Claims
- 1. A drive arrangement for exerting a bidirectional substantially axial force between first and second structures, the drive arrangement comprising:
a screw drive arrangement including an internally threaded nut and an externally threaded screw shaft, the externally threaded screw shaft having a longitudinal axis and being threadedly engaged with the internally threaded nut; a first coupling connected to the externally threaded screw shaft and configured to connect the externally threaded screw shaft and one of the first and second structures; a second coupling connected to the internally threaded nut and configured to connect the internally threaded nut and the other of the first and second structures, a selected one of said first and second couplings being configured to accommodate transaxial displacement of the screw drive arrangement; and a rotatory drive arrangement for applying a torque to the screw drive arrangement for effecting rotatory displacement between the internally threaded nut and the externally threaded screw shaft, the magnitude of the bidirectional substantially axial force being responsive to the magnitude of the torque applied by the rotatory drive arrangement, and the direction of the bidirectional substantially axial force being responsive to the direction of the torque applied by the rotatory drive arrangement, wherein transaxial loading of the screw drive arrangement is accommodated by the selected one of the first and second couplings.
- 2. The drive arrangement of claim 1 wherein said screw drive arrangement is a ballscrew arrangement, and there is further provided a plurality of recirculating load bearing balls arranged in sequence and interposed between the internally threaded nut and the externally threaded screw shaft.
- 3. The drive arrangement of claim 2, wherein said plurality of recirculating load bearing balls are arranged in plural recirculating load bearing ball circuits.
- 4. The drive arrangement of claim 2, wherein there is further provided a plurality of recirculating spacer balls in the sequence of recirculating load bearing balls for reducing scuffing friction between the recirculating load bearing balls.
- 5. The drive arrangement of claim 4, wherein said plurality of recirculating spacer balls are each dimensioned smaller than each of said plurality of recirculating load bearing balls.
- 6. The drive arrangement of claim 1 wherein the selected one of said first and second couplings is configured to accommodate two degrees of transaxial freedom of displacement with respect to the longitudinal axis.
- 7. The drive arrangement of claim 6, wherein the selected one of said first and second couplings comprises a gimbal.
- 8. The drive arrangement of claim 6, wherein the selected one of said first and second couplings comprises a spherical roller thrust bearing arrangement.
- 9. The drive arrangement of claim 8, wherein said spherical roller thrust bearing arrangement comprises upper and lower bearing arrangements, and there is further provided a rotatory power coupling affixed to a selected one of the internally threaded nut and the externally threaded screw shaft for receiving rotatory energy from said rotatory drive arrangement, said rotatory power coupling being axially interposed between said upper and lower bearing arrangement.
- 10. The drive arrangement of claim 9, wherein said rotatory power coupling comprises a toothed element for engaging a correspondingly configured flexible drive member that engages said rotatory drive arrangement and transmits the rotatory energy to said toothed element.
- 11. The drive arrangement of claim 1, wherein each of said first and second couplings is configured to accommodate transaxial displacement with respect to the longitudinal axis of the screw drive arrangement.
- 12. The drive arrangement of claim 11 wherein each of said first and second couplings comprises a gimbal.
- 13. The drive arrangement of claim 12, wherein the first and second structures are a stationary member and a translatable platen of a press, respectively, said first coupling being arranged to connect the externally threaded screw shaft to a one of the stationary member and the translatable platen of the press, and the second coupling is arranged to couple the internally threaded nut to the other of the stationary member and the translatable platen of the press.
- 14. The drive arrangement of claim 1, wherein said first coupling is arranged to connect the externally threaded screw shaft to said rotatory drive arrangement.
- 15. The drive arrangement of claim 1, wherein said second coupling is arranged to connect the internally threaded nut to said rotatory drive arrangement.
- 16. A drive arrangement for exerting a bidirectional substantially axial force between first and second structures that are vertically movable with respect to each other, the drive arrangement comprising:
a screw drive arrangement including an internally threaded nut and an externally threaded screw shaft, the externally threaded screw shaft having a vertically arranged longitudinal axis and being threadedly engaged with the internally threaded nut; a first coupling connected to the externally threaded screw shaft and configured to connect the externally threaded screw shaft and the first structure, the first structure being fixed in a superior location to the second structure; a second coupling connected to the internally threaded nut and configured to connect the internally threaded nut and the second structure at a predetermined location of the second structure, the second structure having an imbalance about the predetermined location, a selected one of said first and second couplings being configured to accommodate transaxial displacement of the screw drive arrangement; and a rotatory drive arrangement for applying a torque to the screw drive arrangement for effecting rotatory displacement between the internally threaded nut and the externally threaded screw shaft, the magnitude of the bidirectional substantially axial force being responsive to the magnitude of the torque applied by the rotatory drive arrangement, and the direction of the bidirectional substantially axial force being responsive to the direction of the torque applied by the rotatory drive arrangement, wherein transaxial loading of the screw drive arrangement resulting from the imbalance of the second structure is accommodated by the selected one of the first and second couplings configured to accommodate transaxial displacement of the screw drive arrangement.
- 17. The drive arrangement of claim 16, wherein there is further provided a working die installed on the second structure, said working die being asymmetrically arranged about the predetermined location of the second structure where said second coupling is connected so as to cause an imbalance.
- 18. The drive arrangement of claim 17, wherein said second coupling is the selected one of said first and second couplings being configured to accommodate transaxial displacement of the screw drive arrangement.
- 19. The drive arrangement of claim 18, wherein the selected one of said first and second couplings is configured to accommodate a transaxial displacement of the screw drive arrangement of up to 10 degrees.
- 20. The drive arrangement of claim 18, wherein the accommodation of transaxial displacement limits transaxial loading of the screw drive arrangement to less than approximately ten percent (10%) of the axial load.
- 21. The drive arrangement of claim 20, wherein the accommodated transaxial displacement is less than 3 degrees.
- 22. The drive arrangement of claim 18, wherein said first coupling is configured to accommodate transaxial displacement of the screw drive arrangement.
- 23. The drive arrangement of claim 16, wherein there is further provided a guide arrangement for guiding the second structure along a predetermined path in response to the torque applied by said rotatory drive arrangement.
- 24. The drive arrangement of claim 23, wherein said guide arrangement comprises:
a vertical guide post; and a guide bushing engaged with said vertical post, said guide bushing being coupled to said second structure.
- 25. The drive arrangement of claim 24, wherein said second structure comprises a movable platen of a press.
- 26. The drive arrangement of claim 25, wherein the press is a hemming press for stamping and hemming sheet metal components for vehicles, and the movable platen experiences an operating load of approximately between 25,000 lbf. and 50,000 lbf. in tension and approximately 220,000 lbf. in compression.
- 27. The drive arrangement of claim 26, wherein the operating load is applied over a service life of approximately 8.6 million cycles.
- 28. The drive arrangement of claim 27, wherein said screw drive arrangement is a ballscrew arrangement, and there is further provided a plurality of load bearing balls interposed between the internally threaded nut and the externally threaded screw shaft.
- 29. The drive arrangement of claim 28, wherein the plurality of load bearing balls interposed between the internally threaded nut and the externally threaded screw shaft are dimensioned within a tolerance of approximately 25 millionths of an inch.
- 30. The drive arrangement of claim 29, wherein the plurality of load bearing balls comprises 360 load bearing balls arranged in three ball circuits, each circuit having approximately 5 active turns.
- 31. The drive arrangement of claim 29, wherein the externally threaded screw shaft is hardened to approximately between 56 to 60 on the Rockwell hardness scale.
- 32. The drive arrangement of claim 28, wherein the screw shaft is dimensionally characterized by:
an outside diameter of approximately 6 in.; and a pitch lead of approximately 0.9845 in.
- 33. The drive arrangement of claim 28, wherein said screw drive arrangement is a free fall ballscrew arrangement with zero pre-load.
- 34. The drive arrangement of claim 25, wherein there is further provided an energy absorbing element for absorbing energy resulting from a crash load of the movable platen.
- 35. The drive arrangement of claim 34, wherein said energy absorbing element comprises a resilient element having a predetermined resilience characteristic responsive to the application of an axial load.
- 36. The drive arrangement of claim 35, wherein said resilient element comprises a wedge-shaped resilient element that converts axial deformation responsive to the application of the axial load into radial resilient deformation.
- 37. A drive arrangement for a platen of an automotive body panel stamping press, the drive arrangement comprising:
a ballscrew apparatus including an internally threaded nut and an externally threaded screw shaft threadedly engaging the internally threaded nut and there is further provided a plurality of recirculating load bearing balls arranged in sequence and interposed between the internally threaded nut and the externally threaded screw shaft, the load bearing balls being arranged in a plurality of recirculating load bearing ball circuits; a first coupling connected to the externally threaded screw shaft for connecting the externally threaded screw shaft to a stationary member of the press; a second coupling connected to the internally threaded nut for connecting the internally threaded nut to the platen of the press; and a rotatory drive arrangement connected to the externally threaded screw shaft and configured to rotate the externally threaded screw shaft relative to the internally threaded nut and thereby impart a substantially axial reciprocal motion between the movable platen and the stationary member of the press, at least one of said first and second couplings being arranged to accommodate transaxial loading of said ballscrew apparatus during the substantially axial reciprocal motion between the movable platen and the stationary member of the press.
- 38. The drive arrangement of claim 37, wherein the substantially axial reciprocal motion between the movable platen and the stationary member of the press is oriented vertically, and said ballscrew apparatus is a free fall ballscrew arrangement with zero pre-load.
- 39. The drive arrangement of claim 38, wherein said first coupling comprises a gimbal that is arranged to provided two degrees of transaxial freedom to said externally threaded screw shaft relative to the substantially axial reciprocal motion between the movable platen and the stationary member of the press.
- 40. The drive arrangement of claim 39, wherein the accommodation of transaxial displacement limits transaxial loading of the screw drive arrangement to less than approximately ten percent (10%) of the axial load.
- 41. The drive arrangement of claim 39, wherein the accommodated transaxial displacement is less than 3 degrees.
- 42. The drive arrangement of claim 39, wherein the screw shaft is dimensionally characterized by:
an outside diameter of approximately 6 in.; and a pitch lead of approximately 0.9845 in.
- 43. The drive arrangement of claim 38, wherein said second coupling comprises a gimbal that is arranged to provided two degrees of transaxial freedom to said internally threaded nut relative to the substantially axial reciprocal motion between the movable platen and the stationary member of the press.
- 44. The drive arrangement of claim 38, wherein said first coupling comprises a spherical roller thrust bearing arrangement that is arranged to provided two degrees of transaxial freedom to said externally threaded screw shaft relative to the substantially axial reciprocal motion between the movable platen and the stationary member of the press.
- 45. The drive arrangement of claim 44, wherein said spherical roller thrust bearing arrangement comprises upper and lower bearing arrangements, and there is further provided a rotatory power coupling affixed to said externally threaded screw shaft for receiving rotatory energy from said rotatory drive arrangement, said rotatory power coupling being axially interposed between said upper and lower bearing arrangement.
- 46. The drive arrangement of claim 38, wherein said first coupling comprises a partially spherical end portion of said externally threaded screw shaft.
- 47. The drive arrangement of claim 46, wherein said partially spherical end portion of said externally threaded screw shaft is internally partially spherical.
- 48. The drive arrangement of claim 38, wherein there is further provided a plurality of recirculating spacer balls in the sequences of recirculating load bearing balls in the plural recirculating load bearing ball circuits for reducing scuffing friction between the recirculating load bearing balls.
- 49. The drive arrangement of claim 37, wherein the plurality of load bearing balls comprises approximately 360 load bearing balls arranged in three ball circuits, each circuit having approximately 5 active turns.
- 50. The drive arrangement of claim 37, wherein the plurality of recirculating load bearing balls interposed between the internally threaded nut and the externally threaded screw shaft are dimensioned within a tolerance of approximately 25 millionths of an inch.
- 51. The drive arrangement of claim 50, wherein the externally threaded screw shaft is hardened to approximately between 56 to 60 on the Rockwell hardness scale.
- 52. A mechanical press drive for advancing and retracting a movable platen of a press, the press drive comprising:
a ballscrew apparatus including a nut and a screw threadedly engaging the nut; a first coupling connected to the screw and configured to connect the screw and one of a movable platen of a press or a stationary member of the press; a second coupling connected to the nut and configured to connect the nut and the other of the platen and the stationary member of the press; and a drive motor operably connected to one of the nut and screw and configured to relatively rotate the nut and screw to impart reciprocal motion to the movable platen, and the two couplings being configured to cooperatively isolate the ballscrew apparatus from offset and moment loading that may occur during press operation.
- 53. The mechanical press drive as defined in claim 52, in which:
the first coupling is configured to couple the screw to an output of the motor; the second coupling is configured to couple the nut to the movable upper platen of the press; and the drive motor is configured to be supported on a stationary member of the press and to rotate the screw to impart reciprocal motion of the movable platen of a the press.
- 54. A mechanical press drive as defined in claim 52, in which the ballscrew apparatus is configured to suspend a vertically movable upper platen from a stationary crown.
- 55. A mechanical press drive as defined in claim 52, in which at least one of the couplings comprises a gimbal.
- 56. A mechanical press drive as defined in claim 53, in which the second coupling comprises a lower gimbal comprising: an inner trunnion pivotally coupled to the nut; an outer trunnion pivotally coupled to the inner trunnion; and a lower mount coupled to the outer trunnion and configured to connect to an upper platen of the press.
- 57. A mechanical press drive as defined in claim 53, in which the first coupling comprises a driveshaft coupled to the output of the motor and an upper gimbal comprising: an inner trunnion pivotally coupled to the nut; an outer trunnion pivotally coupled to the inner trunnion; and an upper mount coupling the outer trunnion to the driveshaft.
- 58. A mechanical press drive as defined in claim 57 in which the first coupling comprises a thrust shaft connected at an upper end to a lower end of the driveshaft and connected at a lower end to the upper mount; and a thrust bearing configured to rotatably support the thrust shaft on the crown of a press while isolating the gearbox from compressive forces generated by the ballscrew apparatus.
- 59. A mechanical press drive as defined in claim 52 in which the motor output is coupled to a gearbox, an output of the gearbox is coupled to a drive shaft; and the drive shaft is coupled to the screw.
RELATIONSHIP TO OTHER APPLICATION
[0001] This application claims the benefit of Provisional Patent Application Serial No. 60/400,146, filed Aug. 1, 2002.
Provisional Applications (1)
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Number |
Date |
Country |
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60400146 |
Aug 2002 |
US |