DE102016206569A1 - Synchro ring spring with locking function - Google Patents

Abstract

In a synchronizer for a transmission of a motor vehicle, it is provided that in each case an annular spring is provided between a synchronous carrier body and a synchronizer ring, which is axially displaceable and radially resiliently arranged to initiate a Vorsynchronisation and the sliding sleeve in a neutral position and / or switching position To lock against the synchronous carrier body.

Description

The invention relates to a synchronizer for a transmission of a motor vehicle with a synchronous carrier body for non-rotatably receiving an axially displaceable sliding sleeve, which in turn is connected to a drive shaft of the transmission, and at least one gear, which is coupled by means of the sliding sleeve with the synchronous carrier body and with a synchronizer ring, which is arranged between a coupling body of the gear wheel and the synchronous carrier body to produce a speed equalization of the gear wheel to the synchronous carrier body. In addition, ring springs are provided for Vorsynchronisation between the synchronous carrier body and the synchronizer rings.

By the US 4,776,228 For example, a synchronizer with a synchronous carrier body, a sliding sleeve, a synchronizer ring, a coupling body and a gear is known, which has for Vorsynchronisierung annular springs which are each mounted in a groove of the synchronizer ring and pressed at an axial switching movement of the sliding sleeve against the synchronizer ring.

The EP 0743466 A1 shows a synchronizer with two axially movable annular springs which are axially supported on a synchronous carrier body and press radially resiliently provided slides in recordings of a sliding sleeve to lock them in a neutral position relative to the synchronous carrier body. A locking of the sliding sleeve in a switching position is not possible.

By the WO 2007/068432 a synchronizer is known which comprises ring springs between a synchronizer carrier body and axially spaced synchronizer rings. The annular springs have axially extending thin-walled stops which limit an axial displaceability of the annular spring.

The FR 2390633 discloses an annular spring, which has radial projections for centering a sliding sleeve, which engage resiliently in a locking receptacle of the sliding sleeve.

By the EP 0756098 B1 is a synchronizer with two spring rings with evenly distributed on the circumference of the spring rings arranged protrusions which abut a ramped cam of the sliding sleeve. The spring rings are each mounted axially displaceable between the synchronizer carrier body and a synchronizer ring and are urged radially to the Vorsynchronisation means of the sliding sleeve against the synchronizer ring and through the cam. A centering of the sliding sleeve relative to the synchronous carrier body is not possible.

The invention has for its object to provide a synchronizer with spring rings that allow both a Vorsynchronisierung, as well as a locking of the sliding sleeve in a neutral position and a switching position.

The object is achieved by the features of claim 1.

It is a particular advantage of the invention that the respectively arranged between a synchronous carrier body and a synchronizer ring ring springs are arranged axially displaceable and radially resilient. The annular springs have radial projections, by means of which they can engage in locking receptacles of the sliding sleeve. By this measure, the ring springs can engage both for locking the sliding sleeve relative to the synchronous carrier body in the locking receptacles of the sliding sleeve, as well as for Vorsynchronisation be brought by the sliding sleeve in contact with the respective synchronizer ring.

The sliding sleeve has in an advantageous embodiment, two locking receptacles, in which the annular springs can engage both in a neutral position, as well as in a switching position. The latching receptacles each have groove contours, e.g. Ramps on which the radial projections of the annular springs, with a defined by the ramp contour force, can slide in and out of the locking receptacle.

Advantageously, the two ring springs support each other during the switching process and in the locking of the sliding sleeve. Here, the annular spring, which is associated with the gear wheel to be switched is taken axially for Vorsynchronisation by the locking receptacle of the sliding sleeve and pressed against the synchronizer ring, while the other annular spring is blocked on the synchronous carrier body adjacent in the axial direction and is pressed by the groove contour radially resiliently inward.

As soon as the presynchronization has taken place, the first annular spring is first pressed radially inwards by the groove contour between the latching receptacles until the annular spring, fitting against the synchronizer support body, engages in the second latching receptacle. In this switching position, the sliding sleeve is locked by the first annular spring in the axial direction wherein the annular spring is spaced from the synchronizer ring.

In a preferred embodiment, the ring springs in addition to the radial projections and axial projections, by means which these are supported on the synchronous carrier body. By this measure, the synchronous carrier body can be made narrow especially in the region of its end walls, so that the weight of the synchronous carrier body and the required space can be minimized.

In an alternative embodiment, two different length switching paths of the sliding sleeve can be realized in an advantageous manner. For this purpose, the sliding sleeve per spring ring two, the proposed switching path corresponding axially spaced apart, locking receptacles. The locking receptacles for the first annular spring are arranged rotatably offset by at least one tooth of the internal toothing of the sliding sleeve to the locking receptacles of the second annular spring. The annular springs are arranged rotationally offset by the same amount, so that the radial projections can engage in the corresponding latching receptacles.

The arranged between the synchronizer carrier body and the respective synchronizer rings ring springs are preferably of identical construction, so that they are inexpensive to produce in large quantities.

Further advantageous embodiment are described in the subclaims.

An embodiment of the invention is illustrated in the drawings and will be described below. Show it

1 a synchronous carrier body with a ring spring in a perspective view

2 the synchronous carrier body with two ring springs in section in a neutral position

3 the synchronous carrier body in a "Vorsynchronisationsstellung" of the annular springs in section

4 the synchronous carrier body in a switching position of a sliding sleeve in section

5 the synchronous carrier body in the switching position with locking of the sliding sleeve by one of the annular springs.

6 the synchronous carrier body with staggered annular springs in a perspective view.

7 a partial view of the sliding sleeve with staggered annular springs.

8th the sliding sleeve with staggered arranged locking receptacles.

9 the sliding sleeve in section with different lengths of shift.

A synchronizer 1 for a transmission of a motor vehicle has according to 2 a synchronous carrier body 2 on which is rotatably mounted on a transmission shaft and on its outer periphery an axially displaceably mounted sliding sleeve 3 wearing. The sliding sleeve 3 is by means of an internal toothing 4 rotatably with an external toothing 6 of the synchronizer carrier body 2 connected. In the axial direction is on both sides next to the synchronous carrier body 2 a synchronizer ring 7 . 8th arranged, which in turn each a gear wheel 9 . 11 is assigned, which in each case by means of the sliding sleeve 3 with the synchronous carrier body 2 is detachable.

It is provided for Vorsynchronisierung that in each case between the synchronous carrier body 2 and the synchronizer ring 7 . 8th a ring spring 12 ; 13 is arranged. The ring springs 12 . 13 are axial on end walls 17 . 18 of the synchronizer carrier body 2 supported between a hub 14 and a sprocket 16 of the synchronizer carrier body 2 are arranged. To the synchronous carrier body 2 in the area of its end walls 17 . 18 to be able to train narrow, assign the ring springs 11 . 12 axial protrusions 11.1 . 12.1 on.

In the radial direction, the ring springs 12 . 13 radial projections 12.2 . 13.2 on, which through recesses 19 in the sprocket 16 reach through and into detent recesses 21 . 22 in the sliding sleeve 3 engage to these opposite the synchronous carrier body 2 to lock.

The ring springs 12 . 13 are axially displaceable and arranged radially resilient. The rest shots 21 . 22 are each in the area of the recesses 19 formed as grooves in teeth 20 the internal toothing of the sliding sleeve 3 are arranged and each have lateral, in the axial direction increasing groove contours 23 For example, ramps that allow the ring springs 12 . 13 with a force defined by the ramp contour in the grooves 21 . 22 can slide in and out.

In a neutral position according to 2 lie the ring springs 12 . 13 by means of their axial projections 12.1 . 13.1 on the end walls 17 of the synchronizer carrier body 2 at. At the same time, the radial projections engage 12.2 . 13.2 resilient, ie with a defined bias in the locking receptacles 21 . 22 the sliding sleeve 3 one. In this position is the sliding sleeve 3 against axial displacement relative to the synchronous carrier body 2 secured.

When initiating the switching process, the sliding sleeve 3 according to 3 in the direction of synchronizer ring 7 shifted by one switching path s. This takes the sliding sleeve 3 the ring spring 12 by means of her locking receptacle 21 with, until the ring spring 12 on a front side 24 of the synchronizer ring 7 strikes.

At the same time the ring spring 13 , which are on the opposite end wall 18 of the synchronizer carrier body 2 abuts the end wall 18 blocked in the axial direction and through the groove contour 23 pressed radially inward.

Once the speeds of the synchronizer ring 7 and the gear wheel 9 to the speed of the synchronizer carrier body 2 and the sliding sleeve 3 are adapted, the sliding sleeve 3 to be switched through the switching path s until the gear according to 5 is inserted. In this switching position, the ring spring engages 12 with their radial projections 12.2 in the snap-in receptacle 22 and locks the sliding sleeve 3 in the switching position relative to the synchronous carrier body 2 ,

In an alternative embodiment according to 6 , It is for the realization of different lengths of switching paths s, a of the sliding sleeve 3 to insert the gears 9 . 11 , provided that ever ring spring 12 . 13 two snap shots 21 . 22 and 26 . 27 in the internal toothing of the sliding sleeve 3 are arranged. The rest shots 21 . 22 are at least one tooth 20 across from

the rest shots 26 . 27 arranged rotated against each other. The switching path S of the sliding sleeve 3 corresponding distance s of the locking receptacles 21 . 22 is here unequal to the distance a of the locking receptacles 26 . 27 ,

The ring springs 12 . 13 are according to the snap shots 21 . 22 respectively. 26 . 27 rotatably offset from each other, so that the radial projections 12.2 the first ring spring 12 in the rest shots 21 . 22 and the radial projections 13.2 the second ring spring 13 in the rest shots 26 . 27 can intervene.

In this alternative embodiment, the neutral position is according to 9 by simultaneous engagement of the annular spring 12 in the snap-in receptacle 21 and engagement of the annular spring 13 in the snap-in receptacle 27 with simultaneous axial support of the ring springs 12 . 13 on the synchronizer carrier body 2 Are defined.

The first switching position of the sliding sleeve 3 when switching the first gear wheel 9 is, as already described above, by the engagement of the annular spring 12 in the snap-in receptacle 22 defined while the second switching position of the sliding sleeve 3 when switching the second gear wheel 11 by intervention of the ring spring 13 in the snap-in receptacle 26 is defined.

The ring springs 12 . 13 are in both switching positions on the synchronous carrier body 2 supported and from the synchronizer rings 7 . 8th spaced.

LIST OF REFERENCE NUMBERS

1

 synchronizer

2

 Synchronous support body

3

 sliding sleeve

4

Internal toothing ( 3 )

5

6

External toothing ( 2 )

7

 synchronizer ring

8th

 synchronizer ring

9

 Gear wheel (toothing)

10

11

 Gear wheel (toothing)

12

 Ringfeder

12.1

 Projection (axial)

12.2

 Projection (radial)

13

 Ringfeder

13.1

 Projection (axial)

13.2

 Projection (radial)

14

Hub ( 2 )

15

16

Sprocket ( 2 )

17

Front wall ( 2 )

18

Front wall ( 2 )

19

Recess ( 16 )

20

Tooth (internal toothing of 3 )

21

 latching receptacle

22

 latching receptacle

23

 Groove contour (ramp)

24

Front side ( 7 )

a

Switching path ( 3 ), Distance ( 21 - 22 )

s

Switching path ( 3 ), Distance ( 26 - 27 )

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 4776228 [0002]
• EP 0743466 A1 [0003]
• WO 2007/068432 [0004]
• FR 2390633 [0005]
• EP 0756098 B1 [0006]

Claims (10)

Synchronizing device with a synchronous carrier body for non-rotatably receiving an axially displaceable sliding sleeve, at least one gear wheel, at least one synchronizing ring and in each case one between the synchronous carrier body and the synchronizer ring arranged spring ring, characterized in that the spring ring ( 12 ; 13 ) for pre-synchronization axially displaceable and for locking the sliding sleeve ( 3 ) is arranged radially resiliently in a neutral position or a switching position. Synchronizing device according to claim 1, characterized in that the sliding sleeve ( 3 ) two axially spaced locking recesses ( 21 . 22 ; 26 . 27 ) having. Synchronizing device according to claim 3, characterized in that two spring rings ( 12 . 13 ) are provided that both spring rings ( 12 . 13 ) axially on the synchronous carrier body ( 2 ) are supported, that the first spring ring ( 12 ) for locking the sliding sleeve ( 3 ) relative to the synchronous carrier body ( 2 ) in a neutral position in the first latching receptacle ( 21 ) engages and that the second spring ring ( 13 ) in the second latching receptacle ( 22 ) intervenes. Synchronizing device according to claim 2, characterized in that two spring rings ( 12 . 13 ) are provided, that the first spring ring ( 12 ) for locking the sliding sleeve ( 3 ) relative to the synchronous carrier body ( 2 ) in a first switching position in the second latching receptacle ( 22 ) engages and axially on the synchronous carrier body ( 2 ) is supported or that the second spring ring ( 13 ) in a second switching position in the first latching receptacle ( 21 ) engages and axially on the synchronous carrier body ( 2 ) is supported. Synchronizing device according to one of claims 1 to 4, characterized in that an axial distance (s; a) between the locking receptacles ( 21 . 22 ; 26 . 27 ) the switching path (s: a) of the sliding sleeve ( 3 ) and the distance between neutral position and switching position corresponds. Synchronizing device according to one of the preceding claims, characterized in that the sliding sleeve ( 3 ) in addition to the locking receptacles ( 21 . 22 ) more, at least one tooth ( 20 ) of the internal toothing of the sliding sleeve ( 3 ) rotatably arranged, latching receptacles ( 26 . 27 ) having. Synchronizing device according to one of claims 5 or 6, characterized in that an axial distance (s) of the locking receptacles ( 21 . 22 ) unequal to the axial distance (a) of the locking receptacles ( 26 . 27 ) Synchronizing device according to one of the preceding claims, characterized in that the spring rings ( 12 . 13 ) have radial projections. Synchronizing device according to claim 6, characterized in that the spring rings ( 12 . 13 ) with their radial projections ( 12.2 . 13.2 ) according to the offset of the locking receptacles ( 21 . 22 ; 26 . 27 ) are arranged offset in rotation with respect to each other. Synchronizing device according to one of the preceding claims, characterized in that the spring rings ( 12 . 13 ) for supporting on the synchronous carrier body ( 2 ) axial projections ( 12.1 . 13.1 ) exhibit.

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