Damper and latching assemblies for electrical switching devices

We claim: 1. An electrical switching device, comprising: a sidewall; a first shaft configured to translate between a first and a second position in relation to the sidewall; a first contact mounted on the first shaft; a second contact, wherein the first contact and the first shaft are configured so that the first contact is in electrical contact with the second contact when the first shaft is in the first position, and the first contact is out of electrical contact with the second contact when the first shaft is in the second position; and a damper and latching assembly comprising: the first shaft; a second shaft mounted for rotation on the sidewall, the second shaft being configured so that, during operation, the first shaft rotates the second shaft from a first to a second angular position of the second shaft as the first shaft moves from the first to the second position of the first shaft; a first rotating member mounted for rotation on the sidewall between a first and a second angular position, the first rotating member comprising a third shaft, the third shaft being configured to, during operation, engage the first shaft when the first shaft is in the second position of the first shaft and the first rotating member is in the second angular position of the first rotating member, the engagement of the third shaft and the first shaft restraining the first shaft in the second position of the first shaft; a second rotating member mounted on the second shaft and configured so that, during operation, rotation of the second shaft from the first to the second angular position of the second shaft causes the second rotating member to rotate from a first to a second angular position of the second rotating member; and a spring coupled to a third rotating member that is mounted for rotation on the sidewall and also coupled to the second rotating member, the third rotating member being configured so that, during operation, rotation of the second rotating member from the first to second angular position of the second rotating member causes the third rotating member to rotate from a first to a second angular position of the third rotating member, and the third rotating member imparts the energy to the first spring as the third rotating member is rotated from the first to the second angular position of the third rotating member, wherein rotation of the second shaft from the first to the second angular position of the second shaft imparts energy to the spring via the third rotating member, and at least a portion of the energy imparted to the spring biases the first rotating member toward the first angular position of the first rotating member as the first rotating member rotates from the second to the first angular position of the first rotating member. 2. The device of claim 1 , wherein the first shaft is biased toward the first position of the first shaft and is configured to, during operation, move from the second to the first position of the first shaft as the first rotating member rotates from the second to the first angular position of the first rotating member. 3. The device of claim 1 , wherein the spring is a torsion spring and is configured so that, during operation, the rotation of the third rotating member from the first to the second angular position of the third rotating member imparts the energy to the spring by winding the spring. 4. The device of claim 1 , wherein the energization of the spring dampens the movement of the first shaft from the first to the second position of the first shaft. 5. The device of claim 1 , wherein the third shaft has a substantially D-shaped cross section. 6. The device of claim 1 , wherein: the damper and latching assembly further comprises a solenoid, and a paddle connected to the solenoid, the solenoid being configured to, during operation, rotate the paddle between a first and a second angular position of the paddle; and the paddle is configured to contact the third rotating member when the third rotating member is in the second angular position of the third rotating member, and to rotate the third rotating member toward the first angular position of the third rotating member as the paddle moves from the first to the second angular position of the paddle. 7. The device of claim 1 , wherein the third rotating member is configured so that, during operation, the third rotating member rotates the third shaft from the second to the first position of the third shaft as the third rotating member rotates from the second to the first position of the third rotating member, thereby releasing the first shaft from the third shaft. 8. The device of claim 1 , wherein: the first shaft comprises a step, and the third shaft is further configured to, during operation, engage the step when the first shaft is in the second position of the first shaft and the first rotating member is in the second angular position of the first rotating member; and the engagement of the step and the first shaft restrains the first shaft in the second position of the first shaft. 9. The device of claim 1 , wherein: the first shaft has a substantially planar surface; the second shaft has a substantially planar surface configured to, during operation, contact the surface of the first shaft as the first shaft rotates the second shaft from the first to the second angular position of the second shaft; and an orientation of the surface the first shaft substantially matches an orientation of the surface of the second shaft as the first shaft rotates the second shaft from the first to the second angular position of the second shaft. 10. The device of claim 1 , wherein the first shaft is configured to, during operation, prevent rotation of the first rotating member from the first to the second position of the first rotating member when the first shaft is in the first position of the first shaft. 11. The device of claim 1 , wherein the first rotating member is configured so that, during operation, rotation of the third rotating member from the first to the second angular position of the third rotating member causes the first rotating member to rotate from the first to the second angular position of the first rotating member. 12. The device of claim 11 , wherein: the spring is a first spring; the damper and latching assembly further comprises a second spring coupled to the first rotating member and the sidewall; and the second spring is configured to, during operation, bias the first rotating member toward the second angular position of the first rotating member. 13. The device of claim 1 , wherein: the damper and latching assembly further comprises a coupling member, a mounting pin that engages the coupling member and the second rotating member, and a coupling pin that engages the coupling member and the third rotating member; the second rotating member is coupled to the third rotating member by way of the coupling member, the mounting pin, and the coupling pin; and the coupling member is configured so that, during operation, the coupling pin is disengaged from the third rotating member when the second rotating member is in the second angular position of the second rotating member thereby decoupling the third rotating member from the second rotating member. 14. The device of claim 13 , wherein: the third rotating member comprises a side member having an opening formed therein; and the coupling pin is configured to, during operation, reside within the opening and out of contact with the third rotating member when the second rotating member is in the second angular position of the second rotating member. 15.