Reversible gerotor pump system

We claim: 1. A reversible gerotor pump system, comprising a cylindrical housing comprising a slot of 180 degree along a periphery of the housing, and the slot being defined by a first end at top and a second end at bottom, an eccentric ring positioned within the housing with a radial clearance C 3 between the eccentric ring and the housing, a locking pin being fixed to the eccentric ring and movably engaged between the first end and the second end in the slot, an outer rotor positioned within the eccentric ring with a radial clearance C 2 between the eccentric ring and the outer rotor, the outer rotor being eccentric with the eccentric ring and comprising a plurality of internal teeth with recesses between adjacent teeth, an inner rotor positioned within the outer rotor, the inner rotor comprising a plurality of external teeth, wherein at least a portion of the external teeth of the inner rotor are engaged with at least a portion of the internal teeth of the outer rotor, and the inner rotor and the outer rotor are eccentric relative to one another with an inner rotor tip clearance Ci being defined as a radial clearance between a tip of the external teeth and corresponding portion of the outer rotor, and the plurality of meshed teeth of the inner rotor and the outer rotor form a plurality of cavities that expand and contract as the shaft, inner rotor, and outer rotor rotate; a shaft being coupled with the inner rotor for rotatably driving the inner rotor with a radial clearance C 1 between the shaft and the inner rotor, a suction port for providing hydraulic fluid to the cavity being expanded, the suction port comprising an upstream side and a downstream side, and a discharge port for discharging hydraulic fluid from the cavity being contracted, wherein the locking pin stops at the first end to stop rotation of the eccentric ring when the shaft rotates in clockwise direction in a first position; when the shaft rotates in reverse direction, the eccentric ring is driven to rotate in counterclockwise rotation direction by contact force between the eccentric ring and the outer rotor to pass through a second position where the eccentric ring, the inner rotor, and the outer rotor rotate as one part along with the shaft, and the radial clearance C 3 is greater than the sum of C 1 , C 2 , and Ci in the second position; the locking pin stops at the second end to stop rotation of the eccentric ring when the shaft rotates in the counterclockwise direction in a third position; and the suction port and the discharge port respectively function for sucking and discharging a hydraulic fluid unidirectionally in both clockwise and counterclockwise rotation directions wherein the eccentric ring is of convex profile on outer diameter. 2. The reversible gerotor pump system of claim 1 , wherein interior diameter contact is present at radial clearances C 1 and C 2 at the second position. 3. The reversible gerotor pump system of claim 1 , further comprising a positive contact system, wherein the positive contact system increases frictional force between an interior side of the eccentric ring and the outer rotor for rotation. 4. The reversible gerotor pump system of claim 3 , wherein a positive contact mechanism comprises a cavity at the interior side of the eccentric ring, a spring inside the cavity in a constantly compressed state, and a plunger inside the cavity and being constantly pressed by the spring, wherein compression of the spring applies a load N on the outer rotor through the plunger, and friction force F′ of formula F′=μ*N, μ is a coefficient of the frictional contact, is applied to rotate the eccentric ring with the outer rotor and inner rotor during rotation direction change. 5. The reversible gerotor pump system of claim 4 , wherein the plunger is coated with a Ferritic Nitro-Carburizing (FNC) friction coating. 6. The reversible gerotor pump system of claim 4 , wherein the cavity is formed by a drill through hole in the eccentric ring with a cap added at the outer diameter of the eccentric ring. 7. The reversible gerotor pump system of claim 1 , wherein a positive contact system is a frictional disc brake type mechanism comprising spring, piston, and pads, and the frictional disc brake system provides spring force to hold the eccentric ring and the outer rotor at the second position, and outlet pressure releases pads and allow the eccentric ring and the outer rotor to rotate freely in the first and third positions. 8. The reversible gerotor pump system of the claim 1 , wherein the locking pin moves in the slot with clearance at both clockwise and counterclockwise directions to provide a self-damping effect to avoid loading impact. 9. The reversible gerotor pump system of the claim 1 , further comprising prolongations on the suction port at the upstream side and the downstream side, wherein the prolongations increase filling time for the cavities when the reversible gerotor pump system rotates. 10. The reversible gerotor pump system of the claim 9 , wherein fill speed is above 5000 rpm. 11. The reversible gerotor pump system of the claim 10 , wherein volumetric efficiency is at least 90% at 5000 rpm. 12. A transmission system for vehicles comprising the reversible gerotor pump system of claim 1 . 13. An electric vehicle comprising the transmission system of claim 12 . 14. The electric vehicle of claim 13 , wherein the electric vehicle is a heavy duty truck.