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

What is claimed is: 1. A fuel cell separator for supplying reactant gas to a membrane-electrode assembly of a fuel cell stack, the fuel cell separator comprising: reactant gas inlet through holes for introducing reactant gases; reactant gas outlet though holes for discharging the reactant gases; and a coolant inlet through hole for introducing a coolant; and a coolant outlet through hole for discharging the coolant, wherein the reactant gas inlet through holes and the reactant gas outlet through holes are alternately formed along an 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 one of the reactant gases is an oxidizing gas, and a first oxidizing agent inlet through hole, a first oxidizing agent outlet through hole, a second oxidizing agent inlet through hole, and a second oxidizing agent outlet through hole are sequentially formed along a first side edge of the fuel cell separator, for an introduction and exhaust of the oxidizing gas, wherein one of the reactant gases is a fuel gas, and a first fuel inlet through hole, a first fuel outlet through hole, a second fuel inlet through hole, and a second fuel outlet through hole are sequentially formed along a second side edge of the fuel cell separator, which is opposite to the first side edge, for an introduction and exhaust of the fuel gas, wherein the coolant inlet through hole and the coolant outlet through hole are respectively formed on opposite edges of the full cell separator on which the reactant gas inlet through holes and the reactant gas outlet though holes are not formed, and wherein the coolant flows in a direction in which the oxidizing gas flows. 2. The fuel cell separator of claim 1 , wherein the reactant gas passages are oxidizing agent passages, and the oxidizing agent passages are formed on one of the opposite surfaces to interconnect the oxidizing agent inlet through holes and the oxidizing agent outlet through holes such that a plurality of channels can be bent one time to form a U-shaped flow. 3. The fuel cell separator of claim 1 , wherein the reactant gas passages are oxidizing agent passages, and the oxidizing agent passages are formed on one of the opposite surfaces to interconnect the oxidizing agent inlet through holes and the oxidizing agent outlet through holes such that a plurality of channels can be bent at least two times to form a meander-shaped flow. 4. The fuel cell separator of claim 1 , wherein the reactant gas passages are fuel passages, and the fuel passages are formed on one of the opposite surfaces to interconnect the fuel inlet through holes and the fuel outlet through holes such that a plurality of channels can be bent one time to form a U-shaped flow. 5. The fuel cell separator of claim 1 , wherein the reactant gas passages are fuel passages, and the fuel passages are formed on one of the opposite surfaces to interconnect the fuel inlet through holes and the fuel outlet through holes such that a plurality of channels can be bent at least two times to form a meander-shaped flow.