating the first target flow rate by the following equation (E1) when the SR ratio is a value between the minimum value and the maximum value: