A valve assembly is disclosed for controlling fluid flow between two reservoirs. The valve assembly includes a relief valve arranged inside the housing and configured to open a first fluid flow path when the first reservoir is above a first predetermined pressure value.
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1. A valve assembly configured for controlling fluid flow between a first reservoir and a second reservoir, each reservoir being arranged externally with respect to the valve assembly, the valve assembly comprising: a valve housing;a relief valve arranged inside the valve housing and configured to o
1. A valve assembly configured for controlling fluid flow between a first reservoir and a second reservoir, each reservoir being arranged externally with respect to the valve assembly, the valve assembly comprising: a valve housing;a relief valve arranged inside the valve housing and configured to open a first fluid flow path inside the valve housing when a pressure inside the first reservoir is above a first predetermined pressure value;a solenoid assembly arranged inside the valve housing and configured to open a second fluid flow path inside the valve housing when a rate of the fluid flow from the first reservoir to the second reservoir is above a predetermined reference value;a flow restrictor arranged inside the valve housing and configured to open a third fluid flow path inside the valve housing when the rate of the fluid flow from the first reservoir to the second reservoir is below the predetermined reference value, and when the pressure inside the first reservoir is below a second predetermined pressure value;a stop plate configured to limit travel of the piston toward the flow restrictor; anda catch mechanism arranged inside the valve housing and operatively connected to the solenoid assembly;wherein: the solenoid assembly includes an armature configured to selectively open and close the flow restrictor;the armature includes a piston and a plunger; andthe catch mechanism connects the piston to the plunger and is configured to permit the plunger to translate away from the flow restrictor such that the third fluid flow path is opened without displacing the piston. 2. The valve assembly according to claim 1, wherein the first predetermined pressure value is greater than the second predetermined pressure value. 3. The valve assembly of claim 1, further comprising a plunger spring configured to preload the plunger against the stop plate and press the plunger against the flow restrictor to maintain the flow restrictor in a closed position, and a coil configured to energize the armature and overcome the plunger spring to open the flow restrictor. 4. The valve assembly of claim 3, further comprising a solenoid spring configured to generate a force sufficient to close the restrictor by displacing the armature, wherein the coil is additionally configured to overcome the solenoid spring. 5. The valve assembly according to claim 3, wherein the coil is configured to overcome the plunger spring when the rate of the fluid flow is below the predetermined reference value. 6. The valve assembly according to claim 3, wherein the plunger spring is configured to generate a force sufficient to close the third fluid flow path when the pressure inside the first reservoir is a positive value, but insufficient to close the third fluid flow path when the pressure inside the first reservoir is a negative value. 7. The valve assembly according to claim 1, wherein the flow restrictor is configured to be normally closed, the valve assembly further comprising a spring configured to urge the flow restrictor to open. 8. The valve assembly according to claim 1, wherein at least one of the relief valve and the flow restrictor includes an inward-sloped pressure seal configured to seal the corresponding relief valve and the flow restrictor against the housing. 9. The valve assembly according to claim 1, further comprising a cover configured to retain the relief valve, the flow restrictor, and the solenoid assembly inside the housing. 10. The valve assembly according to claim 9, wherein the cover engages and interconnects with the housing via a snap-fit. 11. The valve assembly according to claim 9, further comprising a static seal configured to seal the cover against the housing. 12. The valve assembly according to claim 11, wherein the static seal is an O-ring type seal. 13. The valve assembly according to claim 1, wherein the valve housing comprises a first recess for receiving the flow restrictor and a second recess for receiving the relief valve, wherein the valve assembly further comprises a static seal surrounding the first recess and the second recess, and wherein the first recess and the second recess are fluidly connected to form a portion of the first fluid flow path. 14. An evaporative emissions control system comprising: a controller;a first reservoir;a second reservoir; anda valve assembly configured to control fluid flow between the first reservoir and the second reservoir, wherein each reservoir is arranged externally with respect to the valve assembly, the valve assembly including: a valve housing;a relief valve arranged inside the valve housing and configured to open a first fluid flow path inside the valve housing when a pressure inside the first reservoir is above a first predetermined pressure value;a solenoid assembly regulated by the controller, arranged inside the valve housing, and configured to open a second fluid flow path inside the valve housing when a rate of the fluid flow from the first reservoir to the second reservoir is above a predetermined reference value;a flow restrictor arranged inside the valve housing and configured to open a third fluid flow path inside the valve housing when the rate of the fluid flow from the first reservoir to the second reservoir is below the predetermined reference value, and when the pressure inside the first reservoir is below a second predetermined pressure value;a catch mechanism arranged inside the valve housing and operatively connected to the solenoid assembly; anda stop plate arranged inside the valve housing;wherein: the solenoid assembly includes an armature configured to selectively open and close the flow restrictor, and the armature includes a piston and a plunger;the catch mechanism connects the piston to the plunger and is configured to permit the plunger to translate away from the flow restrictor such that the third fluid flow path is opened without displacing the piston; andthe stop plate is configured to limit travel of the piston toward the flow restrictor. 15. The evaporative emissions control system according to claim 14, wherein the first predetermined pressure value is greater than the second predetermined pressure value. 16. The evaporative emissions control system of claim 14, further comprising a plunger spring configured to preload the plunger against the stop plate and press the plunger against the flow restrictor to maintain the flow restrictor in a closed position, and a coil configured to energize the armature and overcome the plunger spring to open the flow restrictor. 17. The evaporative emissions control system of claim 16, further comprising a solenoid spring configured to generate a force sufficient to close the restrictor by displacing the armature, wherein the coil is additionally configured to overcome the solenoid spring. 18. The evaporative emissions control system according to claim 17, wherein the coil is configured to overcome the plunger spring when the rate of the fluid flow is below the predetermined reference value. 19. The evaporative emissions control system according to claim 17, wherein the plunger spring is configured to generate a force sufficient to close the third fluid flow path when the pressure inside the first reservoir is a positive value, but insufficient to close the third fluid flow path when the pressure inside the first reservoir is a negative value. 20. The evaporative emissions control system according to claim 14, wherein the flow restrictor is configured to be normally closed, the valve assembly further comprising a spring configured to urge the flow restrictor to open.
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