Mechanism and system for rotating an elongate member of an oil pump

What is claimed is: 1. A rotator mechanism for rotating an elongate member in a pumping system, the rotator mechanism comprising: a body member having a longitudinal body axis and a through-hole aligned with the body axis and configured to receive a portion of the elongate member; a worm gear set coupled to the body member and including: a worm gear disposed about the body axis; and a worm meshing with the worm gear and having a worm axis, a worm first end, and a worm second end spaced-apart from the first end along the worm axis, the worm rotatably coupled to the body member; a lever coupled to the worm, the lever configured to rotate the worm relative to the body member; a first clutch coupled between the lever and the worm first end and configured to cause the worm to rotate in a first direction about the worm axis when the lever moves in the first direction about the worm axis and configured to allow the lever to rotate freely relative to the worm when the lever moves in a second direction about the worm axis, opposite the first direction; and a second clutch coupled to the worm and configured to allow the worm to rotate in the first direction about the worm axis and to prevent the worm from rotating in the second direction about the worm axis; wherein the worm gear is configured to rotate the elongate member about the body axis when the worm rotates in the first direction about the worm axis; and wherein the first and second clutches each have a plurality of circumferentially-spaced sprags, each clutch configured to allow rotation of an outer race relative to an inner race in a first direction about the worm axis while preventing the rotation of the outer race relative to the inner race in the opposite direction wherein the inner race of the first clutch is coupled for rotation with the worm, and the outer race of the first clutch is coupled for rotation with the lever. 2. The rotator mechanism of claim 1 wherein the first clutch is disposed beyond the worm first end and outside the body member; and wherein the second clutch is disposed axially-adjacent the worm second end and outside the body member; and wherein the worm is at least partially enclosed in the body member, and the worm axis extends within the body member. 3. The rotator mechanism of claim 1 wherein the clutches each include a plurality of circumferentially-spaced bearing elements disposed axially-adjacent the plurality of circumferentially-spaced sprags. 4. The rotator mechanism of claim 1 wherein the worm gear set is a self-locking worm gear set configured to allow the worm to rotate in the first direction about the worm axis and configured to inhibit rotation of the worm in the second direction about the worm axis. 5. The rotator mechanism of claim 1 further comprising: a cap having an annular head disposed about the body axis, a first face on the annular head, a generally tubular body extending from the annular head opposite the first face, a radially-extending shoulder on the tubular body, the shoulder being spaced-apart from the annular head and oriented opposite the first face; wherein the tubular body extends into the through-hole of the body member, and at least a portion of the annular head of the cap is disposed outside the body member; wherein the shoulder of the cap engages a first face of the worm gear for rotation with the worm gear; and wherein the first face of the cap is configured to couple and support the elongate member. 6. The rotator mechanism of claim 1 wherein the elongate member is configured to reciprocate and is selected from a group comprising: a polished rod, a sucker rod, and a pumping string; and wherein the rotator mechanism and the elongate member are configured to reciprocate together when coupled to a reciprocating member of the pumping system. 7. The rotator mechanism of claim 1 wherein the inner race of the first clutch is disposed axially beyond the worm and is rotationally fixed relative to the worm. 8. The rotator mechanism of claim 7 wherein rotation of the outer race of the first clutch in the first direction by an angle delta causes the inner race of the first clutch and the worm to rotate in the first direction about the worm axis; and wherein the angle delta is between zero and less than 15 degrees. 9. The rotator mechanism of claim 8 wherein the angle delta is between zero and 7.5 degrees. 10. The rotator mechanism of claim 8 wherein the angle delta is between zero and 2 degrees. 11. A rotator mechanism for rotating an elongate member in a pumping system, the rotator mechanism comprising: a body member having a longitudinal body axis and a through-hole aligned with the body axis and configured to receive a portion of the elongate member; a worm gear set coupled to the body member and including: a worm gear disposed about the body axis; and a worm meshing with the worm gear and having a worm axis, a worm first end, and a worm second end, the worm rotatably coupled to the body member; a lever coupled to the worm, the lever configured to rotate the worm relative to the body member; and a first clutch coupled between the lever and the worm first end and configured to cause the worm to rotate in a first direction about the worm axis when the lever moves in the first direction about the worm axis and configured to allow the lever to rotate relative to the worm when the lever moves in a second direction about the worm axis, opposite the first direction; wherein the first clutch is coupled between the worm and a first clutch housing, and the first clutch housing is coupled between the first clutch and the lever; wherein the first clutch housing extends along the worm axis away from the first clutch, and the lever is spaced-apart from the first clutch along the worm axis; wherein the first clutch housing is rotatable relative to the body member; and wherein the worm gear is configured to rotate the elongate member about the body axis when the worm rotates in the first direction about the worm axis. 12. The pumping system of claim 11 wherein the first clutch housing comprises a first end, a second end spaced-apart from the first end, and a through-bore extending from the first end to the second end and aligned with the worm axis; wherein the first clutch is disposed within the through-bore at the first end of the first clutch housing; wherein the worm first end extends into through-bore at the second end of the first clutch housing; wherein the lever is coupled to the second end of the first clutch housing, spaced-apart from the first clutch; and wherein the first clutch housing is configured to transfer a torque from the lever to the first clutch, and the first clutch is configured to transfer the torque to the worm when the lever moves in the first direction about the worm axis. 13. The pumping system of claim 12 wherein the first clutch is disposed axially beyond the worm and includes an inner race and an outer race; wherein the outer race couples to the first clutch housing and is configured to transfer the torque; and wherein a shaft plug extends axially between the inner race and the worm first end, and is configured to transfer the torque therebetween. 14. The pumping system of claim 12 further comprising: a second clutch coupled to the worm and configured to allow the worm to rotate in the first direction about the worm axis and to prevent the worm from rotating in the second direction about the worm axis; and a second clutch housing having a first end, a second end spaced-apart from the first end, and a through-bore extending from the first end to the second end