DE3035045A1 - Synchromesh gear-changing mechanism - has axial clearance between dog teeth unaffected by wear of synchromesh components - Google Patents

Abstract

The synchromesh gear changing mechanism has one or more gears in constant mesh with the input power train, and an output shaft positively synchronised with the gear and coupled to it by a dog clutch. The synchromesh components (43,53) are so designed that as wear takes place they have no effect on the axial clearance between the two sets of dog teeth (41,51) during the synchronisation operation. The first axial engagement pressure, e.g. from a sliding sleeve (3), can be arranged to act directly on the synchromesh components (43,53), while a second and higher pressure initiates dog clutch engagement.

Description

The invention relates to a synchronizing and switching device

direction according to the preamble of claim 1, both mechanically as well as being actuated via a pressure medium and in which the connection of the synchronizing elements with the output shaft either via a synchro-hub or via an internal one Shift sleeve can be done.

Such, as well as differently constructed synchronizing and switching devices are well known and have the disadvantage that the wear and tear of the synchronizing elements - Synchronizing ring with cone or synchronizing lamellae - through continuous reduction the distance between the locking toothing and the switching toothing in the gearwheel in the case of locking synchronizers or of the coupling toothing and the switching toothing in the case of simple synchronizations in an unfavorable way due to ratcheting noises, combined with damage to the gear teeth, make noticeable and in an advanced state all synchronization to question.

An example of a Ronus synchronizing and switching device with locking effect is from DE-PS 926 468 and for a lamella synchronizing and switching device from US Pat. No. 615,325 known. Works in both versions The wear of the synchronizing elements also affects the frontal distance the switching and locking or the coupling teeth, so that the already described Disadvantages occur.

It is therefore the object of the invention, in a synchronizing and Switching device according to the preamble of claim 1 to the deficiencies indicated fix with a simple design of the synchronizing and switching device at the same time.

This task is with the characterizing features of claim 1 fulfilled.

While with the known synchronizing and switching devices the friction surface of the synchronizing elements between a synchronizing or Lock ring and the gear to be switched are arranged and any wear on the friction surfaces has the effect of reducing the distance between the end faces and the gear teeth, the arrangement according to the invention guarantees a completely constant distance between the end faces this gearing. The wear of the friction elements only increases the distance between the friction surfaces when the synchronizing and shifting device is not actuated, so that the start of synchronization is slightly delayed.

If the design is made according to claim 3, that is, with friction disks as synchronization elements, high pressures can be used for synchronization, which lead to short switching times.

This arrangement is particularly suitable for a synchronizing and switching device which is switched directly with pressure medium, as claimed in claim 4 is possible.

As a result of the pressure build-up, which is always uniform, can locking means on the synchronizing device can be dispensed with.

It is of course also possible to actuate the sliding sleeve to be provided with pressure medium, while the rest of the structure is carried out according to claim 3.

In the following, further details of the invention are given by means of exemplary embodiments and explained with reference to drawings.

1 shows a section through a synchronizing and switching device, which is operated with a shift sleeve.

2 shows a section through a synchronizing and switching device, which is hydraulically applied.

3 shows the arrangement of the switching teeth before and during synchronization.

Fig. 4 shows the arrangement of the switching teeth according to the form-fitting Coupling.

In Fig. 1 is on an output shaft 1 with driving teeth 11 a synchronizer body 2 rotatably and axially fixedly connected to this output shaft, while at least one gear 4, which is connected to the drive train via a countershaft is permanently in engagement, rotatable on this output shaft, but not axially displaceable, is arranged. This gear 4 has a switching toothing 41, the end face beveled 411 or rounded, as well as a device 42 for receiving the outer lamellae 43. With the synchronizing body 2 is non-rotatably via a switching toothing 21, however axially displaceable via a coupling toothing 51 an inner disk carrier 5 with a rigid end lamella 52, which also carries the inner lamellae 53. The axial Fixing between disk carrier 5 and synchronizer body 2 takes place via a latching device 6, - e.g. B. a ball 61, which under the pressure of a spring 62 in a locking recess 54 engages the inner disk carrier 5. With the inner disk carrier 5 5 is a Sliding sleeve 3, e.g. B. with a grooved pin 31, rotatably connected, this sliding sleeve with a pressure piston 32 arranged thereon, the disk pack - outer disks 43, Inner lamellae 53 - to the end lamella 52 can compress. The axial displacement between sliding sleeve 3 and inner plate carrier 5 is in spite of the grooved pin 31 made possible because this is in a slot-like recess 55 of the inner disc carrier 5 intervenes.

The embodiment according to FIG. 2 corresponds in principle to that already described Embodiment according to Fig. 1 with the difference that the actuation of the synchronization as well as the circuit takes place directly with a pressure medium.

For this purpose, the inner disk carrier 5 'with a stationary one has priority with a spring ring 56 held end lamella 57 on the facing away from the gear 4 ' Side. The end lamella 74, which is arranged on the side facing the gearwheel 4 ' has its own disk carrier 7, which is located between the synchronizer body 2 'and the inner disk carrier 5 'is arranged so that a first pressure chamber 8 is between the inner disc carrier 5 'and the end disk carrier 7 and a second pressure space 9 between the end disk carrier 7 and synchronizer body 2 'results.

Between the inner disk carrier 5 'and the end disk carrier 7 is in a radial direction Direction of an entrainment device, e.g. B. driving teeth 72, for the non-rotatable Coupling of these two components and in the axial direction a spring, for. Legs Compression spring 73, arranged to open the disk pack 43 ', 53'. A connection 76 from the first pressure chamber 8 to the second pressure chamber 9 is arranged so that the feed of the pressure medium is still possible when the synchronization is completed and the axial displacement of the end disk carrier 7, which also has the coupling teeth 71 carries, has not yet ended.

Fig. 3 shows schematically the gear teeth 21 on the synchronizer 2, the switching teeth 41 on the gear 4 and the coupling teeth 51 on the inner disk carrier 5, the coupling toothing 51 and switching toothing for better tracking after synchronization 41 beveled at the end 411, 511 or rounded. The distance "x" between the end faces of the coupling 51 and switching teeth 41 before and during the synchronization can be kept very small.

In Fig. 4, the completed circuit is also shown schematically, this end position also by locking means in the switching and synchronizing device itself, but can also be fixed in the shift linkage.

If the sliding sleeve 3 is used to initiate a shift to the right moves, the pressure piston 32 causes the synchronization. The inner disc carrier 5 is held in the position shown by a coordinated latching device 6. the relative movement of the sliding sleeve 3 with respect to the inner disk carrier 5 is by a slot-like recess 55 into which the grooved pin 31 protrudes. The synchronization duration can be defined as a function of time, pressure and, if necessary, also distance will. After synchronism, the pressure is increased and the sliding sleeve 3 is overpressed the locking device 6, so that the coupling teeth 51 of the inner disk carrier positive connection of the synchronizer body 2 and gear 4th via the shift teeth 21 and 41 causes. The tracking is done by frontal Bevels 511, 411 both on the coupling teeth of the inner disk carrier as also facilitated on the switching teeth of the gear.

The end position can be achieved by locking means as well as by depositing the gear teeth are effected.

Switching to idle causes the sliding sleeve 3 and the Grooved pin 31 ensures that the inner disk carrier is returned to the neutral position, which in turn is secured by the latching device 6.

If a circuit with pressure medium is initiated according to Fig. 2, the first pressure chamber 8 is acted upon by a feed channel 10. About the frontal pressure surface 59 is the inner disk carrier 5 'in the direction of the gear wheel is closed and the end lamella 57 presses on the lamella pack Synchronization.

The end lamella 74 is supported via the pressure surface 75 of the End plate carrier 7.

A second pressure chamber is also delayed via a connecting channel 76 9 acted upon as a function of pressure or time and thus the latching device according to synchronism 6 'overcome and the positive coupling via the gear shift device 21 ', 71, 41' causes.

After the pressure medium supply channel 10 has been vented, the return can both the end disk carrier 7 and the inner disk carrier 5 ', e.g. B. over Springs 44 and 73, but also acted upon by suitably arranged pressure means Printing areas.

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Claims (4)

Synchronizing and switching device P a t e n t a n s p r ü c h e e Synchronizing and switching device with at least one with the drive train Always in mesh gear and an output shaft, which via synchronizing elements non-positively brings about a speed adjustment and via gear clutches positively connects the gear to the output shaft to transmit the drive force, thereby characterized in that the synchronizing elements (43, 53) are arranged so that they in the event of wear no influence on the axial distance (x) from the coupling toothing (51) to the gear teeth (41) during the synchronization process. 2. Synchronizing and switching device according to claim 1, characterized characterized in that the first axial switching pressure, e.g. B. a sliding sleeve (3), acts directly on the synchronizing elements (43, 53) and only a second, higher one Switching pressure initiates the axial movement of the coupling toothing (51) and the positive locking Brings about coupling. 3. Synchronizing and switching device according to claim 1 or 2, d a d u r c h g e k e n n n z e i c h n e t that the synchronizing elements slats (43, 53) on the one hand on the gear to be switched (4) and on the other hand on a plate carrier (5) are attached and that these lamellas are non-rotatable, but axially displaceable, both with a synchronizer (2) and with a sliding sleeve (3), which at the same time is designed as a pressure piston (32) for the disk pack and that the Lamellae (53) on the inner lamella carrier (5) move axially with the latter jam and the inner disk carrier carries the coupling teeth (51) and in one axial direction on the stop and in the other direction by springs or a Latching device (6) is held. 4. Synchronizing and switching device according to claim 1 or 2, characterized characterized in that the synchronizing elements are slats (43 ', 53') and once are attached to the gear wheel (4 ') and on the other hand to an inner disk carrier (5') and that this inner disk carrier is still on the side facing away from the gearwheel (4 ') a stationary end lamella (57) carries that the end lamella facing the gear (4 ') (74) has its own end plate carrier (7) on which the coupling toothing (71) is arranged and that in the axial direction between this inner <5 ') and end disk carrier (7) a first pressure chamber (8) is arranged in such a way that the inner disc carrier moves when the pressure is built up in the direction of the gearwheel (4 '), while the support of the lamellae is on the end lamella (74) which is held as a result of the pressure chamber arrangement that the pressure build-up in a second pressure chamber (9) between the end plate carrier (7) and synchronizing body (2 ') is arranged, the positive coupling between the gear (4 ') and synchronizer body (2') and that a latching device (6 ') between Synchronizer body (2 ') and end disk carrier (7) a driving device (72) and in the axial direction a spring (73) between this and the inner disk carrier (5 ') is arranged.