Gas flow controller including valve decoupling mechanism

What is claimed is: 1. A gas flow controller for use in a gas fired apparatus including a pilot burner and a main burner, the controller comprising: a pilot valve moveable between a closed position and an open position to provide selective fluid communication between a gas inlet and the pilot burner; a main burner valve providing selective fluid communication between the gas inlet and the main burner; an actuator configured to open the pilot valve upon actuation of the actuator; a flow controller valve operable to open and close a fluid flow path between the gas inlet and a back side of the main burner valve upon actuation of the actuator; and a decoupling mechanism configured to connect the actuator to the pilot valve and to selectively disconnect the actuator from the pilot valve when the actuator is actuated and a pressure differential across the pilot valve exceeds a threshold pressure limit, wherein the decoupling mechanism prevents the pilot valve from opening when the actuator is actuated and the pressure differential across the pilot valve exceeds the threshold pressure limit. 2. The gas flow controller of claim 1 , wherein the decoupling mechanism includes a shaft, an engagement member slidably connected to the shaft, and a biasing element configured to exert a biasing force on the engagement member. 3. The gas flow controller of claim 2 , wherein the shaft includes a retaining element, the biasing element configured to bias the engagement member towards the retaining element, wherein the engagement member is configured to disengage the retaining element to operably disconnect the actuator from the pilot valve. 4. The gas flow controller of claim 1 , further comprising an interconnecting member having a first end connected to the pilot valve and a second end distal from the first end, the interconnecting member configured to pivot about a fulcrum to open and close the pilot valve, wherein the decoupling mechanism is configured to engage the interconnecting member between the second end and the fulcrum upon actuation of the actuator. 5. The gas flow controller of claim 4 , wherein the interconnecting member has an aperture defined therein and the flow controller valve includes a valve stem configured to engage a shaft of the decoupling mechanism to open and close the flow controller valve, wherein at least one of the valve stem and the shaft of the decoupling mechanism extends through the aperture defined in the interconnecting member. 6. The gas flow controller of claim 1 , wherein the decoupling mechanism enables actuation of the flow controller valve when the actuator is actuated regardless of the pressure differential across the pilot valve. 7. The gas flow controller of claim 1 , wherein the actuator is movable from a first position to a second position, the actuator configured to open both the pilot valve and the flow controller valve when the actuator is moved from the first position to the second position and the pressure differential across the pilot valve is less than the threshold pressure limit. 8. The gas flow controller of claim 1 , wherein the actuator includes a manually depressible knob including a first end configured to be manually actuated by a user, and an opposing second end configured to engage the decoupling mechanism. 9. The gas flow controller of claim 1 , wherein the main burner valve is located in fluid communication between the pilot valve and the main burner, and the flow controller valve is located in fluid communication between the pilot valve and the back side of the main burner valve. 10. A gas flow controller for use in a gas fired apparatus including a pilot burner and a main burner, the controller comprising: a pilot valve moveable between a closed position and an open position to provide selective fluid communication between a gas inlet and the pilot burner; a main burner valve providing selective fluid communication between the gas inlet and the main burner; an actuator configured to open the pilot valve upon actuation of the actuator; a flow controller valve operable to open and close a fluid flow path between the gas inlet and a back side of the main burner valve upon actuation of the actuator; and a decoupling mechanism interconnecting the actuator to the pilot valve, the decoupling mechanism configured to limit an opening force applied to the pilot valve upon actuation of the actuator, wherein the decoupling mechanism prevents the pilot valve from opening when the actuator is actuated and a pressure differential across the pilot valve exceeds a threshold pressure limit. 11. The gas flow controller of claim 10 , further comprising an interconnecting member having a first end connected to the pilot valve and a second end distal from the first end, the interconnecting member configured to pivot about a fulcrum to open and close the pilot valve. 12. The gas flow controller of claim 11 , wherein the decoupling mechanism includes an engagement member and a decoupling spring configured to bias the engagement member towards the interconnecting member, the engagement member configured to engage the interconnecting member between the fulcrum and the second end of the interconnecting member upon actuation of the actuator. 13. The gas flow controller of claim 12 , wherein the decoupling spring limits the opening force applied to the pilot valve upon actuation of the actuator. 14. A gas flow controller for use in a gas fired apparatus including a pilot burner and a main burner, the controller comprising: a pilot valve moveable between a closed position and an open position to provide selective fluid communication between a gas inlet and the pilot burner; an actuator configured to open the pilot valve upon actuation of the actuator; a main burner valve providing selective fluid communication between the gas inlet and the main burner; a flow controller valve operable to open and close a fluid flow path between the gas inlet and a back side of the main burner valve upon actuation of the actuator; an interconnecting member having a first end connected to the pilot valve and a second end distal from the first end, the interconnecting member configured to pivot about a fulcrum to open and close the pilot valve; and a decoupling mechanism including a shaft, an engagement member slidably connected to the shaft, and a biasing element configured to bias the engagement member towards the interconnecting member, whereby actuation of the actuator causes the engagement member to engage the interconnecting member between the second end of the interconnecting member and the fulcrum, and apply a limited opening force to the pilot valve. 15. The gas flow controller of claim 14 , wherein the shaft includes a retaining element configured to inhibit movement of the engagement member along the shaft in a first direction, and permit movement of the engagement member along the shaft in a second direction opposite the first direction. 16. The gas flow controller of claim 15 , wherein the engagement member includes a tubular member and an annular retaining lip extending radially inward from the tubular member, the retaining lip configured to engage the retaining element of the shaft to inhibit movement of the engagement member along the shaft in the first direction. 17. The gas flow controller of claim 14 , wherein the decoupling mechanism enables actuation of the flow controller valve when the actuator is actuated regardless of a pressure differential across the pilot valve.