DE2706661A1 - Synchromesh for vehicle gear box - has locking assembly connecting two synchro rings into one axially slidable unit - Google Patents

Abstract

The two adjacent gears are connected by a synchro ring (14) which has toothing (13) on its inner side. Toothing notches (28) are provided in which a set of steel balls (25) loaded by springs, provide a neutral position of the ring when both gears can rotate independently. In this position of the ring an inner tapered ring (33) carried by one of the gears (7) is moved so that the two tapered surfaces become out of contact and no wear due to friction takes place. The angled-down edges (29) of the collar (24) keep the rings out of contact with the respective gears.

Description

Synchronizing device for a motor vehicle

gear change transmission The invention relates to a synchronizing device for a motor vehicle gear change gearbox with one on a gear shaft non-rotatable and axially immovable synchronous body, with one of one Shift operating element axially displaceable shift sleeve for producing a formal connection between the synchro-hub and certain gears of the Gear wheels associated with the transmission, which are rotatably mounted on the transmission shaft are and in mesh with gears held on adjacent transmission shafts stand, with arranged between the synchronizer and the whole gears Synchronizer rings, those with a conical inner contour on a conical outer contour of the associated Gear wheel can be brought to the frictional contact and the stop cams on their circumference have to limit their relative rotational movement with respect to the synchronizer body and with locking pieces arranged in axial grooves of the locking body, the spring-loaded Means for the cancelable transmission of axial forces from the shift sleeve to the synchromesh rings exhibit.

In the previously known synchronizing devices of this type (For example DT-PS 925 443 and 935 768) the locking pieces were used at the same time as stops for the stop cams attached to the circumference of the synchronizer rings. at the synchronizer rings were assigned to these known lusführung after removal of them Transmission gear, that is, after the cancellation of the axial displacement of the shift sleeve conditional positive connection between the synchronizer body and the synchronizer ring adjacent gear wheel, essentially left to its own devices. To those facing each other conical contours, namely the inner contour of the synchronizer rings and the outer contour the constantly drifting gear wheels can then create a sliding contact, which in the long run can lead to considerable wear and tear.

The object of the invention is therefore to provide a To improve synchronization device of the type mentioned and in particular to ensure that the resulting from the grinding of the synohron rings on the gear wheels Wear is largely prevented.

The solution to this problem results according to the invention in that that the locking pieces are designed in such a way that they close the synchronizer rings connect a unit that can be moved together in the axial direction. Through this Training is achieved that when removing a certain gear counterpart by corresponding displacement of the switching actuator together with the Shift sleeve and the locking piece also the synchronizer ring assigned to the respective gear wheel through Axial displacement is brought out of engagement with the outer cone of the gear wheel. Otherwise, by constantly grinding the two conical contour surfaces the resulting wear of the synchronizer ring and the gear wheel becomes significant reduced.

Another feature of the present invention is that the stop cams of the synchronizer rings in the area of the wider in the circumferential direction axial grooves of the synchronizer body are arranged and on the groove boundary walls of the synchronizer body to limit the relative rotational movement of the synchronizer rings come to a stop.

This ensures that the stop of the synchronizer rings during of the synchronization process no longer from the locking pieces but directly from the Much stronger trained synchronizer is added.

Another advantageous embodiment of the invention provides that the Locking pieces have axially extending sheet metal bodies behind the synchronizer body facing away from the faces of the synchronizer rings grip, whereby the synchronizer rings at an axial displacement of the locking pieces against the switch-on direction and thereby their inner cone from the associated outer cone of the gear wheel is pulled down. Finally, it should also be provided that the locking pieces each have a guided in a tubular sleeve ball, which is through a held in a radial bore of the synchronizer spring is loaded and the into a circumferential groove of the sliding sleeve provided with inclined boundary walls intervenes.

An embodiment of the invention is shown in the drawing and is explained in more detail below. The drawing shows a longitudinal section in FIG through the synchronizing device according to the invention and FIG. 2 is a plan view on the unit consisting of locking piece, synchronizer body and synchronizer rings.

In FIG. 1 of the drawing, 1 is a gear housing and with 2 denotes a gear shaft (countershaft) rotatably mounted in the housing. A synchronizing body 3 is mounted on the transmission shaft 2 by means of a spline 4 rotatably held, which is also in the axial direction by a shaft shoulder 5 or is fixed by a locking ring 6. Both sides of the synchronizer 3 are on the transmission shaft 2 each assigned to a gear of the gear change transmission Gear wheels 7 and 8 rotatably mounted by means of needle bearings 9 and 10. These gear wheels are, as is not shown here, in constant mesh with counter gears, which are rigidly attached to an adjacent gear shaft.

The gear wheels 7 and 8 have clutch teeth 11 and 12, their The toothing is formed in the same way as the toothing 13 on the outer circumference of the synchronizer body 3, on which a sliding sleeve 14 with a similar internal toothing by means of a switch actuating element, not shown here, for switching the individual courses is axially displaceable.

Located between the synchronizer body 3 and the gear wheels 7 and 8 there are also synchronizer rings 15 and 16, which have a conical inner contour 17 and 18, respectively, with which they during the synchronization process on a conical outer contour 19 respectively 20 of the gear wheels 7 and 8 come to rest. Also the synchronizer rings 15 and 16 have a toothing 21 or 22, which is that of the clutch teeth 11 and 12 of the gear wheels and the teeth 13 of the synchronizer and the sliding sleeve 14 corresponds.

As can also be seen from the upper part of Figure 1, are about the Perimeter of the synchronizer 3 distributed in axial grooves of the same locking pieces arranged, which consists of a substantially radially arranged guide sleeve 23, one substantially axially extending sheet metal body 24 and one under the force of a compression spring 26th standing ball 25 exist. The compression spring 26 is in radial Bores 27 of the synchronizer body 3 held and presses the ball 25 radially outside in a circumferential groove 28 on the sliding sleeve with sloping boundary walls is provided. The tubular PUhrungshülse 23 and the sheet metal body 24 are rigid connected to one another, while the ball 25 is movably held in the guide sleeve 23 is. The ends 29 of the sheet metal body 24 are each bent radially inward and engage behind an end face 30 or rather facing away from the synchronizer body 3 31 in recesses 35 and 36 of the synchronizer rings 15 and 16. Located in this area stop cams 33 and 34 facing the synchronizer body 3 on the synchronizer rings, which are designed to be narrower in their width than the width of the axial grooves 32 am Synchro-hub. By stopping the stop cams 33 and 34 on the groove boundary walls the axial groove 32 is the relative rotation of the synchronizer rings 15 and 16 with respect to the synchronizer body 3 limited to a predetermined angle, depending on the direction of rotation the cams either hit one or the other groove delimitation wall.

The following is the function and mode of action of the in the drawing synchronizer shown are shown. When inserting a specific Transmission gear, for example the transmission gear assigned to the gear wheel 7, the sliding sleeve 14 must be moved to the left in the drawing until its internal teeth the clutch gear 11 of the gear gear 7 with the external teeth 13 of the synchronizer connects. Since, however, the initial state is the continuously rotating gear wheel 7 has a different speed than the synchronizer body rotating with the gear shaft 2 3, there must first be a synchronization, that is, a synchronism of the one another to be coupled parts. This is done with the help of the synchronizer ring 15, the inner cone 17 of which is in the starting position, that is to say when it is not switched Gear, such a large distance from the outer cone 19 of the gear tooth rsdes 7, that there is no contact. Now the sliding sleeve 14 in the drawing after moved to the left, the force is then transmitted from the sliding sleeve on the synchronizer ring 15 via the evenly arranged on the circumference of the synchronizer body 3 Locking pieces. In this case, an axial force limited in height is applied via the inclined Circumferential groove 28 formed on the sliding sleeve initially on the boundary surfaces compression spring-loaded balls 25 and transferred from these to the PUhrung sleeves 23, which in turn the synchronizer ring 15 assigned to each other until they touch move tones 17 and 19. When the cones 17 and 19 touch the synchronizer ring 15 taken along in the direction of rotation of the gear wheel 7 until its stop cam 33 abut against the boundary walls of the axial groove 32 in the synchronizer body 3. Through this the synchronizer ring 15 is pivoted into its locking starting position in which the Tooth tops of the toothing 13 on the sliding sleeve and the toothing 21 on the synchronizer ring stand in such a specific, mutually associated position that at a Moving the sliding sleeve further while pressing in the compression spring-loaded ball 25 such an axial force is exerted on the synchronizer ring 15 that by frictional Connection of the two associated cones 17 and 19 between the gear wheel 7 and the synchronizer ring 15 synchronism is generated. When this synchronization is established is, the sliding sleeve 14 can be pushed further in the axial direction until it also over the clutch teeth 11 of the gear wheel 7 slides and thus the form-fitting Connection between the gear wheel and the synchronizer body 3 has been established. Of the The corresponding gear is then engaged.

When removing this gear counter by moving back the The sliding sleeve engages towards the end of the compression spring-loaded ball 25 again in the circumferential groove 28 of the sliding sleeve, whereby the locking piece with the sliding sleeve also moves back will. In this case, the synchronizer ring is also shifted back because the bent Ends 29 of the sheet metal body 24 of the locking piece, which are behind the stop cams 33 of the Synohron ring 15 grab the synchronizer ring from the outer cone 19 of the gear wheel 7 and keep your distance from it. A wear and tear through always again subsequent striking and grinding of the up to activation of the assigned transmission gear rotating at different speeds Parts can thus be largely avoided. Another benefit of the Invention proposed synchronizer is that as a result of direct stop of the stop cams of the synchronizer rings on the groove boundary walls of the synchronizer the locking pieces during the synchronization process no longer the need to take over blows occurring in the circumferential direction.

Claims (4)

CLAIMS 0) Synchronizing device for a motor vehicle gear change transmission with one held non-rotatably and axially immovable on a gear shaft Synchronizer body, with one of a shift actuating element axially displaceable Shift sleeve for producing a form-fitting connection between the synchronizer body and gear wheels assigned to certain gears of the transmission, which are on the transmission shaft are rotatably mounted and with gears held on adjacent transmission shafts are in meshing engagement with arranged between the synchronizer and the gear wheels Synchronizer rings that have a conical inner contour on a conical outer contour of the assigned gear wheel can be brought to the frictional contact and the stop cams on their circumference to limit their relative rotational movement have the synchronizer body and arranged with in axial grooves of the synchronizer body Locking pieces, the spring-loaded means for the reversible transmission of axial forces of the shift sleeve aaf have the synchronizer rings, characterized in that the locking pieces (23-26) are designed in such a way that they the synchronizer rings (15, 16) to form a unit that can be moved together in the axial direction. 2. Synchronizing device according to claim 1, characterized in that that the stop lugs (33, 34) of the synchronizer rings (15, 16) in the area of the circumferential direction wider axial grooves (32) of the> synchronizer (3) arranged siRa and to the Slot boundary walls of the synchronizer body to limit the relative rotary movement the synchronizer rings come to a stop. 3. Synchronizing device according to claim 1 or 2, characterized in that that the locking pieces have axially extending sheet metal body (24) with radially inwardly bent ends (29) facing away from behind the synchronizer body (3) Grip the end faces (30, 31) of the synchronizer rings (15, 16). 4. Synchronizing device according to one of claims 1 to 3, characterized characterized in that the locking pieces are each one in a tubular sleeve (23) have guided ball (25), which through a in a radial bore (27) of the Synchronizer body (3) held spring (26) is loaded and in a with oblique Boundary walls engage the provided, circumferential groove (28) of the sliding sleeve (14).