Fuel cell separator and fuel cell stack and reactant gas control method thereof

The invention claimed is: 1. A fuel cell stack comprising: a plurality of unit cells stacked with one another, each unit cell including a membrane-electrode assembly and a pair of separation plates; and end plates that are located on opposite ends of a body formed by the stacked plurality of unit cells, the end plates including a first end plate coupled to one end of the body and a second end plate coupled to the other end of the body, wherein the pair of separation plates of each unit cell form a fuel cell separator, the fuel cell separator comprising; reactant gas inlet through holes for introducing reactant gases; and reactant gas outlet through holes for discharging the reactant gases, wherein the reactant gas inlet through holes and the reactant gas outlet through holes are alternately formed along a first side edge of the fuel cell separator and one or more passages are formed on at least one of opposite surfaces of the fuel cell separator to connect the reactant gas inlet through holes to the respective reactant gas outlet through holes, wherein the end plates are provided with: reactant gas inlet ports installed on the first end plate for supplying the reactant gases and corresponding to the reactant gas inlet through holes; reactant gas outlet ports installed on the first end plate for discharging residual reactant gases and reaction by-product and corresponding to the reactant gas outlet through holes; and valves which are installed on pipes connecting the reactant gas inlet ports to the reactant gas outlet ports to control reactant gas flow, the pipes including a first pipe and a second pipe which are installed on the first end plate and a third pipe which is installed on the second end plate, wherein the reactant gas inlet ports and the reactant gas outlet ports are alternately formed on the first end plate, wherein one of the reactant gases is an oxidizing gas, wherein the reactant gas inlet ports include: first and second oxidizing agent inlet ports installed on the first end plate for supplying the oxidizing gas; and a third oxidizing agent inlet port installed on the second end plate and sharing a first manifold with the second oxidizing agent inlet port, wherein the reactant gas outlet ports include: first and second oxidizing agent outlet ports installed on the first end plate for discharging residual oxidizing gas and the reaction by-product; and a third oxidizing agent outlet port installed on the second end plate and sharing a second manifold with the first oxidizing agent outlet port, wherein the valves include: an oxidizing agent inlet valve installed on the first pipe interconnecting the first and second oxidizing agent inlet ports to control flow of the oxidizing gas; an oxidizing agent outlet valve installed on the second pipe interconnecting the first and second oxidizing agent outlet ports to control flow of the oxidizing gas; and an oxidizing agent intermediate valve installed on the third pipe interconnecting the third oxidizing agent inlet port and the third oxidizing agent outlet port to control oxidizing gas flow, and wherein the oxidizing agent intermediate valve is structured to be opened when the oxidizing agent inlet valve and the oxidizing agent outlet valve are closed in a high load operation condition, wherein the third oxidizing agent outlet port and the first oxidizing agent inlet port are fluidly connected through the second manifold, and the third oxidizing agent inlet port and the second oxidizing agent inlet port are fluidly connected through the first manifold, and wherein the first oxidizing agent inlet port, the second oxidizing agent inlet port, the third oxidizing agent outlet, and the third oxidizing agent inlet port are structured such that the oxidizing gas is supplied through the first oxidizing agent inlet port and discharged through the third oxidizing agent outlet port, and then the discharged oxidizing gas is supplied through the third oxidizing agent inlet port and discharged through the second oxidizing agent outlet port in the high load operation condition. 2. The fuel cell stack of claim 1 , wherein: one of the reactant gases is a fuel gas; the reactant gas inlet ports are first and second fuel inlet ports for supplying the fuel gas; and the reactant gas outlet ports are first and second fuel outlet ports for discharging residual fuel gas. 3. The fuel cell stack of claim 2 , wherein one of the valves is a fuel inlet valve, which is installed on a pipe interconnecting the first and second fuel inlet ports to control flow of the fuel gas. 4. The fuel cell stack of claim 2 , wherein one of the valves is a fuel outlet valve, which is installed on a pipe interconnecting the first and second fuel outlet ports to control flow of the fuel gas. 5. The fuel cell stack of claim 2 , wherein: the reactant gas inlet ports further include a third fuel inlet port sharing a manifold with the second fuel inlet port; and the reactant gas outlet ports further include a third fuel outlet port sharing a manifold with the first fuel outlet port. 6. The fuel cell stack of claim 5 , wherein the valves further include a fuel intermediate valve, which is installed on a pipe interconnecting the third fuel inlet and outlet ports to control fuel gas flow. 7. The fuel cell stack of claim 1 , wherein the oxidizing agent intermediate valve is configured and structured to be opened in the high load operation condition, such that the oxidizing gas supplied through only the first oxidizing agent inlet port is not output via the first oxidizing outlet port, but passes through the third oxidizing agent outlet port, the oxidizing agent intermediate valve, and the third oxidizing agent inlet port, before finally being discharged through the second oxidizing agent outlet port in the high load operation condition. 8. The fuel cell stack of claim 1 , wherein the oxidizing agent inlet valve and the oxidizing agent outlet valves are configured and structured to be opened, and the oxidizing agent intermediate valve is configured and structured to be closed in a low load operation condition. 9. The fuel cell stack of claim 8 , wherein the oxidizing gas is uniformly supplied to the first and second oxidizing agent inlet ports in the low load operation condition such that the oxidizing gas is discharged through the first and second oxidizing agent outlet ports in the low load operation condition.