Control mechanisms and methods of tool-holding arm for exoskeletons

The invention claimed is: 1. A tool-holding arm incorporated into an exoskeleton including: a hip structure; a thigh link coupled to the hip structure at a hip joint; a shank link coupled to the thigh link at a knee joint; a foot structure coupled to the shank link at an ankle joint, wherein, when the exoskeleton is supported on a support surface, a weight of the exoskeleton is transferred from the hip structure to the support surface through the thigh link, shank link and foot structure; and an electronic control system, said tool-holding arm comprising: a plurality of links; a tool coupling configured to removably secure a tool to the tool-holding arm; a first fluid spring configured to provide a gravity-counteracting force to the tool-holding arm; and at least one of: a) a locking mechanism configured to lock the first fluid spring; and b) an adjustment mechanism configured to adjust an amount of the gravity-counteracting force provided by the first fluid spring, wherein the electronic control system of the exoskeleton is configured to control the at least one of the locking mechanism and the adjustment mechanism. 2. The tool-holding arm of claim 1 , wherein: the first fluid spring is a hydraulic or pneumatic spring; and the first fluid spring includes a first rod, a first plunger and a first cylinder. 3. The tool-holding arm of claim 2 , wherein the tool-holding arm includes the locking mechanism. 4. The tool-holding arm of claim 3 , wherein the locking mechanism is a valve, the valve being configured to control a flow of a fluid into and out of the first cylinder. 5. The tool-holding arm of claim 2 , wherein the tool-holding arm includes the adjustment mechanism. 6. The tool-holding arm of claim 5 , wherein the adjustment mechanism includes: a second rod; a second plunger; a second cylinder; and a fluid conduit configured to transfer a fluid between the second cylinder and the first cylinder, wherein a position of the second plunger within the second cylinder determines the amount of the gravity-counteracting force provided by the first fluid spring. 7. The tool-holding arm of claim 6 , wherein the tool-holding arm further includes the locking mechanism, and wherein the locking mechanism is a valve, the valve being configured to control a flow of the fluid within the fluid conduit. 8. The tool-holding arm of claim 4 wherein: the valve includes a stem and a seat; when the stem contacts the seat, the valve is in a closed position in which the valve prevents the fluid from flowing into and out of the first fluid spring; and when the stem does not contact the seat, the valve is in a fully or partially open position in which the valve does not prevent the fluid from flowing into and out of the first fluid spring. 9. The tool-holding arm of claim 6 , further comprising a second fluid spring configured to provide the gravity-counteracting force to the tool-holding arm, wherein: the second fluid spring includes a third rod, a third plunger and a third cylinder; the fluid conduit is further configured to transfer the fluid between the second cylinder and the third cylinder; and the position of the second plunger within the second cylinder determines the amount of the gravity-counteracting force provided by the second fluid spring. 10. The tool-holding arm of claim 6 , wherein the adjustment mechanism further includes a motor configured to control the position of the second plunger within the second cylinder. 11. The tool-holding arm of claim 6 , further comprising a valve configured to control a flow of the fluid within the fluid conduit. 12. The tool-holding arm of claim 2 , further comprising a tensioning spring, wherein the first fluid spring is located within the tensioning spring. 13. An exoskeleton comprising: a hip structure; a thigh link coupled to the hip structure at a hip joint; a shank link coupled to the thigh link at a knee joint; a foot structure coupled to the shank link at an ankle joint, wherein, when the exoskeleton is supported on a support surface, a weight of the exoskeleton is transferred from the hip structure to the support surface through the thigh link, shank link and foot structure; an electronic control system; and a tool holding arm, wherein the tool holding arm includes: a plurality of links; a tool coupling configured to removably secure a tool to the tool-holding arm; a first fluid spring configured to provide a gravity-counteracting force to the tool-holding arm; and at least one of: a) a locking mechanism configured to lock the first fluid spring; and b) an adjustment mechanism configured to adjust an amount of the gravity-counteracting force provided by the first fluid spring, wherein the electronic control system of the exoskeleton is configured to control the at least one of the locking mechanism and the adjustment mechanism. 14. The exoskeleton of claim 13 , wherein the tool-holding arm includes the locking mechanism. 15. The exoskeleton of claim 13 , wherein the tool-holding arm includes the adjustment mechanism and: the exoskeleton further includes a rear structure; when the exoskeleton is worn by a user, the rear structure is located behind the user; and the adjustment mechanism is coupled to the rear structure. 16. The exoskeleton of claim 13 , wherein the tool-holding arm includes both the locking mechanism and the adjustment mechanism, with the electronic control system configured to control both the locking mechanism and the adjustment mechanism. 17. A method of controlling a tool-holding arm incorporated into an exoskeleton including hip structure, a thigh link coupled to the hip structure at a hip joint, a shank link coupled to the thigh link at a knee joint, foot structure coupled to the shank link at an ankle joint and an electronic control system for selectively moving the exoskeleton, said tool-holding arm including a plurality of links, a tool coupling configured to removably secure a tool to the tool-holding arm and a first fluid spring configured to provide a gravity-counteracting force to the tool-holding arm, said method comprising at least one of: a) locking the first fluid spring with a locking mechanism of the tool-holding arm; and b) adjusting an amount of the gravity-counteracting force being provided by the first fluid spring through an adjustment mechanism of the tool-holding arm, and wherein the method further comprises: controlling the at least one of the locking mechanism and the adjustment mechanism through the electronic control system of the exoskeleton. 18. The method of claim 17 , wherein the first fluid spring is a hydraulic or pneumatic spring including a first rod, a first plunger and a first cylinder and the method further comprises: altering a flow of a fluid into and out of the first cylinder in locking the first fluid spring. 19. The method of claim 17 , wherein the first fluid spring is a hydraulic or pneumatic spring including a first rod, a first plunger and a first cylinder, the tool-holding arm includes a second rod, a second plunger and a second cylinder, and the method further comprises: altering a flow of a fluid between the second cylinder and the first cylinder in adjusting the amount of gravity-counteracting force provided by the first fluid spring. 20. The method of claim 17 , wherein both the locking mechanism and the adjustment mechanism are controlled through the electronic control system of the exoskeleton.