Power take off gear with a hydraulic impact damper

The invention claimed is: 1. A power take off gear, comprising: a flange forming an input for the power take off gear and including a radially outwardly extending protrusion; a ring gear; a circumferentially curved piston including: a radially inwardly extending protrusion; and, a circumferential end; first and second cover plates fixedly secured to the ring gear; at least one elastic element engaged with the flange and the first and second cover plates; and, a chamber: bounded by the circumferential end of the curved piston and material forming the ring gear; and, sealed in first and second axial directions by the first and second cover plates, respectively, wherein for first torque applied to the flange in a rotational direction at a first magnitude, the flange is arranged to rotate with respect to the ring gear in the rotational direction such that: the radially outwardly extending protrusion contacts the radially inwardly extending protrusion; the flange displaces the circumferentially curved piston in the rotational direction; and, the circumferential end of the curved piston displaces fluid disposed in the chamber to dampen the rotation of the flange in the first rotational direction. 2. The power take off gear of claim 1 , wherein for second torque applied to the flange in the rotational direction and at a second magnitude, greater than the first magnitude, the flange is arranged to rotate with respect to the ring gear in the rotational direction such that: the radially outwardly extending protrusion contacts the ring gear; and, the second torque is transmitted to the ring gear in the rotational direction. 3. The power take off gear of claim 1 , wherein the first and second cover plates are in contact with the circumferentially curved piston. 4. The power take off gear of claim 1 , further comprising an interface of a radially outermost portion of the circumferentially curved piston with the ring gear and wherein the circumferential end of the circumferentially curved piston is arranged to displace the fluid in the chamber through the interface. 5. The power take off gear of claim 1 , wherein for the first torque applied to the flange in the rotational direction at the first magnitude, the circumferential end of the circumferentially curved piston is arranged to displace in the rotational direction with respect to the ring gear to reduce a volume of the first space. 6. A power take off gear, comprising: a flange forming an input for the power take off gear and including a radially outwardly extending protrusion; a ring gear at least partially rotatable with respect to the flange and including: first and second oppositely facing radial sides; and, first and second circumferentially disposed and circumferentially aligned slots; a curved piston circumferentially displaceable with respect to the ring gear and including: first and second radially inwardly extending protrusions at least partially circumferentially aligned with the radially outwardly extending protrusion; and, first and second circumferential ends disposed in the first and second slots, respectively; at least one elastic element engaged with the flange and the first and second cover plates; and, first and second cover plates: fixedly secured to the first and second radial sides, respectively; and, sealing the first and second slots in first and second axial directions, respectively, wherein: the first slot is bounded radially inwardly and outwardly and at a first circumferential end by material forming the ring gear; and, the second slot is bounded radially inwardly and outwardly and at a second circumferential end by material forming the ring gear. 7. The power take off gear of claim 6 , wherein: for first torque applied to the flange in a first rotational direction at a first magnitude, the flange is arranged to rotate with respect to the ring gear in the first rotational direction such that: the radially outwardly extending protrusion contacts the first radially inwardly extending protrusion; the flange displaces the curved piston in the first rotational direction; the first end of the curved piston displaces in the first rotational direction in the first slot; and, the first end displaces fluid disposed in the first slot to dampen motion of the flange in the first rotational direction. 8. The power take off gear of claim 6 , wherein: for second torque applied to the flange in the first rotational direction and at a second magnitude, greater than the first magnitude, the flange is arranged to rotate with respect to the ring gear in the first rotational direction such that: the radially outwardly extending protrusion contacts the ring gear; and, the second torque is transmitted to the ring gear in the first rotational direction. 9. The power take off gear of claim 8 , wherein when the radially outwardly extending protrusion contacts the ring gear, a space is present in the first slot between the first circumferential end of the curved piston and the first circumferential end of the slot. 10. The power take off gear of claim 6 , wherein the first circumferential end of the piston is arranged to displace the fluid disposed in the first slot by forcing the fluid along a path radially disposed between the curved piston and the ring gear. 11. The power take off gear of claim 6 , wherein for torque applied to the flange in the first rotational direction and below the first magnitude, the flange is arranged to rotate with respect to the ring gear in the first rotational direction such that: the at least one elastic element is at least partially compressed; and, the radially outwardly extending protrusion and the first radially inwardly extending protrusion are separated by a space in a circumferential direction. 12. The power take off gear of claim 6 , wherein for torque applied to the flange in a second rotational direction, opposite the first rotational direction, and at the first magnitude, the flange is arranged to rotate with respect to the ring gear in the second rotational direction such that: the radially outwardly extending protrusion contacts the second radially inwardly extending protrusion; the flange displaces the curved piston in the second rotational direction; the second end of the curved piston displaces in the second rotational direction in the second slot; and, the second end displaces the fluid disposed in the second slot to dampen motion of the flange in the second rotational direction. 13. The power take off gear of claim 6 , wherein the first and second cover plates are in contact with the curved piston. 14. The power take off gear of claim 6 , wherein the first and second cover plates are sealed to the ring gear at respective radially outer circumferences of the first and second cover plates. 15. A power take off gear, comprising: a flange forming an input for the power take off gear and including a radially outwardly extending protrusion forming a portion of a radially outer circumference of the flange; a ring gear including: first and second oppositely facing radial sides; and, first and second slots: bounded radially inwardly and outwardly by material forming the ring gear; and, including first and second openings, respectively, facing each other in a circumferential direction; a curved piston disposed in the first and second openings, respectively and with first and second radially inwardly extending protrusions; first and second cover plates: fixedly secured to the first and second radial sides; sealed to the ring gear at respective radially