IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0787651
(1999-09-24)
|
우선권정보 |
DE-0023809 (1998-09-30) |
국제출원번호 |
PCT//EP99/07111
(2001-06-28)
|
§371/§102 date |
20010628
(20010628)
|
국제공개번호 |
WO00//19104
(2000-04-06)
|
발명자
/ 주소 |
|
출원인 / 주소 |
- Luk, Automobitechnik GmbH
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
6 인용 특허 :
12 |
초록
A vacuum pump, in particular for brake booster systems in motor vehicles, with a drivable rotor via which a blade in a housing can be set in rotation is proposed. The vacuum pump is distinguished by the fact that the rotor consists of plastic and is formed as one piece.
대표청구항
▼
1. A vacuum pump comprising:a drivable rotor having a blade in a housing which can be set in rotation, the rotor being comprising plastic and being formed as one piece, the rotor comprising a first longitudinal section configured for being coupled to a drive shaft via which a torque can be transmitt
1. A vacuum pump comprising:a drivable rotor having a blade in a housing which can be set in rotation, the rotor being comprising plastic and being formed as one piece, the rotor comprising a first longitudinal section configured for being coupled to a drive shaft via which a torque can be transmitted from a drive shaft to the rotor and that the first longitudinal section being formed as one piece with the rotor and wherein the rotor comprises first and second support sections, characterized in that the rotor comprises a second longitudinal section and a third longitudinal section and the second and the third longitudinal sections being formed as one piece with the rotor and the rotor has one slot for the receipt of one blade, said one slot being disposed in the third longitudinal section.2. A vacuum pump according to claim 1, wherein the rotor has at least one cavity open at the edge.3. A vacuum pump according to claim 2, wherein the cavity is introduced from a position consisting of the group consisting of the drive-side frontal side of the rotor and the frontal face of the rotor turned away from the drive.4. A vacuum pump according to claim 1, wherein the rotor comprises walls having a slight thickness.5. A vacuum pump according to claim 1, wherein the rotor comprises two wall areas and a transition between the two wall areas of the rotor having a different thickness, the which is continuous.6. A vacuum pump according to claim 1, wherein the slot has a diameter is smaller than the rotor diameter in the area of the slot in which the blade is displaceable.7. A vacuum pump according to claim 1, wherein the rotor has a diameter and a slot and wherein the rotor has at least one support whose diameter is the same as the rotor diameter in the area of the slot in which the blade is displaceable.8. A vacuum pump according to claim 1, wherein the rotor has a slot and two supports and wherein a diameter of at least one of the supports is smaller than the rotor diameter in the area of the slot.9. A vacuum pump according to claim 1, wherein the rotor has at least two cavities disposed next to one another which are separated from one another by a rib.10. A vacuum pump according to claim 9, wherein the rotor has wall areas and wherein the rib is thinner than the rest of the wall areas of the rotor.11. A vacuum pump according to claim 1, further comprising a coupling formed by a disk and wherein the rotor can be energized with a torque via the coupling.12. A vacuum pump according to claim 11, wherein the disk has a thickness and a diameter, and wherein the ratio of the thickness (b) and the diameter (d) of the disk lies in a range of 0.14?b/d?0.3.13. A vacuum pump according to claim 1, wherein the rotor has a drive segment having a support length (l) and the rotor having a diameter and wherein the diameter (D) of the rotor lies in a range of 0.35?l/D?0.65.14. A vacuum pump according to claim 1, further comprising at least two drive segments which are connected to one another by a closed ring.15. A vacuum pump according to claim 1, further comprising a coupling having a drive mechanism selected from the group consisting of a long hole in which a drive shaft engages and a drive tongue which engages in a corresponding slot in a drive shaft.16. A vacuum pump according to claim 15, wherein the drive tongue has a double surface formed by a first longitudinal section of the rotor which is provided with a vat-like cap preferably consisting of sheet metal.17. A vacuum pump according to claim 1, wherein the rotor has an elastic drive element working together with a drive shaft.18. A vacuum pump according to claim 1, further comprising a drive element.19. A vacuum pump according to claim 18 wherein the drive element is spring steel.20. A vacuum pump according to claim 18, wherein drive element projects into a slot in a drive shaft and is displaceably guided in it.21. A vacuum pump according to claim 20, wherein the drive element engages in a slot-like recess in the rotor.22. A vacuum pump according to claim 18, wherein the drive element is held undisplaceably in the recess.23. A vacuum pump according 18, wherein the drive element is embedded in the rotor.24. A vacuum pump according to claim 18, of the preceding claims characterized by the fact that the drive element is formed in the shape of a U.25. A vacuum pump according claim 18, wherein the rotor comprises at least one stop surface during the energizing of the drive element with a torque.26. A vacuum pump according to claim 25, wherein the drive element is formed as a ball in a bearing area of the rotor.27. A vacuum pump according to claim 18, wherein the rotor has at least on stop for the drive element.28. A vacuum pump according to claim 18, wherein the drive element is angled off at an end engaging a recess in the rotor.29. A vacuum pump according to claim 1, wherein the rotor is disposed in communication with a motor.30. A vacuum pump according to claim 1, wherein the rotor has a first longitudinal section which can be coupled to a drive shaft via which a torque can be transmitted from the drive shaft to the rotor and that the first longitudinal section is formed as one piece with the rotor.31. A vacuum pump according to claim 1, further comprisinga coupling having a bearing surface; andan opposing surface disposed at the rotor for each bearing surface of the coupling where a torque transmitted from a drive shaft can be conducted into the rotor via the opposing surface.32. A vacuum pump according to claim 31, wherein the rotor has at least one cavity open at the edge.33. A vacuum pump according to claim 32, wherein the cavity is introduced from a position consisting of the group consisting of the drive-side frontal side of the rotor and the frontal face of the rotor turned away from the drive.34. A vacuum pump according to claim 31 characterized by the fact that the opposing surface is located on a drive segment projecting over the drive-side frontal surface of the rotor (1).35. A vacuum pump according to claim 31, wherein the rotor has walls having a slight thickness.36. A vacuum pump according to claim 31, wherein the rotor comprising two wall areas and a transition between the two wall areas of the rotor having a different thickness which is continuous.37. A vacuum pump according to claim 31, wherein the rotor has a slot and at least one support having a diameter is smaller than the rotor diameter in the area of the slot in which the bade is displaceable.38. A vacuum pump according to claim 31, wherein the rotor has a diameter and a slot and wherein the rotor has at least one support whose diameter is the same size as the rotor diameter in the area of the slot in which the blade is displaceable.39. A vacuum pump according to claim 31, wherein the rotor has a slot and two supports and wherein a diameter of at least one of the supports is smaller than the rotor diameter in the area of the slot.40. A vacuum pump according to claim 31, wherein the rotor has at least two cavities disposed next to one another which are separated from one another by a rib.41. A vacuum pump according to claim 40, wherein the rotor has wall areas and wherein the rib is thinner than the rest of the wall areas of the rotor.42. A vacuum pump according to claim 31, further comprising a coupling formed by a disk and wherein the rotor can be energized with a torque via the coupling.43. A vacuum pump according to claim 42, wherein the disk has a thickness and a diameter, and wherein the ratio of the thickness (b) and the diameter (d) of the disk lies in a range of 0.14?b/d?0.3.44. A vacuum pump according to claim 31, wherein the disk has a drive segment having a support length (l) and the rotor having a diameter and wherein the diameter (D) of the rotor lies in a range of 0.35?l/D?0.65.45. A vacuum pump according to claim 31, further comprising at least two drive segments which are connected to one another by a closed ring.46. Vacuum pump according to claim 31, further comprising a coupling having a drive mechanism selected from the group consisting of a long hole in which the drive shaft engages and a drive tongue which engages in a corresponding slot in a drive shaft.47. A vacuum pump according to claim 46, wherein the drive tongue has a double surface formed by a first longitudinal section of the rotor which is provided with a vat-like cap preferably consisting of sheet metal.48. A vacuum pump according to claim 31, wherein the rotor has an elastic drive element working together with a drive shaft.49. A vacuum pump according to claim 31, further comprising a drive element.50. A vacuum pump according to claim 49, wherein the drive element projects into a slot in a drive shaft and is displaceably guided in it.51. A vacuum pump according to claim 50, wherein the drive element engages in a slot-like recess in the rotor.52. A vacuum pump according to claim 49, wherein the drive element is held undisplaceably in the recess.53. A vacuum pump according 49, wherein the drive element is embedded in the rotor.54. A vacuum pump according to claim 49, wherein the drive element is formed in the shape of a U.55. A vacuum pump according claim 49, wherein the rotor comprises at least one stop surface during the energizing of the drive element with a torque.56. A vacuum pump according to claim 55, wherein the drive element is formed as a ball in a bearing area of the rotor.57. A vacuum pump according to claim 49, wherein the rotor has at least one stop for the drive element.58. A vacuum pump according to claim 49, wherein the drive element is angled off at an end engaging a recess in the rotor.59. Vacuum pump according to claim 31, wherein the rotor is disposed in communication with a motor.60. A vacuum pump according to claim 31, wherein the rotor has a first longitudinal section which can be coupled to a drive shaft via which a torque can be transmitted from the drive shaft to the rotor and that the first longitudinal section is formed as one piece with the rotor.61. A vacuum pump according to claim 1, wherein the rotor has at least two cavities which are each introduced from a frontal side of the rotor and that the rotor has at least one closed wall running transversely or essentially transversely to the central longitudinal axis of the rotor, said wall separating the cavities from one another in the axial direction.62. A vacuum pump according to claim 61, wherein the cavities extend in the axial direction into the central area of the rotor.63. A vacuum pump according to claim 61, wherein the rotor has walls have a slight thickness.64. A vacuum pump according to claim 61, wherein the rotor comprises two wall areas and a transition between the two wall areas of the rotor having a different thickness which is continuous.65. A vacuum pump according to claim 61, wherein the rotor has a slot and at least one support having a diameter is smaller than the rotor diameter in the area of the slot in which the blade is displaceable.66. A vacuum pump according to claim 61, wherein the rotor has a diameter and a slot and wherein the rotor has at least one support whose diameter is the same size as the rotor diameter in the area of the slot in which the blade is displaceable.67. A vacuum pump according to claim 61, wherein the rotor has a slot and two supports and wherein a diameter of at least one of the supports is smaller than the rotor diameter in the area of the slot.68. A vacuum pump according to claim 61, wherein the rotor has at least two cavities disposed next to one another which are separated from one another by a rib.69. A vacuum pump according to claim 68, wherein the rotor has wall areas and wherein the rib is thinner than the rest of the wall areas of the rotor.70. A vacuum pump according to claim 61, further comprising a coupling formed by a disk and wherein the rotor (1) can be energized with a torque via the coupling.71. A vacuum pump according to claim 70, wherein the disk has a thickness and a diameter, and wherein the ratio of the thickness (b) and the diameter (d) of the disk lies in a range of 0.14?b/d?0.3.72. A vacuum pump according to claim 61, wherein the rotor has a drive segment having a support length (l) and the rotor having a diameter and wherein the diameter (D) of the rotor lies in a range of 0.35?l/D?0.65.73. A vacuum pump according to claim 61, further comprising at least two drive segments which are connected to one another by a closed ring.74. A vacuum pump according to claim 61, further comprising a coupling having a drive mechanism selected from the group consisting of a long hole in which the drive shaft engages and a drive tongue which engages in a corresponding slot in a drive shaft.75. A vacuum pump according to claim 73, wherein the drive tongue has a double surface formed by a first longitudinal section of the rotor which is provided with a vat-like cap preferably consisting of sheet metal.76. A vacuum pump according to claim 61, wherein the rotor has an elastic drive element working together with a drive shaft.77. A vacuum pump according to claim 61, further comprising a drive element.78. A vacuum pump according to claim 77, wherein drive element projects into a slot in a drive shaft and is displaceably guided in it.79. A vacuum pump according to claim 77, wherein the drive element engages in a slot-like recess in the rotor.80. A vacuum pump according to claim 77, wherein the drive element is held undisplaceably in the recess.81. A vacuum pump according 77, wherein the drive element is embedded in the rotor.82. A vacuum pump according to claim 77, wherein the drive element is formed in the shape of a U.83. A vacuum pump according to claim 77, wherein the rotor comprises at least one stop surface during the energizing of the drive element with a torque.84. A vacuum pump according to claim 77, wherein the drive element is formed as a ball in a bearing area of the rotor.85. A vacuum pump according to claim 77, wherein the rotor has at least one stop for the drive element.86. A vacuum pump according to claim 77, wherein the drive element is angled off at an end engaging a recess in the rotor.87. Vacuum pump according to claim 61, wherein the rotor is disposed in communication with a motor.88. A vacuum pump according to claim 61, wherein the rotor has a first longitudinal section which can be coupled to a drive shaft via which a torque can be transmitted from the drive shaft of the rotor and that the first longitudinal section is formed as one piece with the rotor.89. A vacuum pump according to claim 61, wherein rotor has a opposing surface and further comprising a coupling having a bearing surface of a coupling where a torque transmitted from the drive shaft can be conducted into the rotor via the opposing surface.90. A vacuum pump according to claim 61, wherein the rotor has at least one cavity open at the edge.91. A vacuum pump according to claim 90, wherein the cavity is introduced from a position selected from the frontal side of the rotor and from its frontal face (5) turned away from the drive.
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