EP1299654A1

EP1299654A1 - Sliding sleeve

Info

Publication number: EP1299654A1
Application number: EP01956471A
Authority: EP
Inventors: Gerald Buer; Wilfried Soyka; Kristina May; Ernst Röckelein
Original assignee: INA Schaeffler KG; Schaeffler KG
Current assignee: IHO Holding GmbH and Co KG
Priority date: 2000-07-12
Filing date: 2001-06-13
Publication date: 2003-04-09
Also published as: PL199762B1; WO2002004829A1; BR0112472A; CN1276197C; CN1441881A; JP2004502907A; DE10033764B4; DE10033764A1; AU2001278448A1; PL365833A1; KR100849879B1; KR20030025938A

Abstract

The invention relates to a sliding sleeve (1) comprising a sleeve body (2) and a selector fork guide (3). Said selector fork guide (3) is provided with a first ring (4) having an angular cross-section that is produced from sheet metal in a non-cutting shaping process, said ring radially projecting from the sleeve body (2) and being fastened on the sleeve body (2).

Description

Name of the invention

sliding sleeve

description

Field of the Invention

The invention relates to a sliding sleeve with a sleeve body and a shift fork guide, in which the shift fork guide has at least one first ring made of sheet metal in a non-cutting shaping process and projecting radially from the sleeve body and fastened to the sleeve body.

Background of the Invention

Such a sliding sleeve is described in DE 198 206 54 A1. Of the sliding sleeves listed in this document, the sliding sleeve produced, including its sleeve guidance, by shaping processes is particularly advantageous. The costs for their production are low compared to sliding sleeves of the generic type, which are mainly produced by machining processes. The shift fork guide of the sliding sleeve is formed by one or two radially projecting rings fastened on the outer circumference of a sleeve body and or two cylindrical contact surfaces on the lateral surface of the sleeve body. When using a ring, a fork-shaped end of a shift fork engages around the ring laterally. If two rings are used, the rings are arranged at a distance from one another and laterally delimit a groove which is open radially outwards. The ends of the shift fork engage in this groove. The ends of the shift fork rest on the cylindrical contact surface or surfaces. there there is a relative movement between the ends of the shift fork guide and the contact surface of the sleeve body. The ends slide on the interface. The contact surface must therefore be designed with sufficient accuracy and good surface quality. For this reason, these surfaces may be machined in sliding sleeves according to the prior art after assembly of the ring (s) on the sleeve body. This increases the costs for the production of such sliding sleeves and the advantage of saving costs described at the outset is thus partially nullified.

The rings of the shift fork guide described in DE 198 20 654 A1 are thick-walled. In some cases, this has a disadvantageous effect on the weight of a sliding sleeve of the generic type and the material consumption for its manufacture.

Object of the invention

The object of the invention is therefore to provide a sliding sleeve in which the disadvantages described above are avoided.

Summary of the invention

This object is achieved according to the characterizing part of claim 1 in that the ring, viewed in longitudinal section, has an angular cross-section with a first leg extending radially from the sleeve body and a second leg extending from the first leg. One or two of the rings according to the invention with an angular cross section are attached to the sleeve body of the sliding sleeve. One leg of the ring forms the contact surface for the ends of the shift fork and / or serves as a stiffening element. The rings can therefore be made thin-walled and thus light and material-saving. The cylindrical contact surface is prefabricated on the ring, whereby usually a drawn and possibly also calibrated surface Before accuracy and surface quality for the contact of the ends of the shift fork with the shift fork guide guaranteed. It is no longer necessary to rework the contact surface after assembling the rings of the shift fork guide.

One embodiment of the invention provides that the second leg forms a circumferential stiffening collar. For a sliding sleeve, the shift fork guide of which is formed from two rings, one embodiment provides that the second leg lies axially aligned on the lateral surface of the sleeve body and points in the direction of a second ring arranged on the sleeve body and axially adjoining the first ring. The second leg forms the cylindrical contact surface for the ends of the shift fork. The second ring and the first leg of the first ring limit the groove for the engagement of the ends of the shift fork. The first ring is preferably designed such that it can also be used as a second ring. Either the second leg of the rings placed against one another or only a second leg of one of the rings form the contact surface for the ends of the shift fork.

A further embodiment of the invention provides that a second ring is arranged on the sleeve body axially spaced from the first ring and the second leg extends from the radially outer end of the first leg and the second leg axially points away from the second ring. In other words, at least one of the rings has a stiffening collar at its radially outward end. The stiffening collar points in the axial direction away from the groove of the shift fork guide.

The strength of the rings according to the invention can be increased if, as an embodiment of the invention provides, at least the leg has at least one bead formed from the sheet metal and is therefore stiffened. A further improvement in strength also results if, as described in a further embodiment, the first leg is double-walled. This embodiment of the invention is particularly suitable for the use of Shift fork guides, which are formed only by a ring. The wall sections of the leg that form the doubling can lie directly next to one another or can be axially spaced apart from one another. It is then also provided that the cross section of the first leg is considered to be axially sectioned, is formed by a U-profile open to the lateral surface, and the second leg extends from the opening on the opening side. The second leg then protrudes at right angles from one end of the U-profile and lies against the outer surface of the sleeve body.

Brief description of the drawings

The invention is explained in more detail below on the basis of several exemplary embodiments. Show it

FIG. 1 shows an exemplary embodiment of a sliding sleeve according to the invention, in which two rings of the same design form the shift fork guide with the second legs lying one against the other, on average,

FIG. 2 shows alternative arrangements and designs of rings on a sleeve body of the sliding sleeve from FIG. 1,

Figure 5 shows a sliding sleeve with a shift fork guide, the

Rings have a stiffening collar and

Figure 6 shows a sliding sleeve with a shift fork guide, which is formed from a ring, the first leg of which is designed as a U-profile.

Detailed description of the drawings

Figure 1 shows with 1 an embodiment of a sliding sleeve according to the invention. The sliding sleeve 1 consists of a sleeve body 2 and one Shift fork guide 3. The shift fork guide 3 sits on the sleeve body 2 and is formed by two rings 4 formed symmetrically to one another. The ring 4 has an angular cross section with a first leg 4a extending from the sleeve body 2 in the radial direction and a second leg 4b departing at right angles from the first leg 4a. The second legs 4b lie axially aligned on the lateral surface of the sleeve body 2 and abut one another with their end faces. The rings 4 delimit a guide groove 3a. The bottom of the groove 3a has a cylindrical contact surface 3b, which is formed by the outward-facing side of the second leg 4b. The first leg 4a of the rings 4 is provided with a plurality of beads 5 distributed in the radial direction and distributed around the circumference of the ring 4.

In FIG. 2, two rings 6 formed symmetrically to one another are arranged axially one after the other on the sleeve body 2. The second legs 6b in turn face each other and touch each other on the end faces. The radially outwardly directed first legs 6a have a thicker wall than the second legs 6b and are therefore unreinforced.

Figure 3 shows a version of the arrangement of a ring 7 and a ring 8, which together form a shift fork guide. The second leg (7b) of the ring 7 is axially aligned with the outer surface of the sleeve body 2 and touches the first leg 8a of the second ring 8. The second leg 8b of the ring 8 points outward in the axial direction. The guide groove 9 is delimited by the back of the first leg 8a, by the outwardly facing side of the second leg 7b and by the side surface of the first leg 7a of the ring 7 facing the ring 8. The cylindrical guide surface (9a) is formed by the outward side of the second leg 7b. The first legs 7a, 8a of the rings 7, 8 are each stiffened with beads 10 and 11, respectively. FIG. 4 shows two rings 12 and 13, which are arranged as in FIG. 3. The first legs 12a and 13a are made unreinforced. The second legs 12b and 13 are of different lengths.

FIG. 5 shows a detail of a sliding sleeve 14 with a sleeve body 15 and a shift fork guide 16. The shift fork guide 16 is formed from two symmetrically designed rings 17. The rings 17 are axially spaced apart. The first leg 17a of the rings 17 points inwards in the radial direction. The second leg 17b extends from the radially outer end of the first leg 17a. In addition, the second leg 17b points axially outwards and thus away from the other ring 17. The guide groove 16a of the shift fork guide 16 is delimited in the axial direction by one side of the first leg 17a. The cylindrical contact surface 18 in the groove base of the guide groove 16a is formed by a molding on the sleeve body 15.

Finally, FIG. 6 shows a sliding sleeve 19 with a ring 20 on a sleeve body 21. The ring 20 forms the shift fork guide 22. The first leg 20a is double-walled by a U-profile which is open to the outer surface. On the opening side, the second leg 20b extends from the U-profile. The second leg 20b is axially aligned with the outer surface of the sleeve body and, with its outwardly facing cylindrical surface, forms a cylindrical contact surface for ends of a shift fork, not shown.

reference numeral

Sliding sleeve 16 shift fork guide

Sleeve body 16a guide groove

Shift fork guide 16 ring a guide groove 17a first leg b contact surface 17b second leg

Ring 17 contact surface a first leg 18 sliding sleeve b second leg 19 ring

Bead 20a first leg

Ring 20b second leg a first leg 20 sleeve body b second leg 21 shift fork guide

Ring a first leg b second leg

Guide groove a guide surface 0 bead 1 bead 2 ring 2a first leg 2b second leg 3 ring 3a first leg 3b second leg 4 sliding sleeve 5 sleeve body

Claims

claims

1. sliding sleeve (1, 14, 19) with a sleeve body (2, 15, 21) and a shift fork guide (3, 16, 22), in which the shift fork guide (3, 16,

22), has at least one first ring (4, 6, 7, 12, 17, 20) made radially from the sleeve body (2, 15, 21) and fastened to the sleeve body and made of sheet metal in a non-cutting shaping process, characterized in that the ring (4, 6, 7, 12, 17, 20), viewed in longitudinal section, has an angular cross-section with a first leg (4a, 6a, 7a, 12a, 17a) pointing radially from the sleeve body (2, 15, 21), 20a) and a second leg (4b, 6b, 7b, 12b, 17b, 20b) extending from the first leg (4a, 6a, 7a, 12a, 17a, 20a).

2. Sliding sleeve according to claim 1, characterized in that the second leg (17b) forms a circumferential stiffening collar.

3. sliding sleeve according to claim 1, characterized in that the second leg (4b, 6b, 7b, 12b,) bears axially aligned on the lateral surface of the sleeve body (2) and in the direction of one arranged on the sleeve body (2) and on the first Ring (4, 6, 7, 12) axially adjoining second ring (4, 6, 8, 13) has.

4. sliding sleeve according to claim 1, characterized in that on the sleeve body (15) a second ring (17) to the first ring (17) is axially spaced and the second leg (17b) from the radially outer end of the first leg ( 17a) and the second leg (17b) points axially away from the second ring (17).

5. Sliding sleeve according to claim 1, characterized in that at least one of the legs (4a, 7a, 8a) has at least one bead (5, 10) formed from sheet metal.

6. sliding sleeve according to claim 1, characterized in that at least the first leg (20a) is double-walled.

7. sliding sleeve according to claim 6, characterized in that the cross section of the first leg (20a) viewed axially cut is formed by a U-profile open to the lateral surface of the sleeve body (21) and of the U-profile on the opening side of the second leg (20b) going on.