Bayonet spacer retention system for variable turbine geometry vane packs
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F01D-017/16
F02B-037/24
F02B-039/00
출원번호
US-0397969
(2013-04-22)
등록번호
US-9856744
(2018-01-02)
국제출원번호
PCT/US2013/037561
(2013-04-22)
국제공개번호
WO2013/165723
(2013-11-07)
발명자
/ 주소
Heddy, III, George E.
출원인 / 주소
BorgWarner Inc.
대리인 / 주소
BrooksGroup
인용정보
피인용 횟수 :
0인용 특허 :
13
초록▼
A variable geometry turbocharger includes a vane pack having rotatable vanes constrained by a pair of vane rings connected by a plurality of spacer connectors. The spacer connectors can include a spacer body for maintaining a minimum spacing between the vane rings. The spacer connectors are configur
A variable geometry turbocharger includes a vane pack having rotatable vanes constrained by a pair of vane rings connected by a plurality of spacer connectors. The spacer connectors can include a spacer body for maintaining a minimum spacing between the vane rings. The spacer connectors are configured for bayonet mounting to at least one of the vane rings. To that end, the spacer connectors can include shaft portions extending from opposing sides of the spacer body. A plurality of transverse protrusions can extend outwardly from each shaft portion. Each shaft portion can be received in a respective in a vane ring. The spacer connectors can be rotated such that the transverse protrusions are offset from aperture portions that allow passage of the transverse portions, thereby retaining the vane rings in place in spaced relation. Such a system avoids close tolerances, press fits, expensive bolted joints or weld processes.
대표청구항▼
1. A vane pack (90) for a variable geometry turbocharger comprising: a first vane ring (92);a second vane ring (94);a plurality of spacer connectors (50) connecting the first and second vane rings (92, 94) and maintaining a distance therebetween, the spacer connectors (50) being configured for bayon
1. A vane pack (90) for a variable geometry turbocharger comprising: a first vane ring (92);a second vane ring (94);a plurality of spacer connectors (50) connecting the first and second vane rings (92, 94) and maintaining a distance therebetween, the spacer connectors (50) being configured for bayonet mounting to at least one of the first vane ring (92) and second vane ring (94);wherein the spacer connectors (50) include a spacer body (52) having opposing end faces (58, 60), a first shaft portion (54) extending from one of the end faces (60) of the spacer body (52) to a distal end (68), and wherein a plurality of transverse projections (78) extend from an outer peripheral surface (74) of the first shaft portion (54) for bayonet mounting to the first vane ring (92), and wherein the transverse projections (78) are at substantially 45 degrees relative to a radial direction of the first vane ring (92) and at substantially 90 degrees relative to the aperture portions (107) configured to receive the transverse projections (78);wherein the first vane ring (92) includes a plurality of first apertures (104) having portions (107) configured to receive the transverse projections (78), each first shaft portion (54) being received in a respective one of the first apertures (104) and rotated so that the transverse projections (78) are offset from the portions (107) of the first apertures (104), whereby each first shaft portion (54) is prevented from being withdrawn from the respective first aperture (104); andwherein the aperture portions (107) configured to receive the transverse projections (78) are at substantially 45 degrees relative to a radial direction of the first vane ring (92). 2. The vane pack of claim 1, wherein the spacer body (52) and the first shaft portion (54) are formed as a unitary structure. 3. The vane pack of claim 1, wherein the plurality of first apertures (104) include a counterbore (108), and wherein the distal end (68) of the respective first shaft portions (54) is received in the counterbore (108) such that the distal end (68) is substantially flush with or recessed from an outer surface (96) of the first vane ring (92). 4. The vane pack of claim 1, wherein the spacer connectors (50) include a second shaft portion (56) extending from an opposite one of the end faces (58) of the spacer body (52) to a distal end (72), wherein a plurality of transverse projections (78) extend from an outer peripheral surface (76) of the second shaft portion (56) of the spacer connectors (50) for bayonet mounting to the second vane ring (94), wherein the second vane ring (94) includes a plurality of second apertures (106) having portions (107) configured to receive the transverse projections (78) of the second shaft portion (56), and wherein each second shaft portion (56) is received in a respective one of the second apertures (106) in the second vane ring (94) and rotated so that the transverse projections (78) of each second shaft portion (56) are offset from the portions (107) of the respective second aperture (106), whereby each second shaft portion (56) is prevented from being withdrawn from the respective second aperture (106). 5. The vane pack of claim 1, wherein the first shaft portion (54) of each spacer connector (50) includes a region (84) including a substantially flat surface (86). 6. The vane pack of claim 5, further including a plurality of pins (116), wherein each pin (116) is received in a respective one of a plurality of apertures (114) formed in the first vane rings (92) such that an end (118) of the pin (116) engages the substantially flat surface (86), whereby rotation of the spacer connector (50) is prevented. 7. A retention method for the vane pack (90) of a variable geometry turbocharger comprising: providing a first vane ring (92);providing a second vane ring (94);providing a plurality of spacer connectors (50);connecting each spacer connector (50) to the first and second vane rings (92, 94) such that the vane rings (92, 94) are maintained in spaced relation to each other and such that each spacer connector (50) is bayonet mounted to at least one of the first vane ring (92) and the second vane ring (94);wherein the spacer connectors (50) include a spacer body (52) having opposing end faces (58, 60), a first shaft portion (54) extending from one of the end faces (60) of the spacer body (52) to a distal end (68), wherein a plurality of transverse projections (78) extend from an outer peripheral surface (74) of the first shaft portion (54), wherein the first vane ring (92) includes a plurality of first apertures (104) having portions (107) configured to receive the transverse projections (78), and wherein the connecting comprises:inserting each of the first shaft portions (54) into a respective one of the first apertures (104);rotating the spacer connectors (50) such that the transverse projections (78) are offset from the portions (107) of the first apertures (104), whereby each first shaft portion (54) is prevented from being withdrawn from the respective first aperture (104); andwherein, after the rotating, the transverse projections (78) are at substantially 45 degrees relative to a radial direction of the first vane ring (92) and at substantially 90 degrees relative to the aperture portions (107) configured to receive the transverse projections (78). 8. The method of claim 7, wherein each of the plurality of first apertures (104) includes a counterbore (108), and wherein the rotating occurs while the distal end (68) and the transverse projections (78) of the first shaft portion (54) are located in the counterbore (108). 9. The method of claim 7, wherein the spacer connectors (50) further include a second shaft portion (56) extending from an opposite one of the end faces (58) of the spacer body (52) to a distal end (72), wherein a plurality of transverse projections (78) extend from an outer peripheral surface (76) of the second shaft portion (56) of the spacer connectors (50) for bayonet mounting to the second vane ring (94), wherein the second vane ring (94) includes a plurality of second apertures (106) having portions (107) configured to receive the transverse projections (78) of the second shaft portion (56), and wherein the connecting further comprises: inserting each of the second shaft portions (56) into a respective one of the second apertures (106); androtating the spacer connectors (50) such that that the transverse projections (78) are offset from the portions (107) of the second apertures (106), whereby each second shaft portion (56) is prevented from being withdrawn from the respective second aperture (106). 10. The method of claim 7, wherein the spacer connectors (50) include a region (84) having a substantially flat surface (86), and wherein a plurality of apertures (114) is provided in the first vane ring (92), the method further including: providing a plurality of pins (116);inserting each pin (116) in a respective one of the apertures (114) such that an end (118) of the pin (116) engages the substantially flat surface (86) of a respective spacer connector (50), whereby rotation of the spacer connector (50) is prevented. 11. The method of claim 7, wherein, after the rotating, the transverse projections (78) are at substantially 45 degrees relative to a radial direction of the first vane ring (92) and at substantially 90 degrees relative to the aperture portions (107) configured to receive the transverse projections (78). 12. A vane pack (90) for a variable geometry turbocharger comprising: a first vane ring (92);a second vane ring (94);a plurality of spacer connectors (50) connecting the first and the second vane rings (92, 94) and maintaining a distance therebetween, the spacer connectors (50) being configured for bayonet mounting to at least one of the first vane ring (92) and the second vane ring (94);wherein the spacer connectors (50) include a spacer body (52) having opposing end faces (58, 60), a first shaft portion (54) extending from one of the end faces (60) of the spacer body (52) to a distal end (68), and wherein a plurality of transverse projections (78) extend from an outer peripheral surface (74) of the first shaft portion (54) for bayonet mounting to the first vane ring (92), wherein the first shaft portion (54) of each spacer connector (50) includes a region (84) including a substantially flat surface (86);wherein the first vane ring (92) includes a plurality of first apertures (104) having portions (107) configured to receive the transverse projections (78), each first shaft portion (54) being received in a respective one of the first apertures (104) and rotated so that the transverse projections (78) are offset from the portions (107) of the first apertures (104), whereby each first shaft portion (54) is prevented from being withdrawn from the respective first aperture (104);a plurality of pins (116), wherein each pin (116) is received in a respective one of a plurality of apertures (114) formed in the first vane rings (92) such that an end (118) of the pin (116) engages the substantially flat surface (86), whereby rotation of the spacer connector (50) is prevented; andwherein the aperture portions (107) configured to receive the transverse projections (78) are at substantially 45 degrees relative to a radial direction of the first vane ring (92). 13. The vane pack of claim 12, wherein the spacer body (52) and the first shaft portion (54) are formed as a unitary structure. 14. The vane pack of claim 12, wherein the transverse projections (78) are at substantially 45 degrees relative to the radial direction of the first vane ring (92) and at substantially 90 degrees relative to the aperture portions (107) configured to receive the transverse projections (78). 15. The vane pack of claim 12, wherein the plurality of first apertures (104) include a counterbore (108), and wherein the distal end (68) of the respective first shaft portions (54) is received in the counterbore (108) such that the distal end (68) is substantially flush with or recessed from an outer surface (96) of the first vane ring (92). 16. The vane pack of claim 12, wherein the spacer connectors (50) include a second shaft portion (56) extending from an opposite one of the end faces (58) of the spacer body (52) to a distal end (72), wherein a plurality of transverse projections (78) extend from an outer peripheral surface (76) of the second shaft portion (56) of the spacer connectors (50) for bayonet mounting to the second vane ring (94), wherein the second vane ring (94) includes a plurality of second apertures (106) having portions (107) configured to receive the transverse projections (78) of the second shaft portion (56), and wherein each second shaft portion (56) is received in a respective one of the second apertures (106) in the second vane ring (94) and rotated so that the transverse projections (78) of each second shaft portion (56) are offset from the portions (107) of the respective second aperture (106), whereby each second shaft portion (56) is prevented from being withdrawn from the respective second aperture (106). 17. A retention method for the vane pack (90) of a variable geometry turbocharger comprising: providing a first vane ring (92);providing a second vane ring (94);providing a plurality of spacer connectors (50);connecting each spacer connector (50) to the first and second vane rings (92, 94) such that the vane rings (92, 94) are maintained in spaced relation to each other and such that each spacer connector (50) is bayonet mounted to at least one of the first vane ring (92) and the second vane ring (94);wherein the spacer connectors (50) include a spacer body (52) having opposing end faces (58, 60), a first shaft portion (54) extending from one of the end faces (60) of the spacer body (52) to a distal end (68), wherein a plurality of transverse projections (78) extend from an outer peripheral surface (74) of the first shaft portion (54), wherein the first vane ring (92) includes a plurality of first apertures (104) having portions (107) configured to receive the transverse projections (78), and wherein the connecting comprises:inserting each of the first shaft portions (54) into a respective one of the first apertures (104);rotating the spacer connectors (50) such that that the transverse projections (78) are offset from the portions (107) of the first apertures (104), whereby each first shaft portion (54) is prevented from being withdrawn from the respective first aperture (104);wherein the spacer connectors (50) include a region (84) having a substantially flat surface (86), and wherein a plurality of apertures (114) is provided in the first vane ring (92), the method further including:providing a plurality of pins (116);inserting each pin (116) in a respective one of the apertures (114) such that an end (118) of the pin (116) engages the substantially flat surface (86) of a respective spacer connector (50), whereby rotation of the spacer connector (50) is prevented; andwherein, after the rotating, the transverse projections (78) are at substantially 45 degrees relative to a radial direction of the first vane ring (92) and at substantially 90 degrees relative to the aperture portions (107) configured to receive the transverse projections (78). 18. The method of claim 17, wherein each of the plurality of first apertures (104) includes a counterbore (108), and wherein the rotating occurs while the distal end (68) and the transverse projections (78) of the first shaft portion (54) are located in the counterbore (108). 19. The method of claim 17, wherein the spacer connectors (50) further include a second shaft portion (56) extending from an opposite one of the end faces (58) of the spacer body (52) to a distal end (72), wherein a plurality of transverse projections (78) extend from an outer peripheral surface (76) of the second shaft portion (56) of the spacer connectors (50) for bayonet mounting to the second vane ring (94), wherein the second vane ring (94) includes a plurality of second apertures (106) having portions (107) configured to receive the transverse projections (78) of the second shaft portion (56), and wherein the connecting further comprises: inserting each of the second shaft portions (56) into a respective one of the second apertures (106); androtating the spacer connectors (50) such that that the transverse projections (78) are offset from the portions (107) of the second apertures (106), whereby each second shaft portion (56) is prevented from being withdrawn from the respective second aperture (106).
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이 특허에 인용된 특허 (13)
Duncan William C. W. (Northampton GB3), Bayonet coupling connector.
Wu Wen C. (132-2 ; Hsi Hsin Street Chang Ya Village ; Hsiu Shui Hsiang ; Changhua TWX), Pipe connecting device with bayonet and interlocking bushing structure.
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