Over-center linkage

1 . A compressed air driven double diaphragm pump including a twin pair of diaphragm chambers and a changeover mechanism configured alternately to pressurize and exhaust the two diaphragm chambers, the changeover mechanism comprising a shaft slidably mounted through aligned apertures in opposing surfaces of the twin diaphragm chambers, means for driving the shaft to move axially in forward and reverse directions, a valve comprising a fixed valve plate having a plurality of ports in fluid communication with the twin diaphragm chambers and a valve closure component slidably mounted with respect to the fixed valve plate for selectively closing one or more of the ports, an arm pivotably mounted with respect to the valve and engaging with the shaft, the fixed valve plate hingedly linking with the arm and resilient biasing means associated with the hinged link for biasing the position of the valve closure component to off center of the fixed valve plate. 2 . A compressed air driven double diaphragm pump as claimed in claim 1 , wherein the arm comprises a substantially U shaped frame pivotally mounted in relation to two opposing surfaces of the valve plate and slots provided in parallel extensions of the frame, a hinge is received in the slots and connects with a pair of linear tension springs which in turn are secured to the frame adjacent pivot points of the arm relative to the fixed plate. 3 . A compressed air driven double diaphragm pump as claimed in claim 2 , wherein the arms are mounted on the two opposing surfaces. 4 . A compressed air driven double diaphragm pump as claimed in claim 1 , further including a pivot element extending from the fixed valve plate to the arm, wherein the pivot element is directly connected to the arm and the fixed valve plate. 5 . A compressed air driven double diaphragm pump as claimed in claim 4 , wherein the pivot element comprises a cylindrical shaft. 6 . A compressed air driven double diaphragm pump as claimed in claim 1 , wherein the fixed valve plate pivotally supports the arm. 7 . A compressed air driven double diaphragm pump as claimed in claim 1 , wherein the fixed valve plate provides a reaction force against movement of the arm in a first direction away from the fixed valve plate that is normal to a surface of the fixed valve plate in which openings of the ports are located and movement of the valve closure component in a direction opposite the first direction. 8 . A compressed air driven double diaphragm pump as claimed in claim 1 , wherein the arm extends crosswise to the fixed valve plate. 9 . A compressed air driven double diaphragm pump as claimed in claim 1 , wherein the resilient biasing means associated with the hinged link biases the valve closure component against the fixed valve plate. 10 . A compressed air driven double diaphragm pump as claimed in claim 1 , wherein the arm comprises a substantially U shaped frame pivotally mounted in relation to two opposing surfaces of the fixed valve plate and slots provided in parallel extensions of the frame, a hinge wire pusher or fastener is received in the slots and connects with a pair of linear tension springs which in turn are secured to the frame adjacent its pivot point, the wire pusher or fastener holding the valve closure component against the fixed valve plate. 11 . A compressed air driven double diaphragm pump as claimed in claim 10 , wherein the substantially U-shaped frame is mounted on the two opposing surfaces. 12 . A compressed air driven double diaphragm pump as claimed in claim 10 , wherein the changeover mechanism is configured as a self-contained and retrofittable module. 13 . A compressed air driven double diaphragm pump as claimed in claim 10 , wherein the pair of linear tension bias the position of the valve closure component against the fixed valve plate in an off center position. 14 . A compressed air driven double diaphragm pump as claimed in claim 10 , wherein the center of the shaft between the twin pair of diaphragm chambers is provided an annular notch into which is located the arm extending from the substantially U-shaped frame. 15 . A self-contained and retrofittable module for a compressed air driven double diaphragm pump comprising a twin pair of diaphragm chambers and a changeover mechanism configured alternately to pressurize and exhaust the two diaphragm chambers, the changeover mechanism comprising a shaft slidably mounted through aligned apertures in opposing surfaces of the twin diaphragm chambers, means for driving the shaft to move axially in forward and reverse directions, a valve comprising a fixed valve plate having a plurality of ports in fluid communication with the twin diaphragm chambers and a valve closure component slidably mounted with respect to the fixed valve plate for selectively closing one or more of the ports, an arm pivotably mounted with respect to the valve and engaging with the shaft, the fixed valve plate hingedly linking with the arm and resilient biasing means associated with the hinged link for biasing the position of the valve closure component to off center of the fixed valve plate. 16 . A module as claimed in claim 15 , wherein the arm comprises a substantially U shaped frame pivotally mounted in relation to two opposing surfaces of the valve plate and slots provided in parallel extensions of the frame, a hinge is received in the slots and connects with a pair of linear tension springs which in turn are secured to the frame adjacent pivot points of the arm relative to the fixed plate. 17 . A module as claimed in claim 16 , wherein the arms are mounted on the two opposing surfaces. 18 . A module as claimed in claim 15 , further including a pivot element extending from the fixed valve plate to the arm, wherein the pivot element is directly connected to the arm and the fixed valve plate. 19 . A module as claimed in claim 18 , wherein the pivot element comprises a cylindrical shaft. 20 . A module as claimed in claim 15 , wherein the fixed valve plate pivotally supports the arm. 21 . A module as claimed in claim 15 , wherein the fixed valve plate provides a reaction force against movement of the arm in a first direction away from the fixed valve plate that is normal to a surface of the fixed valve plate in which openings of the ports are located and movement of the valve closure component in a direction opposite the first direction. 22 . A module as claimed in claim 15 , wherein the arm extends crosswise to the fixed valve plate. 23 . A module as claimed in claim 15 , wherein the resilient biasing means associated with the hinged link biases the valve closure component against the fixed valve plate. 24 . A method, comprising: alternatingly pressurizing and exhausting first and second chambers of a pump via a changeover assembly, comprising: sliding a shaft through first and second apertures in opposing sides of the first and second chambers; pivoting, in response to sliding the shaft, an arm relative to the shaft and a fixed valve plate having a plurality of ports in fluid communication with the first and second chambers; sliding, in response to pivoting the arm, a valve closure component relative to the fixed valve plate to selectively open or close one or more of the plurality of ports; and biasing a position of the valve closure component to off center of the fixed valve plate. 25 . A method as claimed in claim 24 , wherein the arm extends c