Elevation device and robot

What is claimed is: 1. An elevation device comprising: a mounting frame; a rotary actuator fixed to the mounting frame; a shaft connected to the rotary actuator and rotatable with respect to the mounting frame, the shaft defining a helical groove in a lateral surface thereof; a drive bar slidably connected to the mounting frame, the drive bar comprising a post that is movably fit in the helical groove, the mounting frame, the shaft and the drive bar constituting a conversion mechanism that converts rotation of the shaft into linear motion of the drive bar, wherein the drive bar is slidable with respect to the mounting frame along a direction that is parallel to an axis of rotation of the shaft; a connecting member fixed to the drive bar; and a sleeve arranged around the post, wherein the sleeve is rollable in the helical groove. 2. The elevation device of claim 1 , further comprising at least one guiding bar slidably connected to the mounting frame, wherein the at least one guiding bar is parallel to the drive bar, and one end of the at least one guiding bar is fixed to the connecting member. 3. The elevation device of claim 2 , further comprising at least one sliding bearing, wherein the mounting frame defines at least one bearing hole to receive the at least one sliding bearing, and the at least one guiding bar is slidably connected to the mounting frame through the at least one sliding bearing. 4. The elevation device of claim 2 , wherein the at least one guiding bar comprises a limiting block at an end opposite the connecting member, and the limiting block is configured to come into contact with the mounting frame to stop motion of the at least one guiding bar. 5. The elevation device of claim 2 , wherein the at least one guiding bar is two in number. 6. The elevation device of claim 1 , wherein the sleeve comprises a lubricating layer on an outer surface thereof. 7. The elevation device of claim 1 , wherein an unfolding helix angle of the helical groove in an area away from the rotatory actuator and a coefficient of friction between the sleeve and an inner surface of the helical groove satisfy an inequation below: μ>tan(β), where μ represents the coefficient of friction between the sleeve and the inner surface of the helical groove, and β represents unfolding helix angle of the helical groove in an area away from the rotatory actuator. 8. The elevation device of claim 1 , further comprising an axle fixed to the mounting frame and at least one rotating bearing, wherein the shaft is hollow and defines a receiving hole, the at least one rotating bearing is fit in the receiving hole, the axle passes through the at least one rotating bearing and partly extends into the receiving hole, the shaft is rotatably connected to the mounting frame by engagement of the axle with the at least one rotating bearing. 9. The elevation device of claim 8 , wherein a protruding ring protrudes from an inner surface of the receiving hole, and one of the at least one rotating bearing rests on the protruding ring. 10. The elevation device of claim 8 , further comprising a spacing sleeve arranged around the axle and received in the receiving hole, wherein the at least one rotating bearing is two in number, and the spacing sleeve is arranged between and abuts against the two rotating bearings. 11. The elevation device of claim 1 , further comprising a sliding bearing, wherein the mounting frame defines a bearing hole to receive the sliding bearing, and the drive bar is slidably connected to the mounting frame through the sliding bearing. 12. The elevation device of claim 1 , wherein the mounting frame comprises a base plate and an end plate protruding from an end of the base plate, wherein the rotary actuator is fixed to the base plate, and the drive bar passes through the end plate. 13. The elevation device of claim 1 , wherein the connecting member defines a plurality of connecting holes. 14. A robot comprises: an elevation device comprising: a mounting frame; a rotary actuator fixed to the mounting frame; a shaft connected to the rotary actuator and rotatable with respect to the mounting frame, the shaft defines a helical groove in a lateral surface thereof; a drive bar slidably connected to the mounting frame, the drive bar comprising a post that is movably fit in the helical groove, the mounting frame, the shaft and the drive bar constating a conversion mechanism that converts rotation of the shaft into linear motion of the drive bar, wherein the drive bar is slidable with respect to the mounting frame along a direction that is parallel to an axis of rotation of the shaft; a connecting member fixed to the drive bar; and a sleeve arranged around the post, wherein the sleeve is rollable in the helical groove. 15. The robot of claim 14 , further comprising at least one guiding bar slidably connected to the mounting frame, wherein the at least one guiding bar is parallel to the drive bar, and one end of the at least one guiding bar is fixed to the connecting member. 16. The robot of claim 15 , further comprising at least one sliding bearing, wherein the mounting frame defines at least one bearing hole to receive the at least one sliding bearing, and the at least one guiding bar is slidably connected to the mounting frame through the at least one sliding bearing. 17. The robot of claim 15 , wherein the at least one guiding bar comprises a limiting block at an end opposite the connecting member, and the limiting block is configured to come into contact with the mounting frame to stop motion of the at least one guiding bar. 18. The robot of claim 14 , wherein an unfolding helix angle of the helical groove in an area away from the rotatory actuator and a coefficient of friction between the sleeve and an inner surface of the helical groove satisfy an inequation below: μ>tan(β), where μ represents the coefficient of friction between the sleeve and the inner surface of the helical groove, and β represents unfolding helix angle of the helical groove in an area away from the rotatory actuator.