Fluid control valve system and methods

What is claimed is: 1. A method of pressurizing a chamber in a fluid control valve having a diaphragm member, the method comprising: increasing an angle between a plane defined by a perimeter of an annular base portion and a radial projection extending inwardly from the annular base portion, the radial projection disposed within an internal chamber of the fluid control valve to abut an upper surface of the diaphragm member; seating the diaphragm member to form a gas chamber axially spaced from a liquid supply chamber; forming a gas seat between the gas and liquid chambers; decreasing the angle between the plane and the radial projection; and disengaging the diaphragm member from a surface of the chamber, the increasing of the angle being about a first pivot point and the decreasing of the angle being about a second pivot point that is different from the first pivot point. 2. The method of claim 1 , further comprising: sliding a free end of the radial projection against the diaphragm member upper surface. 3. The method of claim 1 , wherein seating the diaphragm member includes defining a concave upper surface and a convex lower surface of the diaphragm member. 4. A method of pressurizing a chamber in a fluid control valve having a diaphragm member, the method comprising: increasing an angle between a plane defined by a perimeter of an annular base portion and a radial projection extending inwardly from the annular base portion, the radial projection disposed within an internal chamber of the fluid control valve to abut an upper surface of the diaphragm member; seating the diaphragm member to form a gas chamber axially spaced from a liquid supply chamber; forming a gas seat between the gas and liquid chambers; decreasing the angle between the plane and the radial projection; and disengaging the diaphragm member from a surface of the chamber, the increasing of the angle and the decreasing of the angle being about a pivot point that moves when the radial projection transitions between a depressed position and a deflected position of the radial projection. 5. The method of claim 4 , further comprising: sliding a free end of the radial projection against the diaphragm member upper surface. 6. The method of claim 4 , wherein seating the diaphragm member includes defining a concave upper surface and a convex lower surface of the diaphragm member. 7. A fluid control valve comprising: a valve body having a first inner surface defining a chamber having a first axis and a second axis substantially perpendicular to the first axis, the chamber including an inlet and an outlet in communication with the chamber and substantially aligned along the first axis, the inner surface including an elongated seat member substantially aligned along the second axis, the seat member defining a groove, a portion of the body further defining a port in communication with the groove; a diaphragm member disposed within the chamber for controlling communication between the inlet and the outlet, the diaphragm member having an upper surface and a lower surface, the lower surface including at least a pair of spaced apart elongated members defining a channel therebetween, the diaphragm member having a first position permitting communication between the inlet and the outlet and a second position wherein the elongated members engage the seat member such that the channel is in communication with the groove to define an intermediate chamber in communication with the port; and a depression member disposed within the chamber for moving the diaphragm member into the second position, the depression member having an annular base portion and a plurality of radial projections extending inwardly from the base portion, each radial projection having an arcuate portion with a mounting end and an opposing free end and having a resilient portion disposed between the mounting end and the base portion, the resilient portion defining a pivot point about which the radial projection pivots when moving the diaphragm member into the second position, wherein when the diaphragm member is in the second position, the upper surface defines a substantially concave surface and the lower surface defines a convex surface, the resilient portion of each radial projection of the depression member having an increasing angle with a plane defined by the annular base portion and a decreasing angle with the plane wherein any one of: (i) the increasing of the angle being about a first pivot point and the decreasing of the angle being about a second pivot point that is different from the first pivot point; or (ii) the increasing of the angle and the decreasing of the angle being about a pivot point that moves when the radial projection transitions between a depressed position and a deflected position of the radial projection. 8. The fluid control valve of claim 7 , wherein the elongated members define a substantially tapering cross-sectional area. 9. The fluid control valve of claim 7 , wherein the diaphragm member defines a central axis substantially perpendicular to the first and second axes, wherein further each of the elongated members includes an angled surface relative to the central axis extending from the lower surface of the diaphragm member to define a sidewall surface of the channel. 10. The fluid control valve of claim 7 , wherein the seat member defines a curvilinear surface having an arc length for engaging the lower surface of the diaphragm member, the groove extending along the curvilinear surface for substantially the entire arc length. 11. The fluid control valve of claim 7 , wherein the valve body includes an input opening and a fluid drain opening disposed about the seat member, the input opening being in communication with the outlet and the fluid drain opening being in communication with the inlet. 12. The fluid control valve of claim 7 , wherein the valve body defines a central axis substantially perpendicular to the first and second axes, the port being substantially aligned with the central axis. 13. The fluid control valve of claim 7 , the free end of each radial projection being in sliding engagement with the diaphragm member upper surface. 14. The fluid control valve of claim 7 , the resilient portion having a depressed position in which the diaphragm member is in the second position and having a deflected position in which the resilient portion is reversibly deformed, the arcuate portion remaining undeformed when the resilient portion moves between the depressed and deflected positions. 15. The fluid control valve of claim 7 , the annular base portion including an inwardly-facing surface, the plurality of radial projections being distributed equidistantly about the inwardly-facing surface. 16. The fluid control valve of claim 7 , each of the radial projections having a width along a length of the arcuate portion, the width varying along the length of the arcuate portion. 17. The fluid control valve of claim 7 , the annular base portion having a perimeter defining a plane, the resilient portion extending from the base portion to dispose the arcuate portion at an angle to the plane to define a depression angle between the arcuate portion and the plane, the resilient portion having a depressed position defining a first depression angle and a deflected position defining a second depression angle, the first depression angle being greater than the second depression angle. 18. The fluid control valve of claim 7 , the annular base portion including an inwardly-facing surface, the plurality of radial projections