Automatic testable breather valve

We claim: 1. A breather valve comprising: a housing having a bottom portion having an opening and side portions; a rigid substrate located within the housing; a breathable membrane mounted to the rigid substrate, the rigid substrate forming an aperture that allows the breathable membrane to breathe; a gasket having a top surface and a bottom surface, the gasket having an upper energy director located at the top surface and a lower energy director located at the bottom surface; and a preloaded compression element across the gasket and the rigid substrate, the preloaded compression element providing at least: a first compressive position providing a contact between the lower energy director and the bottom portion of the housing, and a second compressive position in which air passes around the lower energy director and the upper energy director. 2. The breather valve of claim 1 , wherein in the first compressive position, the lower energy director forms a seal around the opening in the bottom portion of the housing to prevent air and water from penetrating through the gasket. 3. The breather valve of claim 1 , wherein the housing includes a top portion with a plurality of openings and wherein the preloaded compression element provides a third compressive position providing a contact between the upper energy director and the top portion of the housing. 4. The breather valve of claim 3 , wherein in the third compressive position, the upper energy director forms a seal around one of the plurality of openings of the top portion to prevent air and water from penetrating through the gasket. 5. The breather valve of claim 4 , wherein the preloaded compression element is normally in the first compressive position and wherein the preloaded compression element may be moved to the second compressive position and the third compressive position by an external probe. 6. The breather valve of claim 1 , wherein the upper energy director and the lower energy director are formed along an outer perimeter of the gasket. 7. The breather valve of claim 1 , wherein the housing includes threaded grooves on outer surfaces of the side portions such that the housing can be fastened into a valve opening of an electronic device. 8. The breather valve of claim 7 , wherein the breathable membrane is permeable to air and impermeable to water. 9. The breather valve of claim 1 , wherein the rigid substrate is a stainless steel substrate and wherein the breathable membrane is mounted to the rigid substrate with an adhesive seal. 10. The breather valve of claim 1 , wherein the gasket is over molded to a perimeter of the rigid substrate and the breathable membrane. 11. The breather valve of claim 1 , wherein the preloaded compression element is a preloaded spring. 12. A portable communication device comprising: a sealed, device housing including a valve opening between an exterior and an interior of the portable communication device, a breather valve positioned at the valve opening, the breather valve including: a housing a bottom portion having an opening and side portions; a rigid substrate located within the housing; a breathable membrane mounted to the rigid substrate, the rigid substrate forming an aperture that allows the breathable membrane to breathe; a gasket having a top surface and a bottom surface, the gasket having an upper energy director located at the top surface and a lower energy director located at the bottom surface; and a preloaded compression element across the gasket and the rigid substrate, the preloaded compression element providing at least: a first compressive position providing a contact between the lower energy director and the bottom portion of the housing, and a second compressive position in which air passes around the lower energy director and the upper energy director. 13. The portable communication device of claim 12 , wherein the valve opening includes first threaded grooves and the breather valve includes second threaded grooves such that the breather valve can be fastened into the valve opening. 14. The portable communication device of claim 12 , wherein in the first compressive position, the lower energy director forms a seal around the opening in the bottom portion of the housing to prevent air and water from penetrating through the gasket. 15. The portable communication device of claim 12 , wherein the housing includes a top portion with a plurality of openings and wherein the preloaded compression element provides a third compressive position providing a contact between the upper energy director and the top portion of the housing. 16. The portable communication device of claim 15 , wherein in the third compressive position, the upper energy director forms a seal around one of the plurality of openings of the top portion to prevent air and water from penetrating through the gasket. 17. The portable communication device of claim 16 , wherein the preloaded compression element is normally in the first compressive position and wherein the preloaded compression element may be moved to the second compressive position and the third compressive position by an external probe. 18. The portable communication device of claim 12 , wherein the upper energy director and the lower energy director are formed along an outer perimeter of the gasket. 19. The portable communication device of claim 12 , wherein the breathable membrane is permeable to air and impermeable to water. 20. The portable communication device of claim 12 , wherein the rigid substrate is a stainless steel substrate and wherein the breathable membrane is mounted to the rigid substrate with an adhesive seal.