Pneumatic controller

We claim: 1. A pneumatic controller for connecting to a vacuum source and providing a temporary vacuum output signal to a controlled device in response to an input signal, the pneumatic controller comprising: a valve body, the valve body including a vacuum port, a control port and a vent port; a differential chamber located within the valve body, the differential chamber being segregated by a diaphragm into first and second chambers, the first chamber being selectively coupled to atmospheric pressure and to the vacuum port, the second chamber being in communication with the vacuum port; a control chamber located with the valve body, the control chamber being in communication with the control port and also being coupled to the vacuum port by an isolation port; and a valve moveably connected to the diaphragm and being moveable between sealed engagement with the isolation port and sealed engagement with the vent port, during sealed engagement of the valve with the isolation port the control chamber being configured to communicate atmospheric pressure from the vent port to the control port, during sealed engagement of the valve with the vent port the control chamber being configured to communicate vacuum pressure from the vacuum port to the control port through the isolation port, the valve including a valve stem and a sealing member, the sealing member being axially moveable relative to the valve stem between a first axial position and a second axial position while remaining in sealed engagement with the isolation port and while remaining in sealed engagement with the vent port, the sealing member also including spaced apart first and second seals extending circumferentially about the sealing member at opposite ends thereof. 2. The pneumatic controller according to claim 1 , wherein in the first axial position the valve stem and the sealing member define an overall length that is shorter than an overall length defined by the valve stem and the sealing member when in the second axial position. 3. The pneumatic controller according to claim 1 , wherein the sealing member is in sliding engagement with the valve stem. 4. The pneumatic controller according to claim 1 , wherein the sealing member is movably connected to the valve stem at a distal end of the valve stem. 5. The pneumatic controller according to claim 1 , wherein the sealing member is movably connected to the valve stem by a pin. 6. The pneumatic controller according to claim 5 , wherein the pin is received within a slot. 7. The pneumatic controller according to claim 6 , wherein the slot is defined in the valve stem and the pin extends from the sealing member through the slot. 8. The pneumatic controller according to claim 1 , wherein the sealing member encircles the valve stem. 9. The pneumatic controller of claim 1 , further comprising a force applying member in biased engagement with the valve, and wherein the force applying member exerts a predetermined force on the valve and permits movement of the valve from sealed engagement with the isolation port to sealed engagement with the vent port only upon a predetermined pressure differential being established between atmospheric pressure in the first chamber and vacuum pressure the second chamber. 10. A pneumatic controller for connecting to a vacuum source and providing a temporary vacuum output signal to a controlled device in response to an input signal, the pneumatic controller comprising: a valve body, the valve body including a vacuum port, a control port and a vent port; a differential chamber located within the valve body, the differential chamber being segregated by a diaphragm into first and second chambers, the first chamber being selectively coupled to atmospheric pressure and to the vacuum port, the second chamber being in communication with the vacuum port; a control chamber located with the valve body, the control chamber being in communication with the control port and also being coupled to the vacuum port by an isolation port; a valve moveably connected to the diaphragm and being moveable between sealed engagement with the isolation port and sealed engagement with the vent port, during sealed engagement of the valve with the isolation port the control chamber being configured to communicate atmospheric pressure from the vent port to the control port, during sealed engagement of the valve with the vent port the control chamber being configured to communicate vacuum pressure from the vacuum port to the control port through the isolation port, the valve including a valve stem and a sealing member, the sealing member being moveably connected to the valve stem and moveable between first and second positions relative to the valve stem and respectively engaging the isolation port and the vent port, the sealing member including axially spaced apart first and second seals, the first seal being configured to engage the isolation port and the second seal being configured to engage the vent port; and a force applying member in biased engagement with the valve, the force applying member configured to exert a predetermined force on the valve and permit movement of the valve from sealed engagement with the isolation port to sealed engagement with the vent port only upon a predetermined pressure differential being established between atmospheric pressure in the first chamber and vacuum pressure in the second chamber. 11. The pneumatic controller of claim 10 , further comprising an adjustment feature cooperating with the force applying member, the adjustment feature configured to provide the predetermined force as an adjustable predetermined force. 12. The pneumatic controller of claim 1 , wherein the force applying member and the adjustment feature are components of a detent. 13. The pneumatic controller of claim 12 , wherein the detent is a ball detent. 14. The pneumatic controller of claim 10 , wherein the force applying member is a ball bearing biased by a spring. 15. The pneumatic controller of claim 10 , wherein the valve includes a valve stem having a reduced diameter portion, the force applying member engaging the reduced diameter portion when the valve is in sealed engagement with the isolation port. 16. The pneumatic controller of claim 15 , wherein the valve stem includes a larger diameter portion adjacent to the reduced diameter portion, the force applying member engaging the larger diameter portion when the valve is in sealed engagement with the vent port. 17. The pneumatic controller of claim 10 , further comprising: a third chamber located within the valve body; and a fourth chamber located within the valve body, the fourth chamber being segregated from the third chamber by a sensor diaphragm and being selectively coupled by a second valve to the first chamber to provide atmospheric pressure to the first chamber upon increased pressure in the third chamber. 18. The pneumatic controller of claim 17 , wherein the third chamber is coupled to a sensor port configured to receive and communicate increased pressure to the third chamber.