Systems and methods for a latchable refueling valve

The invention claimed is: 1. A latching mechanism for a valve, comprising: an armature including each of an upper and a lower offset rounded cam element formed integrally thereon and an upper armature portion with a first, larger outer diameter and a lower armature portion with a second, smaller outer diameter, the upper and lower cam elements integrally formed on the lower armature portion, a rotation sleeve concentrically surrounding the armature and including a plurality of cam guides, the rotation sleeve concentrically surrounding only the lower armature portion, a solenoid actuator, a valve core attached to the armature and configured to transmit electromagnetic force into motion against a spring wherein, movement of the armature toward the spring engages armature cams with the cam guides to impart rotation between the armature and the rotation sleeve, and movement of the armature away from the spring seats the valve in one of a first or a second desired valve position, wherein the spring is attached to an upper axial surface of the upper armature portion, and wherein a lower axial surface of the upper armature portion is seated on an upper axial end of the rotation sleeve in the first desired valve position. 2. The latching mechanism of claim 1 , wherein the plurality of cam guides is identical, each cam guide including: a first prong with a first upper angled surface and a first lower angled surface, and a second prong with a second upper angled surface and a second lower angled surface; wherein the first and second upper angled surfaces are parallel to each other and configured to contact the upper cam element; wherein the first and second lower angled surfaces are parallel to each other and configured to contact the lower cam element; and wherein the upper angled surfaces are perpendicular to the lower angled surfaces. 3. The latching mechanism of claim 2 , wherein the upper cam element is positioned between the second prong of a first cam guide and the first prong of an adjacent second cam guide at the first desired valve position; and wherein the upper cam element is seated between the first upper angled surface and the second prong of the second cam guide at the second desired valve position. 4. The latching mechanism of claim 3 , wherein movement from the first desired valve position to the second desired valve position includes: movement of the armature toward the spring that engages the lower cam element with the second lower angled surface of the first cam guide and imparts rotation of the cam elements away from the first cam guide, and subsequent movement of the armature away from the spring that engages the upper cam element with the first upper angled surface of the second cam guide and imparts rotation of the armature that seats the upper cam element between the first upper angled surface and the second prong of the second cam guide. 5. The latching mechanism of claim 4 , wherein movement from the second desired valve position to the first desired valve position includes: movement of the armature toward the spring that engages the lower cam element with the first lower angled surface of the second cam guide and imparts rotation of the cam elements away from the first cam guide, and subsequent movement of the armature away from the spring that engages the upper cam element with the second upper angled surface of the second cam guide and imparts rotation of the armature that seats the upper cam element between the second cam guide and a third cam guide. 6. The latching mechanism of claim 5 , wherein the first desired valve position is an open position and the second desired valve position is a closed position. 7. The latching mechanism of claim 6 , wherein the imparting rotation includes a fixed armature moving the rotation sleeve from a first angular position to a second angular position. 8. The latching mechanism of claim 6 , wherein the imparting rotation includes a fixed rotation sleeve moving the armature from a first angular position to a second angular position. 9. A system for a hybrid-electric vehicle, comprising: an engine; a fuel tank coupled to a fuel vapor canister via each of a first conduit and a second conduit; a tank pressure control valve coupled in the first conduit between the fuel tank and the fuel vapor canister; a latchable refueling valve coupled in the second conduit between the fuel tank and the fuel vapor canister, the latchable refueling valve including a lower latch index, an upper latch index angularly offset from the lower latch index, and first and second latch guiding teeth; and a controller configured with instructions stored in non-transitory memory and executable by a processor for: in response to a refueling request: opening the tank pressure control valve while maintaining the latchable refueling valve closed at an unlatched, closed position; and when fuel tank pressure is lower than a first pressure threshold, actuating the latchable refueling valve with a voltage pulse to a latched, open position to transfer fuel vapors into the fuel vapor canister, wherein the lower latch index and the upper latch index include rounded ends configured to contact respective lower planar surfaces and upper planar surfaces of each of the first and second latch guiding teeth. 10. The system of claim 9 , wherein actuating the latchable refueling valve to a latched open position includes engaging the lower surface of the first latch guiding tooth with the lower latch index to align the upper latch index with a notch partially formed by the upper surface of the second latch guiding tooth. 11. The system of claim 10 , wherein: the first and second latch indices are formed integrally from an armature, the first and second latch guiding teeth are formed integrally from a latch guide sleeve surrounding the armature, an angular position of the latch guide sleeve is stationary within the latchable refueling valve, and aligning the upper latch index with the notch includes a rotation of the armature within the latch guide sleeve. 12. The system of claim 10 , wherein: the first and second latch indices are formed integrally from an armature, the first and second latch guiding teeth are formed integrally from a latch guide sleeve surrounding the armature, an angular position of the armature is stationary within the latchable refueling valve, and aligning the upper latch index with the notch includes a rotation of the latch guide sleeve about the armature.