Manifold block of fuel cell stack and method of manufacturing the same

What is claimed is: 1. A manifold block mounted to a fuel cell stack for supplying and distributing air and hydrogen to the stack, the manifold block comprising: a main body including a hydrogen inlet, a hydrogen outlet, an air inlet and an air outlet; a hydrogen outlet cover attached to an outer surface of the main body, the hydrogen outlet cover including a condensation chamber connected to the hydrogen outlet; an air inlet cover attached to an inner surface of the main body, the air inlet cover including an air inflow portion connected to the air inlet; and an air outlet cover attached to the inner surface of the main body, the air outlet cover including an air outflow portion connected to the air outlet; wherein the main body includes an air inflow passage sealed by the air inlet cover and an air outflow passage sealed by the air outlet cover, wherein the manifold block includes an air cutoff valve (ACV) cover attached to the outer surface of the main body, the ACV cover having holes, and wherein the ACV cover is connected to both an inlet of the air inflow passage and an outlet of the air outflow passage. 2. The manifold block of claim 1 , wherein the air inlet cover and the air outlet cover are welded to the inner surface of the main body by laser welding, and the ACV cover and the hydrogen outlet cover are welded to the outer surface of the main body by laser welding. 3. The manifold block of claim 1 , wherein the air inlet cover and the air outlet cover attached to the inner surface of the main body are disposed along outer edge portions thereof with flange portions which include a welding groove or a welding protrusion for laser welding, and the inner surface of the main body has a remaining one of the welding groove and the welding protrusion for the laser welding. 4. The manifold block of claim 1 , wherein the hydrogen outlet cover welded to the outer surface of the main body is disposed along an outer edge portion with a flange portion which include a welding groove or a welding protrusion for laser welding, and the outer surface of the main body has a remaining one of the welding groove and the welding protrusion for the laser welding. 5. The manifold block of claim 1 , further comprising: an air inlet guide block assembled with the inner surface of the main body, the air inlet guide block surrounding the air inflow portion in the air inlet cover and the hydrogen outlet in the main body to serve as one of walls of a gasket groove formed in an upper end of the air inflow portion and as one of walls of a gasket groove formed in an upper end of the hydrogen outlet. 6. The manifold block of claim 1 , further comprising: an air outlet guide block assembled with the inner surface of the main body, the air outlet guide block surrounding the air outflow portion in the air outlet cover and the hydrogen inlet in the main body to serve as one of walls of a gasket groove formed in an upper end of the air outflow portion and as one of walls of a gasket groove formed in an upper end of the hydrogen inlet. 7. The manifold block of claim 1 , further comprising: a hydrogen interface for supply of hydrogen, the hydrogen interface being assembled with the outer surface of the main body to be connected to the hydrogen inlet in the main body. 8. The manifold block of claim 7 , further comprising: an ejector diffuser assembled between the hydrogen outlet cover and the hydrogen interface, wherein one side wall of the hydrogen outlet cover, to which one end portion of the ejector diffuser is coupled, is formed to be perpendicular to a longitudinal direction of the ejector diffuser. 9. The manifold block of claim 1 , wherein the main body, the hydrogen outlet cover, the air inlet cover, the air outlet cover and the ACV cover are formed of a plastic material. 10. A method of manufacturing a manifold block that is mounted to a fuel cell stack for supplying and distributing air and hydrogen to the stack, the method comprising: forming a main body including a hydrogen inlet, a hydrogen outlet, an air inlet and an air outlet; forming a hydrogen outlet cover including a condensation chamber connected to the hydrogen outlet; forming an air inlet cover including an air inflow portion connected to the air inlet; forming an air outlet cover including an air outflow portion connected to the air outlet; and welding the hydrogen outlet cover to an outer surface of the main body and welding the air inlet cover and the air outlet cover to an inner surface of the main body, wherein the main body is formed to include an air inflow passage sealed by the air inlet cover and an air outflow passage sealed by the air outlet cover, and wherein the method further comprises: forming an air cutoff valve (ACV) cover having a hole, wherein the ACV is connected to both an inlet of the air inflow passage and an outlet of the air outflow passage; and welding the ACV cover to the outer surface of the main body. 11. The method of claim 10 , wherein the air inlet cover, the air outlet cover, the hydrogen outlet cover and the ACV cover are welded to the main body by laser welding. 12. The method of claim 11 , further comprising: forming a flange portion, including a welding groove or a welding protrusion for laser welding, along an outer edge portion of the hydrogen outlet cover; and forming a remaining one of the welding groove and the welding protrusion for the laser welding on the outer surface of the main body. 13. The method of claim 11 , further comprising: forming a flange portion, including a welding groove or a welding protrusion for laser welding, along an outer edge portion of the air inlet cover; and forming a remaining one of the welding groove and the welding protrusion for the laser welding on the inner surface of the main body. 14. The method of claim 11 , further comprising: forming a flange portion, including a welding groove or a welding protrusion for laser welding, along an outer edge portion of the air outlet cover; and forming a remaining one of the welding groove and the welding protrusion for the laser welding on the inner surface of the main body. 15. The method of claim 10 , further comprising: assembling an air inlet guide block with the inner surface of the main body after the welding, wherein the air inlet guide block surrounds the air inflow portion and the hydrogen outlet to serve as one of walls of a gasket groove formed in an upper end of the air inflow portion and as one of walls of a gasket groove formed in an upper end of the hydrogen outlet. 16. The method, of claim 10 , further comprising: assembling an air outlet guide block with the inner surface of the main body after the welding, wherein the air outlet guide block surrounds the air outflow portion and the hydrogen inlet to serve as one of walls of a gasket groove formed in an upper end of the air outflow portion and as one of walls of a gasket groove formed in an upper end of the hydrogen inlet. 17. The method of claim 10 , further comprising: assembling a hydrogen interface for supply of hydrogen with the outer surface of the main body to be connected to the hydrogen inlet in the main body. 18. The method of claim 17 , further comprising: assembling an ejector diffuser between the hydrogen outlet cover and the hydrogen interface, wherein in the forming the hydrogen outlet cover, one side wall of the hydrogen outlet cover, to which one end portion of the ejector diffuser is coupled, is formed to be perpendicular to a longitudinal direction of the ejector diffus