DE102016104628A1 - Locking device for synchronizations - Google Patents

Abstract

The invention relates to a locking device (1) for synchronizations, with an axially fixed in a shaft and with this rotatably connected synchronizer body (2) having a radially outer teeth (4), and with a rotatably mounted in the shaft idler gear (5), with an outer toothing (6), and with a ring sleeve designed as a shift sleeve (7) radially an internal toothing (8), which cooperates with the external toothing (4) of the synchronizer body (2), wherein the shift sleeve (7) in a first End position is disengaged and in a second end position in engagement with the external toothing (6) of the idler gear (5), wherein in the synchronizer body (2) a synchronizer ring (9) is mounted axially displaceable, the friction surface (10) for cooperation with a Having friction surface (11) of the idler gear (5), further comprising a locking catch (12) for the shift sleeve (7), wherein the locking catch (12) has at least one spring element (13) in a Rastierstellun g positively with the shift sleeve (7) cooperates. In the locking device of the synchronizer ring (9) is designed such that it exerts a radially outwardly directed force on the spring element (13) for supporting the spring force of the spring element (13) due to a torque applied during the synchronization process. The locking device ensures the Rastierfunktion and the synchronization function even with smaller design of the spring element.

Description

The invention relates to a locking device for synchronizations, with an axially fixed in a shaft and rotatably connected with this synchronous body, wherein the synchronizer body has radially outer teeth, and with a rotatably mounted in the shaft idler gear, which has radially outer teeth, and with a Ring trained shift sleeve, which radially has an internal toothing, which cooperates with the external toothing of the synchronizer body, wherein the shift sleeve is in a first end position out of engagement with the external teeth of the idler gear and in a second end position in engagement with the external teeth of the idler gear, wherein in the Synchronizer a synchronizer ring is mounted axially displaceable and the synchronizer body has a friction surface for cooperation with a friction surface of a loose wheel, further comprising a locking catch for the sliding sleeve, wherein the Rastiersperre has at least one spring element in an R astierstellung cooperates positively with the sliding sleeve.

Such a locking device for synchronizations is from the DE 10 2012 103 288 A1 known. The spring arrangement shown there serves to generate an inhibiting force, wherein an adjusting device for achieving an axial displacement of the sliding sleeve in the direction of the idler gear a first force in the axial direction on the shift sleeve applies, which is smaller than the restraining force of the spring assembly and with the friction surfaces of synchronizer ring and idler gear can be brought into contact, so that after the speed synchronization between the synchronizer body and the idler gear adjusting the application of a second force in the axial direction on the shift sleeve, which is greater than the restraining force of the spring assembly and with the teeth of synchronizer body and idler gear by further displacement the shift sleeve can be brought into engagement. The use in this locking device spring arrangement is relatively strong to dimension to ensure the locking catch for the shift sleeve.

From the DE 696 09 678 T2 a synchronizer clutch unit for a manually shiftable transmission is known. Here, a radially deformable C-shaped spring element is arranged between a coupling sleeve and a blocking ring with a plurality of protruding portions, which is engageable with at least one of coupling sleeve teeth when the coupling sleeve is moved in the direction of the blocking ring and radially when engaged with the coupling sleeve teeth inwardly compressible.

In the DE 600 02 277 T2 is described a synchronization unit for a transmission with a synchro-spring, which is mounted on an outer circumference of a locking ring, wherein the locking ring is pressed with the synchro-spring in the direction of a gear, by, in the axial movement of a shift sleeve, the synchro-spring protruding portions of splines on the inner circumference of the shift sleeve is pressed radially inward.

In the US 4,620,623 is a spring for defining a locking function of a shift sleeve in a synchronizer of transmissions described. The spring is arranged in a groove on an inner side of coupling elements, between a web of a shift sleeve and radially arranged teeth of the shift sleeve.

In the DE 1 111 952 a synchronization device for a speed change operation is described. In this locking bands are pressed at speed difference to the outside, whereby a compression of a synchronizer ring and thus over slipping a shift sleeve is avoided at a speed difference.

Object of the present invention is to develop a locking device of the type mentioned so that the Rastierfunktion and the synchronization function is ensured even with a smaller design of the spring element.

The problem is solved by a locking device which is designed according to the features of claim 1.

In the locking device for synchronization is provided that the synchronizer ring is designed such that it exerts a radially outwardly directed force on the spring element to support the spring force of the spring element due to a torque applied during the synchronization process. By additionally acting on the spring element force that supports the spring force of the locking lock, the spring element can be made smaller. When speed is adjusted after the synchronization has ended, this additional force is no longer effective. The spring element is pressed inwards and it is possible to switch through the sliding sleeve.

Basically, two principles of action are considered to be particularly advantageous. The one active principle is to spread the respective spring element in the radial direction. The torque of the synchronizer ring exerts a force on the spring element. In this case, this force supports the own spring force of the locking lock in order to make the spring element smaller. The spring element sits in a groove and transmits the axial Force from the sliding sleeve on the synchronizer ring until the spring element is pushed by sufficient axial force or omission of the support by the torque of the synchronizer ring during synchronization from the groove in the direction of the shaft center. Then the shift sleeve can be switched through. The other operating principle is to push the spring element, which is in particular a stamped part, by a ramp in the radial direction and so to transmit the axial force of the sliding sleeve on the synchronizer ring. If the ramp is centered again after synchronization, the spring element can be forced out of the groove according to the first operating principle.

Structurally particularly simple, the respective spring element is designed when it is designed as an annular spring. This annular spring extends almost over a full circle or over a partial circle. Extends the spring element over almost a full circle, for example over an angle of about 340 °, only a single spring element use. This effect of this spring element can be distributed to a plurality of spring elements, which then extend correspondingly only over a pitch circle, for example over an angle of approximately 90 ° to 110 °. When using a plurality of spring elements preferably three spring elements, in particular three identically designed spring elements are provided. In particular, they are evenly distributed over the circle.

In structurally particularly simple design, the function of the respective spring element, in particular the respective annular spring can be realized when the spring element has an arc portion and, connected to the arc portion in the region of its opposite ends, radially inwardly directed hook portions. According to an advantageous embodiment, it is provided that the two hook portions of the respective spring element are arranged limitedly displaceable in the circumferential direction of the synchronizer body and engage in recesses of the synchronizer body. Thus, over the two hook portions end forces can be introduced into the spring element, which lead to the spreading of the spring element radially outward, thus against the shift sleeve.

It is considered to be particularly advantageous if the synchronizer ring and the synchronizer body or the synchronizer ring and the sliding sleeve each have at least one stop, wherein a spring element associated with these stops is spread radially outwards during a relative rotation of the synchronizer body and synchronizer ring between the stops. It can thus be achieved with structurally particularly simple design and arrangement of the spreading effect.

In particular, it is provided that the respective spring element, bounded on both sides axially, is axially displaceable with respect to the synchronizer body. As a result, with structurally particularly simple design of the interacting parts, the synchronization can take place by moving the synchronizing ring for the purpose of synchronization with its friction surface against the friction surface of the idler gear with slight axial displacement of the sliding sleeve and thus simultaneous displacement of the spring element. Is synchronism between the synchronizer body and idler gear, the shift sleeve can be switched through and it is the spring element pressed inwards. In particular, the respective spring element contacts the synchronizer ring, wherein in the function of the locking lock by means of the respective axially displaceable spring element, the synchronization force is transmitted axially to the synchronizer ring.

The positive connection between the respective spring element and the shift sleeve is accomplished in the simplest manner by the fact that the shift sleeve radially inwardly has a groove for receiving the associated spring element. In particular, the shift sleeve on a over a full circle extending groove for receiving the or the spring elements.

In the active principle with ramp is preferably provided that the synchronizer ring has a radially outwardly directed ramp. In a relative displacement of synchronizer ring and the ramp associated spring element, the spring element is spread in a central region by means of the ramp radially outward.

The respective spring element is preferably formed as a stamped part or as a wire spring. Both variants are particularly easy and inexpensive to produce. A punched part has the particular advantage that the force transmission of the spring element can be structurally influenced by the punching geometry.

Further features of the invention will become apparent from the dependent claims, the accompanying drawings and the description of several reproduced in the drawing preferred embodiments, without being limited thereto.

It shows in a schematic representation:

1 A first embodiment of a locking device for synchronizations, viewed in the axial direction of a shaft of the locking device,

2 a cut AA in 1 .

3 an inverted section BB according to 1 .

4 to 9 for this first embodiment, functional sequences, starting from a rest position of a synchronizer ring with respect to a synchronizer body to the state of switching through a sliding sleeve,

10 a second embodiment in a representation according to 1 .

11 a section AA according to 10 .

12 an inverted section BB according to 10 .

13 to 18 for this second embodiment, switching phases between the rest position and switching through according to the first embodiment, wherein additionally the arrangement of the parts in the inverted section BB according to 10 is illustrated

19 a third embodiment in a representation according to 1 .

20 a section AA according to 19 .

21 an inverted section BB according to 19 .

22 to 27 Switching phases for this third embodiment switching phases according to the 13 to 18 .

28 a fourth embodiment in a representation according to 1 .

29 a section AA according to 28 .

30 an inverted section BB according to 28 .

31 a fifth embodiment in a representation according to 1 .

32 a section AA according to 31 .

33 an inverted section BB according to 31 .

34 to 39 for this fifth embodiment switching phases according to 13 to 18 ,

The first embodiment according to the 1 to 9 illustrates in simplified representation a locking device 1 for synchronizations. This has a synchronizer body 2 on. This one is around an axis 3 rotatable, not illustrated shaft rotatably connected and fixed axially in this shaft. The synchronizer body 2 has radially outer teeth 4 on. In the around the axis 3 rotatable, not illustrated shaft is a loose wheel 5 rotatably mounted. This has radially outer teeth 6 on. The locking device 1 also has a trained as a ring shift sleeve 7 on. This has radially an internal toothing 8th on that with the external teeth 4 of the synchronizer body 2 interacts. The gears 4 . 6 and 8th are each about the axis 3 circulating. In a first end position, how to 2 is illustrated is the shift sleeve 7 out of engagement with the external teeth 6 of the idler wheel 5 , In a second end position of the shift sleeve 7 this is in engagement with the external toothing 6 of the idler wheel 5 , In the synchronizer body 2 is a synchronizer ring 9 mounted axially displaceable. The synchronizer ring 9 has a friction surface 10 for interaction with a friction surface 11 of the idler wheel 5 on. These around the axis 3 circumferential friction surfaces 10 . 11 are at an acute angle to the axis 3 arranged. It is further, as in particular the representation of 3 it can be seen, a locking lock 12 for the shift sleeve 7 intended. This locking lock 12 has a single spring element 13 on, in a Rastierstellung, as in the 1 to 3 is illustrated in particular form-fitting with the sliding sleeve 7 interacts. The synchronizer ring 9 is configured such that it due to a torque applied during the synchronization process, a radially outwardly directed force on the spring element 13 to support the spring force of the spring element 13 exercises.

The spring element 13 is designed as a ring spring made of wire, which extends almost over a full circle. The spring element 13 has a bow section 14 and, with the bow section 14 connected in the region of its opposite ends, radially inwardly directed hook portions 15 . 16 on. These hook sections 15 . 16 grab in recesses 17 . 18 of the synchronizer body 2 one. The two hook sections 15 . 16 are in the circumferential direction of the synchronizer body 2 limited storage. The synchronizer ring 9 points, between the two hook sections 15 . 16 arranged a stop 19 on.

The spring element 13 is on the axis 3 relative, axially bounded on both sides within a recess 20 of the synchronizer body 2 arranged, wherein the strength of the wire of the spring element 13 is dimensioned so that it is less than the axial extent of the recess 20 , As a result, the spring element 13 axially with respect to the synchronizer body 2 displaced. The sliding sleeve 7 has radially inside a groove 21 with a circular arc-shaped cross section. The groove 21 serves to receive the cross-sectionally circular spring element 13 , the over a partial radius into the groove 21 engages, bringing a detent spring element 13 and shift sleeve 7 takes place.

The operation of the locking device described with respect to this embodiment will be described below with reference to the illustration of 4 to 9 explained, in addition to a slightly modified embodiment with three spring elements 13 to the switching phases described in this according to the 13 to 18 Reference is made.

4 shows the functional state of the rest position. Here are the hook sections 15 and 16 of the spring element 13 with play in the recesses associated with them 17 . 18 of the synchronizer body 2 and there is the stop 19 of the synchronizer ring 9 at a distance to the two hook sections 15 . 16 , When synchronizing the shift sleeve is 7 something in the axial direction on the idler gear 5 delivered, with Rastierung the shift sleeve 7 , wherein the spring element 13 correspondingly slightly within the recess 20 of the synchronizer body 2 is moved. When synchronizing, the synchronizer ring rotates 9 in the direction of the 5 illustrated arrow 22 , thus in the direction of the hook section 16 and contact him. As in 6 illustrates, pushes the synchronizer ring 9 when synchronizing the spring element 13 and thus exerts a force, illustrated by the arrow 23 , on the hook section 16 out. This leads to a corresponding rotation of the spring element 13 in total, so how, how to 7 shown, the hook section 15 against a leading stop 24 in the recess 17 as it is complemented by the arrow 25 is illustrated. When moving the hook section further 16 inside the recess 18 increases the distance of the hook sections 15 . 16 , with the result that the spring element 13 is spread outwards, as it is for the illustrated subregion in 7 through the arrows 26 is illustrated. In this synchronization is the spring element 13 thus on stop and causes a radial force to the outside, as shown in the arrows 26 , This force according to the arrows 26 supports the output spring force of the spring element 13 , thus the spring force of the locking lock. As a result, the spring element 13 be designed small. During synchronization, thus speed adaptation of synchronizer body 2 and idler gear 5 , no spreading force is more effective. Illustrated in this regard 8th the unlock. Here, the spring element 13 pressed inwards and it turns the synchronizer ring 9 back. Illustrated in this regard, the inverse arrows to the state after 7 , After unlocking, the switch-through takes place. The spring element is pushed all the way in, the sliding sleeve 7 pushes through so that their internal teeth 8th with the external teeth 6 of the idler gear 5 come in positive engagement.

The second embodiment according to the 10 to 18 differs from the first example in that not a single expansion element in the form of the spring element 13 is provided, but three spreading elements in the form of the three spring elements 13 , These are evenly distributed around the circumference, wherein each spring element 13 a bow section 14 and two hook sections 15 . 16 having, wherein the hook portions 15 . 16 in recesses 17 . 18 intervention. Each spring element 13 is a stop 19 assigned between the two hook sections 15 . 16 of the respective spring element 13 is arranged.

The operation of the locking device according to this embodiment corresponds to that of the locking device according to the first embodiment, only with the difference that three spring elements 13 instead of a single spring element 13 are effective.

The 13 and 14 show the state of the rest position in an axis view according to 10 and an inverted section BB according to 10 , comparable to the rest position according to 4 , The 15 and 16 show representations according to the 13 and 14 , however, for the state of the synchronization, with respective spring element 13 on stop and radially outward force, according to the state in 7 , The 17 and 18 show representations according to the 13 . 14 respectively. 15 . 16 , however, for the state of the switching in accordance with 9 , thus with inwardly pressed spring element 13 and pushing through the sliding sleeve 7 ,

14 it can be seen that the friction surfaces 10 . 11 from synchronizer ring 9 and idler gear 5 not cooperate in the rest position, at detent, thus engaging the respective spring element 13 in the groove 21 the shift sleeve 7 , At the state of synchronization according to 16 the two friction surfaces act 10 . 11 together, with slight axial displacement of sliding sleeve 7 and still in the groove 21 engaging spring element 13 , In the condition according to 18 is the switching through of the sliding sleeve 7 takes place and illustrates that now the spring element 13 out of the groove 21 the shift sleeve 7 is pushed out, thus pressed radially inward and at the area of the sliding sleeve 7 rests, no groove 21 , thus having a smaller, constant inner diameter. Consequently, via the spring element 13 no more axial force on the synchronizer ring 9 transfer.

The third embodiment according to the 19 to 27 is different from that second embodiment according to the 10 to 18 in that the respective spring element 13 when synchronizing between the stop 19 of the synchronizer ring 9 and a stop 27 the shift sleeve 7 is spread radially outward. The 22 to 27 show functional representations of this embodiment according to the functional representations of 13 to 18 to the third embodiment. Thus illustrate 22 and 23 the resting position, the 24 and 25 the synchronization of the spring element 13 at the stop 19 , wherein the radial force to the outside through the trapezoidal stop 27 is reinforced. 26 and 27 show the state of the through-connection. The spring element 13 is pressed inwards and the shift sleeve 7 push through.

The 28 to 30 show a fourth embodiment in which the function of the operation on the one hand and the power transmission on the other hand is disconnected. This embodiment corresponds essentially to the embodiment according to the 19 to 27 ,

In the fifth embodiment according to the 31 to 39 is the respective spring element 13 in a central area between its two hook sections 15 . 16 with a radially outwardly directed recess 29 Mistake. In the rest position is adjacent to this depression 29 a trapezoidal ramp 28 of the synchronizer ring 9 arranged. This trapezium tapers in cross section radially outward. When synchronizing, thus turning the synchronizer ring 9 , contacted the slope of the ramp 28 a slope of the depression 29 of the spring element 13 and causes the spring element 13 at the attacks 24 the recesses 17 . 18 is applied. Due to the action of the ramp 28 on the spring element 13 this will be in the direction of the arrow 26 moved radially outward, thus spread, as shown in the illustration of 36 and 37 is illustrated. These figures show the synchronization, thus with spring element 13 on stop and radial force to the outside. The 38 and 39 show the state of the through-connection. The spring element 13 is pushed inwards, the shift sleeve 7 pushes through and it becomes the synchronizer ring 9 turned back again.

In this fifth embodiment, this being particularly the representation of 31 it can be seen, is the respective spring element 13 formed as a stamped part.

LIST OF REFERENCE NUMBERS

1

locking device

2

synchronizer

3

axis

4

external teeth

5

Losrad

6

external teeth

7

shift sleeve

8th

internal gearing

9

synchronizer ring

10

friction surface

11

friction surface

12

Rastiersperre

13

spring element

14

arc section

15

hook section

16

hook section

17

recess

18

recess

19

attack

20

recess

21

groove

22

arrow

23

arrow

24

attack

25

arrow

26

arrow

27

attack

28

ramp

29

deepening

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

• DE 102012103288 A1 [0002]
• DE 69609678 T2 [0003]
• DE 60002277 T2 [0004]
• US 4620623 [0005]
• DE 1111952 [0006]

Claims (11)

Locking device ( 1 ) for synchronizations, with an axially fixed in a shaft and with this rotatably connected synchronizer body ( 2 ), wherein the synchronous body ( 2 ) radially outer teeth ( 4 ), and with a rotatably mounted in the shaft loose wheel ( 5 ), the radially outer teeth ( 6 ), as well as with a trained as a ring shift sleeve ( 7 ), which radially an internal toothing ( 8th ), which with the external toothing ( 4 ) of the synchronizer body ( 2 ), wherein the sliding sleeve ( 7 ) in a first end position out of engagement with the external toothing ( 6 ) of the loose wheel ( 5 ) and in a second end position in engagement with the external toothing ( 6 ) of the idler gear ( 5 ), wherein in the synchronous body ( 2 ) a synchronizer ring ( 9 ) is mounted axially displaceable and the synchronizer ring ( 9 ) a friction surface ( 10 ) for cooperation with a friction surface ( 11 ) of the idler gear ( 5 ), further comprising a locking catch ( 12 ) for the sliding sleeve ( 7 ), wherein the locking catch ( 12 ) at least one spring element ( 13 ), which in a locking position form-fitting manner with the sliding sleeve ( 7 ), characterized in that the synchronizer ring ( 9 ) is designed such that it due to a torque applied during the synchronization process, a radially outwardly directed force on the spring element ( 13 ) in support of the spring force of the spring element ( 13 ) exercises. Locking device according to claim 1, characterized in that the respective spring element ( 13 ) is designed as an annular spring, which extends almost over a full circle and / or over a pitch circle. Locking device according to claim 1 or 2, characterized in that a spring element ( 13 ) is provided, or three spring elements ( 13 ) are provided, in particular for a plurality of spring elements ( 13 ) are formed identically. Locking device according to one of claims 1 to 3, characterized in that the respective spring element ( 13 ) an arc section ( 14 ) and, with the arc section ( 14 ) connected in the region of its opposite ends, radially inwardly directed hook portions ( 15 . 16 ) having. Locking device according to claim 4, characterized in that the two hook sections ( 15 . 16 ) of the respective spring element ( 13 ) in the circumferential direction of the synchronizer body ( 2 ) are arranged displaceably limited and in recesses ( 17 . 18 ) of the synchronizer body ( 2 ) intervene. Locking device according to one of claims 1 to 5, characterized in that the synchronizer ring ( 9 ) and the synchronous body ( 2 ) or the synchronizer ring ( 9 ) and the sliding sleeve ( 7 ) at least one stop ( 19 . 24 ; 19 . 27 ), wherein one of these attacks associated spring element ( 13 ) in a relative rotation of synchronizer body ( 2 ) and synchronizer ring ( 9 ) between the attacks ( 19 . 24 ; 19 . 27 ) is spread radially outward. Locking device according to one of claims 1 to 6, characterized in that the respective spring element ( 13 ), axially limited on both sides, axially with respect to the synchronizer body ( 2 ) is displaceable. Locking device according to claim 7, characterized in that the respective spring element ( 13 ) the synchronizer ring ( 9 ), wherein, in the function of the detent lock, by means of the respective axially displaceable spring element ( 13 ) a synchronization force axially on the synchronizer ring ( 9 ) is transferable. Locking device according to one of claims 1 to 8, characterized in that the sliding sleeve ( 7 ) radially inside a groove ( 21 ) for receiving the associated spring element ( 13 ) having. Locking device according to one of claims 1 to 9, characterized in that the synchronizer ring ( 9 ) a radially outwardly directed ramp ( 28 ), wherein in a relative rotation of synchronizer ring ( 9 ) and the ramp ( 28 ) associated spring element ( 13 ) the spring element ( 13 ) in a central area by means of the ramp ( 28 ) is spread radially outward. Locking device according to one of claims 1 to 10, characterized in that the respective spring element ( 13 ) is designed as a wire spring or stamped part.

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