Environment control system utilizing an electrochemical cell

What is claimed is: 1. An environment control system that is coupled with an enclosure and comprises: a) an oxygen control electrolyzer cell, wherein the oxygen control electrolyzer cell comprises: i) an ion exchange medium; ii) an anode; iii) a cathode; wherein the anode and cathode are configured on opposing sides of the ion exchange medium; wherein the oxygen control electrolyzer cell is an integral membrane electrode assembly (MEA) comprising: a housing attached to said oxygen control electrolyzer cell; an anode opening in the housing to provide a flow of air to the anode; a cathode opening in the housing to provide a flow of air to the cathode; b) a controller that is coupled with a power source and the oxygen control electrolyzer cell to control electrical potential across the anode and the cathode; wherein an oxygen concentration within an enclosure is controlled by the oxygen control electrolyzer cell; c) a humidification control device; d) a conditioning chamber in fluid communication with the enclosure; e) a humidity control chamber; wherein the humidification control device is in fluid communication with the humidity control chamber; wherein the oxygen control electrolyzer cell is fluid communication with the conditioning chamber; and f) a separator configured between the conditioning chamber and the humidification control device for transporting moisture between the humidity control chamber and the conditioning chamber; wherein the separator comprises ionomer and is substantially air impermeable having no bulk flow of gas therethrough. 2. The environment control system of claim 1 , wherein the oxygen control electrolyzer cell is an oxygen reduction electrolyzer cell having the cathode in fluid communication with the enclosure; and wherein said power source is coupled with the anode and cathode to provide an electrical potential across the anode and the cathode to initiate electrolysis of water, wherein water is reacted to form oxygen and protons on the anode and said protons react with oxygen at the cathode to form cathode side water, thereby reducing oxygen concentration in the enclosure. 3. The environment control system of claim 2 , wherein the humidity control device comprises a humidity control electrolyzer cell, wherein the humidity control electrolyzer cell comprises: i) an ion exchange medium; ii) an anode; iii) a cathode; wherein the anode and cathode of the humidity control electrolyzer cell are configured on opposing sides of the ion exchange medium of the humidity control electrolyzer cell. 4. The environment control system of claim 1 , wherein the oxygen control electrolyzer cell is an oxygen elevation electrolyzer cell having the anode in fluid communication with the enclosure; and wherein said power source is coupled with the anode and cathode to provide an electrical potential across the anode and the cathode to initiate electrolysis of water, wherein water is reacted to form oxygen and protons on the anode and said protons react with oxygen at the cathode to form cathode side water, thereby increasing oxygen concentration in the enclosure. 5. The environment control system of claim 4 , further comprising: i) an oxygen control chamber in fluid communication with the enclosure; wherein the oxygen control electrolyzer cell is fluid communication with the oxygen control chamber; wherein the separator is configured between the oxygen control chamber and the humidity control chamber for transporting moisture between said oxygen control chamber and said humidity control chamber; wherein the separator comprises ionomer and is substantially air impermeable. 6. The environment control system of claim 5 , wherein the humidity control device comprises a humidity control electrolyzer cell, wherein the humidity control electrolyzer cell comprises: i) an ion exchange medium; ii) an anode; iii) a cathode; wherein the anode and cathode of the humidity control electrolyzer cell are configured on opposing sides of the ion exchange medium of the humidity control electrolyzer cell. 7. The environment control system of claim 1 , wherein the integral membrane electrode assembly comprises adhesive bonding the membrane electrode assembly to said housing of the integral membrane electrode assembly. 8. The environment control system of claim 7 , wherein the adhesive is a pressure sensitive adhesive. 9. The environment control system of claim 7 , wherein the adhesive is a thermoplastic adhesive and wherein the thermoplastic adhesive is melted to adhere the MEA to the housing. 10. The environment control system of claim 7 , wherein the adhesive is couple to a gasket to form a gasket-adhesive that extends around an electrode of the MEA. 11. The environment control system of claim 7 , wherein the housing of the integral membrane electrode assembly is a rigid housing. 12. The environment control system of claim 7 , wherein the housing of the integral membrane electrode assembly is an air permeable fabric. 13. The environment control system of claim 12 , wherein the housing of the integral membrane electrode assembly is a non-woven fabric. 14. The environment control system of claim 1 , wherein the MEA comprises a discrete current collector that extends out from a contact with at least one of the anode or cathode. 15. The environment control system of claim 1 , wherein the electrode area of the anode or cathode is no more than about 20 cm 2 . 16. An environment control system that is coupled with an enclosure and comprises: a) an oxygen control electrolyzer cell, wherein the oxygen control electrolyzer cell comprises: i) an ion exchange medium; ii) an anode; iii) a cathode; wherein the anode and cathode are configured on opposing sides of the ion exchange medium; b) a controller that is coupled with a power source and the oxygen control electrolyzer cell to control electrical potential across the anode and the cathode; wherein an oxygen concentration within an enclosure is controlled by the oxygen control electrolyzer cell; c) an oxygen control chamber coupled to the oxygen control electrolyzer cell and comprising an exchange conduit; d) a conditioning chamber, wherein at least a portion of the exchange conduit is configured within the conditioning chamber; e) a humidification control device; wherein the humidification control device is in fluid communication with the conditioning chamber; wherein at least a portion of the exchange conduit is configured with a separator to transfer moisture from the exchange conduit into the conditioner chamber; wherein the separator comprises ionomer and is substantially air impermeable having no bulk flow of gas therethrough. 17. The environment control system of claim 16 , wherein the oxygen control electrolyzer cell is an oxygen reduction electrolyzer cell having the cathode in fluid communication with the enclosure; and wherein said power source is coupled with the anode and cathode to provide an electrical potential across the anode and the cathode to initiate electrolysis of water, wherein water is reacted to form oxygen and protons on the anode and said protons react with oxygen at the cathode to form cathode side water, thereby reducing oxygen concentration in the enclosure. 18. The environment control system of claim 16 , wherein the humidity control device comprises a humidity control electrolyzer cell, wherein the humidity control electrolyzer cell comprises: i) an ion exchange medium; ii) an anode; iii) a cathode; wherei