DE10024352A1 - Shift device for vehicle gearing has shift shaft held in axial neutral position through coil compression spring supported through friction-reducing intermediate elements - Google Patents

Abstract

The shift device has a shift shaft (2) held in an axial neutral position through at least one coil compression spring (6) which is supported on the shaft and/or bearing of same through intermediate elements (12, 13) made of a friction-reducing material such as plastics. One coil compression spring can be mounted at each end of the shift shaft.

Description

The invention relates to a switching device for Wechselge drives, especially for motor vehicles, with an opening opening in the gearbox cover, on the one Shift shaft is rotatably and axially displaceable, the shift shaft via at least one screw pressure which is kept in an axial neutral position.

A switching device of the type mentioned is both from the EP 0 394 556 B1 and DE 44 43 523 C1 are known. The Switching device can as a unit to a change gear be set up and has the purpose of operating a Gear shift lever by the driver in the appropriate setting implement gear clutches in the transmission. To the sem purpose the switching device has two connections for two cables on which the position of the gear shift lever is transmitted. One of the connections does this a radial adjustment of a substantially cylindrical Switching shaft, the other connection an axial displacement the control shaft. By one arranged on the selector shaft This allows shift fingers to have corresponding shift rods which are the desired gear clutches engage in the gearbox.  

Regarding its axial position, the selector shaft is over Prestressed helical compression springs in a neutral position. This happens in DE 44 43 523 C1, one at each end the shift shaft arranged helical compression spring, while the Springs in EP 0 394 556 B1 at one end of the selector shaft are arranged concentrically. Because the screws compression springs on the one hand on the selector shaft and on the other the bearing of the selector shaft, they are supported by the Twisted rotary movement between selector shaft and bearing. Here by generating disruptive reaction forces from the springs.

Against this background, it was the task of the present inventor dung, a switching device of the type mentioned kind of improve that trouble-free radial adjustment the shift shaft is possible.

This object is achieved by the Merk specified in claim 1 times solved. Advantageous configurations are in the sub claims specified.

Accordingly, the invention provides a switching device for a change gearbox, particularly in a motor vehicle can be arranged with an opening in the gearbox housing-closing cover on which a selector shaft rotates and is arranged axially displaceable, the shift shaft via at least one helical compression spring in an axial Neutral position is maintained. The switching device is thereby characterized that the helical compression spring over intermediate elements made of friction-reducing material, preferably made of Plastic, on the control shaft and / or on the bearing of Shift shaft is supported. By inserting the friction reducing intermediate elements can be a radial relative movement  between the helical compression spring on the one hand and the switch shaft and / or the bearing of the control shaft on the other hand instead Find. The helical compression spring is therefore no longer of Rotational movement of the selector shaft carried and twisted, see above accordingly, that it does not exert any interference. The Intermediate element can in particular the shape of a plate, egg Nes ring, a cylinder or a bushing. Be preferred materials are polyethylene, polypropylene, polyvi nyl chloride (PVC) and / or Teflon.

According to a preferred embodiment of the invention is on A helical compression spring is arranged at each end of the selector shaft net, which in the manner according to the invention has a friction reducing intermediate element is supported. Through two screws can compress in opposite axial directions the shift shaft are exercised, so that this in a defi neutral position, which is usually between the third and fourth gear is held. Divided by two different coil springs, it is particularly possible counter forces of different sizes for movement in Direction of the first and second gear or in Direction of fifth gear and reverse gear to realisie ren.

The switching device can also have an inner shift gate se for guiding a backdrop arranged on the selector shaft pin, a locking bracket for locking unselected Shift rods, and a locking device for setting the Ra Have dial positions of the control shaft. With such an a defined movement of the selector shaft in the desired positions and a stabilization of these Positions possible.  

According to a preferred embodiment of the invention, min at least one of the ends of the selector shaft has a shoulder sen, this end pot-like from a friction-reducing Jack is surrounded, the switching shaft by a through break at the bottom of the socket and the edge the opening on the shoulder of the selector shaft. Furthermore, the helical compression spring is supported on the one hand End of the control shaft and on the other hand at the socket and thus biases the bushing against the shoulder of the selector shaft, where the socket depending on the axial position of the Schaltwel le additionally supported on the bearing of the selector shaft. By a such construction is achieved that the screws compression spring then only exerts its axial force on the selector shaft can practice if the socket is on the bearing of the selector shaft supports. This case can be caused by an appropriate dimension be set up so that when the Shift shaft out of the neutral position in a first direction entry. When moving in the opposite direction, on the other hand, the Socket, however, from the bearing of the selector shaft, so that none Change in length of the coil spring and thus no axial Force occurs through the coil spring. With this arrangement thus the effect of the coil spring on a loading Limit the direction of movement of the control shaft.

According to a preferred development of the latter Device can move the bushing Surround the bearing cage of a ball bearing in which the switch shaft is axially displaceably mounted. The socket can in this way can be used to the mentioned camp to guide and secure the cage.

In the following the invention is illustrated with the aid of the figures explained in a playful way. Show it:  

Figure 1 is a top view of a switching device according to the invention.

FIG. 2 shows a top view according to FIG. 1 with a lower sectional plane;

Fig. 3 is a bottom view of the switching device;

Fig. 4 is a side view from the front;

Fig. 5 is a right side view;

Fig. 6 is a left side view and a partial section through the switching device;

Fig. 7 is a left side view of the actuating devices of the switching device;

Fig. 8 is a front view of the axial actuation device.

In the figures, the switching device according to the invention is shown in different views and sections from different directions. To illustrate the views, each figure is accompanied by a symbolic representation of the switching device, which always has the same orientation in space in which the direction of view is indicated by a block arrow and, if appropriate, the sectional plane by a dashed line. The symbolic representation consists of the shift shaft 2 indicated as a cylinder and the axial actuating device 3 and the radial actuating device 5 .

In the view of the switching device according to the invention in Fig. 1, the plate-shaped cover 1 can be seen, which can cover a corresponding opening in the gear housing (not shown) and is screwed to the gear. Perpendicular to the cover 1 extends the substantially zy-cylindrical switch shaft 2 , which is axially displaceable and rotatable with the cover 1 connected via corresponding bearings ver connected. Axial adjustment of the selector shaft 2 can be achieved via the axial actuating device 3 , which has at its end a connection for a cable pull (not shown) coming from the gear shift lever. Furthermore, a radial actuation device 5 (see FIG. 2) is arranged on the cover 1 , which has at one end a connection possibility for another cable pull (not shown) from the gearshift lever and which actuates the cable pull in a rotary movement of the selector shaft 2 implements.

In the plan view of FIG. 1 is a protecting plate 4 can also be seen, which is intended to protect the integrated in the switching device ventilation system against an uncontrolled flow of oil.

In Fig. 3 is a bottom view of the Schaltvorrich device is shown. It can be seen here in particular that the edge of the cover 1 is surrounded by a seal in order to ensure an oil-tight attachment to the transmission housing.

Fig. 4 shows a partial sectional view of the front of the switching device. The exact guidance of the cut is shown in Fig. 2 by the lines AA. The (switching) shaft 2 can be seen , which extends vertically through an opening in the cover 1 . The shaft 2 is axially displaceably movable and rotatable in the opening mentioned in a ball bearing 7 . The upper end of the shaft 2 is seated in a bearing which is coupled to the radial actuation device 5 and can thus force the shaft 2 to rotate about its longitudinal axis.

The upper end region of the shaft 2 is also surrounded by a screw compression spring 6 , which is supported on the one hand indirectly on the cover 1 and on the other hand at the end of the control shaft 2 . The helical compression spring 6 thus exerts an axially upward force on the control shaft 2 due to its pretension.

At the opposite, below the cover 1 end of the control shaft 2 , another helical compression spring 11 is arranged, which is in a similar way on the one hand on a spring plate 12 at the lower end of the Schaltwel le 2 and on the other hand to the rigidly connected to the cover 1 NEN lower Bearing of the control shaft 2 is supported. The last-mentioned support on the bearing of the control shaft 2 takes place via a pot-like socket 13 as an intermediate element. That means that the helical compression spring 11 is supported on the bushing 13 and the bushing is supported with its edge on the bearing of the selector shaft 2 .

The socket 13 surrounds the lower end of the control shaft 2 like a pot and has an opening in its bottom through which the end region of the control shaft 2 is guided. This end region has a smaller radius than the rest of the selector shaft, with a shoulder 14 being formed at the transition between the two radii. On this shoulder 14 , the opening of the socket 13 is seated, since the radius of the opening is smaller than the other radius of the switching shaft 2 .

The support of the socket 13 on the shoulder 14 of the switching shaft 2 has the result that the socket 13 is taken along with an axial downward movement of the switching shaft 2 . The book se 13 in turn takes the spring 11 , and the support from the socket 13 on the bearing of the selector shaft 2 is raised. This means that with a downward movement of the shift shaft 2 from the neutral position shown in FIG. 4 (between third and fourth gear), the length of the helical compression spring 11 is not changed, since the helical compression spring on the one hand on the spring plate 12 connected to the shift shaft 2 and on the other hand is seated on the bushing 13, which is also connected to the helical compression spring 2 in this state. During the downward movement, the spring 11 therefore does not exert any axial pressure on the selector shaft 2 . In this case, an axial pressure is rather generated solely by the upper helical compression spring 6 .

The situation is different, however, when the selector shaft 2 moves upward from the neutral position shown in FIG. 4. In this case, the socket 13 sits on the bearing of the Schaltwel le 2 , so that it can not follow the upward movement of the shift shaft 2 . The helical compression spring 11 is thus fixed with its lower end via the spring plate 12 to the Schaltwel le 2 and with its upper end via the socket 13 on the bearing of the selector shaft, so that it is compressed during the upward movement of the selector shaft 2 .

In the manner described, it is possible to exert the axial force effect of the helical compression spring 11 only during the upward movement of the selector shaft 2 from the neutral position, so that overall the two directions of movement out of the neutral position (towards the first and second gear or towards the fifth gear and Reverse gear) under different opposing forces.

The bushing 13 , via which the helical compression spring 11 is supported on the bearing of the selector shaft 2 , consists of a friction-reducing plastic such as PVC. In the same way, the spring plate 12 is made of a friction-reducing plastic. A relative movement between the helical compression spring 11 and the bearing of the selector shaft 2 or the selector shaft 2 itself is made possible by the material selections mentioned. In particular, this allows the control shaft 2 to rotate about its longitudinal axis without the compression spring 11 being entrained or twisted. Accordingly, the helical compression spring 11 can also exert no undesirable and disruptive tor sion forces during the rotation of the selector shaft 2 .

The spring plate 12 also prevents the helical compression spring 11 from detaching from the lower end of the control shaft 2 and falling into the transmission, for example. In order to prevent such a destructive fall of the helical compression spring 11 for the transmission, the spring plate 12 is preferably designed so that its disassembly is only possible by destroying the spring plate.

In Fig. 4, a guide pin 9 can also be seen , which is guided in an elongated hole of the locking yoke 8 . The locking yoke 8 is firmly connected to the cover 1 , while the guide pin 9 with locking brackets 18 ( Fig. 6) is connected, which can move axially with the control shaft 2 . Although such an axial movement is permitted by the locking bracket link 8 , rotation together with the selector shaft 2 is prevented.

In Fig. 5 is a side view from the right of the switching device is shown. The exact cut corresponds to the line CC of FIG. 2. Above the lid 1 shown in section Darge can be seen how the axial actuation device 3 engages laterally on the upper bearing of the control shaft 2 , the axial movement is shown by a double arrow. Below the cover 1 , the side view shows the shift gate 15 , in which the pen sensen 16 is performed. The shift link 15 is firmly connected to the cover 1 , while the link pin 16 is fixed to the shift shaft 2 . Through the shift gate 15 and the link pin 16 , the axial and radial movements executable by the shift shaft 2 are limited such that a total of six positions (five forward gears and one reverse gear) can be assumed. A locking cam 17 ensures that it is not possible to shift directly from fifth gear to reverse gear.

Fig. 6 shows in the lower part of the switching device in a side view from the left. Above this side view, a section through the illustration along the line BB is shown.

The side view shows the shift finger 19 permanently connected to the selector shaft 2 , through which the actual shifting of shift rods (not shown) of the transmission takes place. By an axial displacement of the Schaltfin gers 19 , a shift rod to be actuated can be selected, which can then be moved in one direction or the other by rotation of the selector shaft 2 and a corresponding radial movement of the Schaltfin gers 19 by one of two gears to insert.

A locking bracket 18 is arranged above and below the shift finger 19 , which is firmly connected to the guide pin 9 ( FIG. 4) on the opposite side of the shift shaft. The locking bracket 18 can thus join the axial movement of the selector shaft Be, but not the rotation. They serve to fix unselected shift rods of the gearbox bes in their rest position.

In the upper sectional view of FIG. 6, a locking device 20 can be seen , through which radial positions of the shift shaft 2 are fixed in certain positions. The locking device is realized by a sector connected to the selector shaft 2 with an undulating outer contour and a ball spring-mounted in the guide pin 9 . In the rest positions, the ball presses into the valleys of the undulating circumferential line.

FIGS. 7 and 8 show in various sections separately Axialbetätigungsvorrichtung 3 and the radial actuation device 5, wherein the cutting guide in Fig. 7 the line EE of FIG. 1 and the cut in Fig. 8, the line DD of FIG. 2 corresponds.

Reference list

1

cover

2

Selector shaft

3rd

Axial actuator

4

Protective plate

5

Radial actuator

6

Helical compression spring

7

ball-bearing

8th

Barrier bracket backdrop

9

Guide pin

10th

ball-bearing

11

Helical compression spring

12th

Spring plate

13

Rifle

14

shoulder

15

Shifting gate

16

Setting pin

17th

Locking cam

18th

Barrier bracket

19th

Shift finger

20th

Locking device

Claims (5)

1. Switching device for change gearbox, in particular for motor vehicles, with a cover ( 1 ) which closes an opening in the transmission housing and on which a shift shaft ( 2 ) is rotatably and axially displaceably arranged, the shift shaft being provided with at least one compression spring ( 6 , 11 ) is held in an axial neutral position, characterized in that the helical compression spring ( 6 ) is supported on the switching shaft ( 2 ) and / or the bearing of the switching shaft via intermediate elements ( 12 , 13 ) made of friction-reducing material, preferably made of plastic. 2. Switching device according to claim 1, characterized in that a helical compression spring ( 6 , 11 ) is arranged at each end of the switching shaft ( 2 ). 3. Switching device according to one of claims 1 or 2, characterized in that it has a shift gate ( 15 ) for guiding a on the shift shaft ( 2 ) arranged Ku lissenstiftes ( 16 ), a locking bracket ( 18 ) for locking unselected shift rods and / or has a Rastein direction ( 20 ) for setting the radial positions of the selector shaft. 4. Switching device according to at least one of claims 1 to 3, characterized in that at least one of the ends of the switching shaft ( 2 ) has a shoulder ( 14 ),
that this end is surrounded in a pot-like manner by a friction-reducing bush ( 13 ), the shift shaft passing through an opening in the bottom of the bush and the edge of the opening being supported on the shoulder of the shift shaft,
that the helical compression spring ( 11 ) is supported on the one hand on the end of the selector shaft ( 2 ) and on the other hand on the socket ( 13 ) and thus prestresses the socket against the shoulder of the selector shaft,
and that the bushing is supported on the bearing of the selector shaft depending on the axial position of the selector shaft. 5. Switching device according to claim 4, characterized in that the bushing ( 13 ) gives the ver sliding movement bearing cage of a ball bearing ( 10 ) in which the switching shaft ( 2 ) is axially displaceably mounted movably.