RU2002130513A - STRETCHING DEVICE - Google Patents

Claims (50)

1. A tension device comprising a housing having a housing surface; a wedge having a wedge surface that has sliding engagement with the surface of the body, the wedge furthermore describes a hole; a piston having a first end mutually engaged with the bore; a pivot arm having a pulley mounted on a trunnion at one end, the pivot arm is rotatably attached to the surface and has a second end pressing against the end of the piston opposite the first end; and a compressible element biasing the wedge toward the piston, whereby moving the wedge with respect to the first end causes the wedge to expand radially with respect to the surface of the housing, thereby inhibiting the movement of the piston. 2. The tensioner according to claim 1, in which the wedge hole contains a hole having the shape of a truncated cone; and the first end of the piston comprises a truncated cone shape that is mutually engaged with a truncated cone shaped hole. 3. The tensioner according to claim 2, in which the wedge further comprises at least one groove located so that the circumference of the wedge has the ability to radially expand in response to movement with respect to the first end of the piston. 4. The tensioner according to claim 3, further comprising a regulator pressing the end of the compressible member and the housing, whereby the preload of the compressible member can be changed. 5. The tensioner according to claim 4, in which the outer surface of the wedge also describes a corrugated shape; and the inner surface also describes a corrugated shape that interacts with the corrugated shape of the outer surface of the wedge. 6. The tensioner according to claim 5, in which the housing further comprises a cylinder. 7. The tensioner according to claim 5, in which the surface of the wedge contains non-metallic material. 8. The tensioner according to claim 1, wherein the compressible member comprises a spring. 9. A tensioning device comprising a first housing having a first inner surface; a second housing having a second inner surface and an outer surface, the outer surface has a sliding engagement with the first inner surface; a first compressible member resisting movement between the first housing and the second housing; a piston having a first end and a second end, the first end being attached to the first housing and substantially parallel to the main axis of the first housing; a keyhole describing a central hole and having a surface that is in sliding engagement with a second inner surface, and a hole that is in sliding engagement with a second end; and a second compressible member pushing the locking cup onto the second end, whereby the locking cup expands radially with respect to the second inner surface. 10. The tensioner according to claim 9, in which the Central hole of the keyhole also contains a hole having the shape of a truncated cone; and the second end of the piston further comprises a truncated cone shape that mutually engages with a truncated cone shaped opening. 11. The tensioner of claim 10, wherein the keyhole further comprises at least one groove located so that the circumference of the keyhole is variable in response to movement with respect to the second end of the piston. 12. The tensioner according to claim 11, in which the surface of the keyhole also describes a corrugated shape; and the second inner surface of the second body further describes a corrugated shape that interacts with the corrugated shape of the surface of the keyhole. 13. The tensioner according to claim 12, wherein the first body describes a cylinder; and the second body describes a cylinder. 14. The tensioning device according to item 13, in which the surface of the keyhole contains non-metallic material. 15. The tensioner of claim 14, wherein the second compressible member rests on the first housing. 16. The tensioner of claim 14, wherein the first compressible member comprises a spring; and the second compressible element comprises a spring. 17. The tensioner according to claim 14, further comprising a bearing surface attached to the piston, the bearing surface being perpendicular to the axis of the piston; and the second compressible element rests on the bearing surface. 18. A damping device comprising a housing having a housing surface; a wedge having a surface that has a sliding engagement with the surface of the body, the wedge also describes a hole; a piston having a first end mutually engaged with the bore; and a compressible element biasing the wedge toward the piston, whereby moving the wedge with respect to the first end causes the wedge to expand radially with respect to the surface of the housing, thereby inhibiting the movement of the piston. 19. The damping device according to claim 18, wherein the wedge hole comprises a hole having the shape of a truncated cone; and the first end of the piston comprises a truncated cone shape that is mutually engaged with a truncated cone shaped hole. 20. The damping device according to claim 19, in which the wedge further comprises at least one groove arranged so that the circumference of the wedge has the ability to radially expand in response to movement with respect to the first end of the piston. 21. The damping device according to claim 20, in which the surface of the wedge also describes a corrugated shape; and the surface of the body also describes a corrugated shape that interacts with the corrugated surface shape of the wedge. 22. The damping device according to item 21, in which the housing further comprises a cylinder. 23. The damping device according to item 22, in which the side surface of the wedge contains non-metallic material. 24. The damping device according to item 23, in which the compressible element contains a spring. 25. A damping device comprising a first housing having a first housing surface; a wedge describing the wedge hole and having a wedge surface for sliding engagement with the first surface of the housing; a second housing coaxial to the first housing and having sliding engagement with the first housing; a piston having a first end and a second end, the first end is engaged with the central bore of the wedge, and the second end is attached to the second housing; a first compressible member bringing the wedge into contact with the first end of the piston; a second compressible element, diverting the first housing from the second housing. 26. The damping device according A.25, in which the wedge hole contains a hole having the shape of a truncated cone; and the first end of the piston comprises a truncated cone shape that is mutually engaged with a truncated cone shaped hole. 27. The damping device according to claim 26, wherein the wedge further comprises at least one groove arranged so that the circumference of the wedge has the ability to radially expand in response to movement with respect to the first end of the piston. 28. The damping device according to item 27, in which the outer surface of the wedge in addition describes a corrugated shape; and the first surface of the body also describes a corrugated shape that interacts with the corrugated surface shape of the wedge. 29. A damping device according to claim 28, wherein the first body further comprises a cylinder; and the second body further comprises a cylinder. 30. The damping device according to clause 29, in which at least the surface of the wedge contains non-metallic material. 31. The damping device according to claim 30, wherein the first compressible member comprises a spring; and the second compressible element comprises a spring. 32. A damping device comprising a first housing having a first housing surface; a second housing having a surface of a second housing; a wedge having a wedge surface that is coaxial and has a sliding engagement with the first surface of the housing and has a sliding engagement with the surface of the second housing, the wedge also includes a surface of the wedge hole describing the hole in which the surface of the second housing is engaged; the compressible element biases the wedge towards the first body, as a result of which the movement of the wedge with respect to the first surface of the body causes the wedge to radially contract with respect to the surface of the second body, thereby inhibiting the movements of the first body. 33. The damping device according to p, in which the wedge hole contains a cylindrical hole. 34. The damping device according to claim 33, wherein the wedge further comprises at least one groove oriented so that the circumference of the wedge is able to radially compress in response to movement with respect to the first surface of the housing. 35. A damping device according to claim 34, wherein the wedge hole further describes a corrugated shape; and the surface of the second body further describes a corrugated shape that interacts with the corrugated shape of the wedge hole. 36. A damping device according to claim 35, wherein the first body further comprises a cylinder; and the second body further comprises a cylinder. 37. The damping device according to clause 36, in which the surface of the wedge holes contains non-metallic material. 38. The damping device according to clause 37, in which the compressible element contains a spring. 39. A damping device comprising a first housing having a first housing surface; a piston having a piston surface; a wedge having a wedge surface that is coaxial and has a sliding engagement with the first surface of the housing and has a sliding engagement with the surface of the piston, the wedge also contains a wedge hole surface describing an opening in which the piston surface is engaged; a first compressible element biasing the wedge towards the first housing, whereby moving the wedge with respect to the first surface of the housing radially compresses the wedge with respect to the piston surface, thereby inhibiting the movement of the piston; and a second compressible element biasing the first housing from the piston. 40. The damping device according to § 39, in which the hole contains a cylindrical hole. 41. The damping device according to claim 40, wherein the wedge further comprises at least one groove oriented so that the circumference of the wedge has the ability to radially compress in response to movement with respect to the first surface of the housing. 42. The damping device according to paragraph 41, in which the surface of the wedge hole also describes a corrugated shape; and the piston surface further describes a corrugated shape that interacts with the corrugated shape of the wedge hole. 43. A damping device according to claim 42, wherein the first body further comprises a cylinder. 44. The damping device according to item 43, in which the surface of the wedge holes contains non-metallic material. 45. The damping device according to item 44, in which the first compressible element comprises a spring; and the second compressible element comprises a spring. 46. The damping device according to p, in which the first surface of the housing describes a conical shape having an angle in the range from 0 to 30 °. 47. The damping device according to clause 39, in which the first surface of the housing describes a conical shape having an angle in the range from 0 to 30 °. 48. A damping device comprising a first element having a first surface; a second element having a second surface, the second surface is axially movable relative to the first surface; a friction element having a variable circumference, which is in sliding engagement with the first surface and the second surface; a compressible element that diverts the friction element from the first surface, whereby the circumference of the friction element changes, leading to an increase in frictional contact with the second surface. 49. The damping device according to claim 48, wherein the friction element further comprises at least one groove arranged so that the circumference of the friction element can vary. 50. The damping device according to claim 49, further comprising a second compressible member deflecting the first member from the second member.