DE10132978B4 - Synchronizer for a planetary gear - Google Patents

Abstract

synchronization (42) for a planetary gear (4) arranged with one on a drive shaft (8) Sun wheel (6), with planet wheels (20), which at least temporarily mesh with the sun gear (6) and on a planet carrier (16) are arranged and with an output shaft (38) connected to the planet carrier (16) is connectable, characterized in that the drive shaft (8) a first spring-loaded plate pack (46) is assigned, the comprises at least one lamella (50) with a catching toothing (54), that the planet carrier (16) a second spring-loaded plate pack (60) is assigned, which comprises at least one lamella (64) with a catching toothing (68), and that an axially displaceable sliding sleeve (34) has a first switching position in which a torque transmission between the planet carrier (16) and the output shaft (38) to form a reduction ratios is formed, and the sliding sleeve (34) has a second switching position in which a direct connection of the drive shaft (8) with the output shaft (38) is adjustable for direct transmission of torque, and that the sliding sleeve ...

Description

The The invention relates to a planetary gear with a synchronizer according to the preamble of claim 1.

From the DE 19506987 A1 is a synchronizer with a disc pack has become known in which for both switchable sides of the synchronizer together a single disc pack is needed. The disk set is provided between two components of a sliding sleeve, that it is axially offset by a spring element, such as a plate spring, permanently under a bias. The synchronization has a coupling toothing, which is spring-loaded with respect to the gear to be switched. For this purpose, coupling bodies are provided, for example, between the synchronizer body and the gear, for example in the form of clutch discs, which can engage with an internal toothing in a corresponding external toothing on the gear or on the gear shaft. The coupling body are limited axially displaceable, on the one hand form the synchronizer body and on the other hand arranged between the coupling body and gear spring means, such as a wave spring, axial limit. The coupling body is axially displaced maximally so far in the direction of the gear until the wave spring wiping flat coupling body and gear is. The coupling body have the lowest possible mass. The bias can also be achieved by a spring device resulting from the design of the friction plates. Thus, friction plates can be used, which are in the form of corrugated springs in the unstressed state and are compressed during installation such that the compressed plate set has flat or nearly flat lamellae, wherein the bias results from the back striving in the initial shape. By form and material selection can be taken finely dosed influence on the bias. This bias causes the disk pack in the unswitched state of the synchronization without friction of the individual disks together with each other rotates together with the synchronizer body and the transmission shaft on which the synchronization is arranged.

The Sliding sleeve has a radially outer catching teeth on, which corresponds with catch teeth on the respective gears to be switched. The catching teeth on the gears can be provided on separate components, compared to the Gear can be sprung and with the gears for example about a toothing are connected. By the arrangement of the catch teeth in separate components on the gears, the mass of the gear teeth can be low being held. The sliding sleeve also has a radially inner Clutch toothing on. At this point, the coupling teeth in the axial direction, a smaller width than in the region of Fangverzahnung, so that the catch teeth on the sliding sleeve with the catch teeth on the gears earlier can contact as the coupling teeth of sliding sleeve and coupling body. The content of the application should be included here in full. The sync is also for Planetary gear used, needed but still a big one Space.

From the WO 90/10806 is a synchronization for a planetary gear known, as it is commonly used as a group transmission in two-group transmissions or three-group transmissions of motor vehicles, especially commercial vehicles. In this type planetary gear in a torque-transmitting switching position, the teeth do not run into each other, but run as a then contiguous component. In this position, it can come to fretting in the teeth.

Of the Invention is based on the object, a small-scale synchronization for a Show planetary gears.

The Task is solved by a synchronization with the features of claim 1. embodiments are the subject of dependent claims.

According to the invention, a synchronizer is proposed for a planetary gear with a arranged on a drive shaft sun gear, with planetary gears that mesh with the sun at least temporarily and which are arranged on a planet carrier and an output shaft which is connectable to the planet carrier. The drive shaft is associated with a first spring-loaded Lammellenpaket comprising at least one blade with a catch toothing. The planet carrier is associated with a second spring-loaded plate pack, which also comprises at least one blade with a catch toothing. An axially displaceable sliding sleeve has a first switching position, in which a torque transmission between the planet carrier and the output shaft is formed to form a reduction ratios, and the sliding sleeve has a second switching position, in which a direct connection of the drive shaft with the output shaft is adjustable for direct Transmission of the torque. The sliding sleeve also has a third switching position, in which a toothing of the sliding sleeve for forming a synchronous torque engages simultaneously in the catch teeth of the first disk set and in the catch teeth of the second disk set. In an advantage adhere configuration has a disk set two slats with a friction coating and an intermediate slat, which has the catch teeth. Preferably, the slats have paper coverings. An advantageous embodiment shows the lamella, which carries the catch teeth formed in the form of a corrugated spring, whereby the lamellae are sprung. In one embodiment, the springing is generated by a corrugated spring, in another embodiment by a coil spring. Another embodiment shows the disk pack sprung by a diaphragm spring.

The The invention will be explained in more detail with reference to a drawing.

It demonstrate:

1 a planetary gear with synchronizer in direct connection;

2 the planetary gearbox after 1 in synchronization position and

3 the planetary gear in stocky compound.

The 1 shows in a gearbox 2 a planetary gear 4 with a sun wheel 6 that with a drive shaft 8th of the planetary gear 4 about a gearing 10 rotatably connected. The drive shaft 8th is in the gearbox 2 in a warehouse 12 rotatably mounted. On a warehouse 14 rotatably mounted is a planet carrier 16 , on the planet's axis 18 several planet wheels 20 are rotatably mounted, of which a planetary gear is shown here. The planet wheel 20 runs with his teeth 22 on the one hand in the internal toothing 28 of the ring gear 24 and on the other hand on the external teeth 26 of the sun wheel 6 , The ring gear 24 is fixed in the gearbox 2 arranged. The planet carrier 16 has an internal toothing 30 in which an external toothing 32 a sliding sleeve 34 can intervene. The sliding sleeve 34 is about a gearing 36 rotatably with the output shaft 38 connected and in the teeth 36 axially along the axis of rotation 40 on the output shaft 38 displaceable. The sliding sleeve can 34 different switching positions of the synchronizer 42 of which in the 1 a switching position is shown. The output shaft 38 is in the gearbox 2 in a warehouse 44 rotatably mounted.

As part of the synchronizer 42 is in the sun wheel 6 a disc pack 46 arranged, this one from three slats 48 . 50 and 52 consists. The slats 48 and 52 are rotatably connected with the Sonnerad via a gearing 6 connected while the slat 50 inside the sun wheel 6 around the axis of rotation 40 can twist. The slat 50 has a catch toothing 54 on, in which the external teeth 32 the sliding sleeve 34 can intervene. The slat package 46 becomes inside the sun wheel 6 axially by a circlip 56 held, against which the disk pack 46 from a circumferentially distributed number of coil springs 58 is pressed, of which here is a coil spring 58 is shown. This is the slat package 46 under a constant bias. The entire disc pack 46 rotates with each component and has its speed.

In the same way is in the planet carrier 16 a disc pack 60 arranged, this one from three slats 62 . 64 and 66 consists. The slats 62 and 66 are rotatably connected with the Sonnerad via a gearing 6 connected while the slat 64 inside the sun wheel 6 around the axis of rotation 40 can twist. The slat 64 has a catch toothing 68 on, in which the external teeth 32 the sliding sleeve 34 can intervene. The slat package 60 becomes within the planet carrier 16 axially by a circlip 70 held, against which the disk pack 60 from a circumferentially distributed number of coil springs 72 is pressed, of which here is a coil spring 72 is shown. This is also the slat package 60 under a constant bias and also the entire disc pack 60 turns with the planet carrier 16 and reveals its speed.

In the 1 interlocks the teeth 36 in the external teeth 74 the drive shaft 8th and thereby connects the drive shaft 8th and the output shaft 38 directly. The torque is directly over the sliding sleeve 34 transmitted and does not have sun gear 6 , Planetary gears 20 and planet carrier 16 from the drive shaft 8th on the output shaft 38 be transmitted. This is the risk of fretting corrosion in the gears of sun gear 6 and planet wheels 20 reduced or avoided.

Should now from this switching position of the direct connection of the waves through the sliding sleeve 34 a reduction by the planetary gear 4 be achieved, so the sliding sleeve 34 to be moved to the right in the drawing plane. This leaves the gearing 36 on the sliding sleeve 34 the external toothing 74 on the drive shaft 8th while the external teeth 32 on the sliding sleeve 34 in the catching teeth 54 of the disk pack 46 remains.

Subsequently, the external teeth are detected 32 the catching teeth 68 on the disk pack 60 , At first the slats slip 62 . 64 and 66 past each other and generate a friction torque in the spring 72 compressed lamellae package 60 until the planet carrier 16 and the sun wheel 6 Do not twist relative to each other. Then the sliding sleeve 34 moved further until the external teeth 32 in the internal toothing 30 at the planet carrier 16 intervenes.

This switch position is in the 3 shown. The torque is in this switching position of the drive shaft 8th on the sun wheel 6 and about the planet wheels 20 and the planet carrier 16 on the output shaft 38 transferred to the formation of a reduction. As a result, a small-sized synchronization is achieved for a planetary gear, which also allows a direct transmission of torque between the drive shaft and output shaft.

2

gearbox

4

planetary gear

6

sun

8th

drive shaft

10

gearing

12

camp

14

camp

16

planet carrier

18

planetary axle

20

planet

22

gearing

24

ring gear

26

external teeth

28

internal gearing

30

internal gearing

32

external teeth

34

sliding sleeve

36

gearing

38

output shaft

40

axis of rotation

42

synchronizer

44

camp

46

disk pack

48

lamella

50

lamella

52

lamella

54

gripping teeth

56

circlip

58

spiral spring

60

disk pack

62

lamella

64

lamella

66

lamella

68

gripping teeth

70

circlip

72

spiral spring

74

external teeth

Claims (7)

Sync ( 42 ) for a planetary gear ( 4 ) with one on a drive shaft ( 8th ) arranged sun gear ( 6 ), with planet wheels ( 20 ) with the sun gear ( 6 ) at least intermittently and on a planet carrier ( 16 ) are arranged and with an output shaft ( 38 ) connected to the planetary carrier ( 16 ) is connectable, characterized in that the drive shaft ( 8th ) a first spring-loaded plate pack ( 46 ), the at least one lamella ( 50 ) with a toothing ( 54 ) that the planet carrier ( 16 ) a second spring-loaded disk pack ( 60 ), the at least one lamella ( 64 ) with a toothing ( 68 ), and in that an axially displaceable sliding sleeve ( 34 ) has a first switching position, in which a torque transmission between the planet carrier ( 16 ) and the output shaft ( 38 ) is formed to form a reduction ratios, and the sliding sleeve ( 34 ) has a second switching position, in which a direct connection of the drive shaft ( 8th ) with the output shaft ( 38 ) is adjustable for direct transmission of torque, and that the sliding sleeve ( 34 ) has a third switching position in which a toothing ( 32 ) of the sliding sleeve ( 34 ) to form a synchronous moment at the same time in the Fangverzahnung ( 54 ) of the first disk pack ( 46 ) and in the toothing ( 68 ) of the second disk pack ( 60 ) intervenes. Sync ( 42 ) for a planetary gear ( 4 ) according to claim 1, characterized in that the disk pack ( 46 . 60 ) two slats ( 48 . 52 . 62 . 66 ) with a friction coating and an intermediate blade ( 50 . 64 ), the catching teeth ( 54 . 68 ) having. Sync ( 42 ) for a planetary gear ( 4 ) according to claim 1 or 2, characterized in that the lamellae ( 48 . 50 . 52 . 62 . 64 . 66 ) Have paper pads. Sync ( 42 ) for a planetary gear ( 4 ) according to one of claims 1 to 3, characterized in that the lamella ( 50 . 64 ), the catching teeth ( 54 . 68 ), is in the form of a corrugated spring and thus the disk set ( 46 . 60 ) springs. Sync ( 42 ) for a planetary gear ( 4 ) according to one of claims 1 to 4, characterized in that the disk pack ( 46 . 60 ) by coil springs ( 58 . 72 ) is sprung. Sync ( 42 ) for a planetary gear ( 4 ) according to one of claims 1 to 4, characterized in that the disk pack ( 46 . 60 ) is spring-loaded by a corrugated spring. Sync ( 42 ) for a planetary gear ( 4 ) according to one of claims 1 to 5, characterized in that the disk pack ( 46 . 60 ) is spring-loaded by a diaphragm spring.