DE3237676A1 - Spring energy store - Google Patents

Abstract

The invention relates to a double-acting spring energy store with two functionally independent storage springs for a switching device for the torsional coupling and decoupling of two rotating components provided with toothing or the like, in particular for connecting and disconnecting a differential lock or a final drive of a motor vehicle, in which switching device a sliding sleeve or the like is engaged and disengaged by swivelling an actuating lever with the interposition of the spring energy store, of a force transmission member transmitting tensile and compressive forces and of a lever arrangement. When the actuating lever is swivelled in one switching direction, only one storage spring is tensioned and, when the actuating lever is swivelled in the other switching direction, only the other storage spring is tensioned, while the other storage spring in each case is deflected simultaneously but without tension, with the result that, during all the switching actuations, only one spring is operative in each case and no return springs or the like have to be overcome. <IMAGE>

Description

Spring storage device

The invention relates to a spring storage device of the im The preamble of claim 1 referred to in Art.

Spring storage devices of this type are used, for example, in motor vehicles with permanent all-wheel drive, e.g. B. the Audi Quattro, used to a differential lock to turn on. In these known arrangements there is the spring storage device from a single storage spring in the form of a compression coil spring.

This is mounted on the free end of a power transmission link and arranged so that the pivoting movement of an actuating lever via this storage spring is transmitted to the power transmission member, the other end of which is connected to a differential gear case arranged lever device engages, through the pivoting movement of the differential lock is either switched on or off.

The lever device can, for example, be interposed a shift shaft and a shift fork act on a sliding sleeve or the like their axial displacement in a known manner a coupling or decoupling of two toothed components is effected.

In these known arrangements, one engages the lever device special return spring. This is arranged so that it is the Eebel device and thus the switching elements connected to it, for example the sliding sleeve, back to their original spatial Situation withdraws when the Operating lever is pivoted back into its basic position, d. H. if the before activated differential lock should be canceled again. This return spring -is dimensioned so that the differential lock. even while driving, d. H. at Load on the interconnected toothed components can be switched off. The way in which it punctures this return spring is very similar to the spring storage device.

The spring storage device is when the operating lever is operated when tooth meets tooth in the differential lock, d. H. if the sliding sleeve cannot be shifted axially immediately, clamped. After a certain driving distance usually takes place via the differential bevel gears Compensation, d. H. some displacement of the teeth, so that the power transmission member then under the action of the spring force of the tensioned spring storage device pivot the lever device on the differential gear in the desired manner and so that the sliding sleeve or the like can move axially. By pivoting of the lever device, the return spring acting on it is tensioned.

When the operating lever to turn off the differential lock off its previously mechanically locked position is pivoted back into its starting position is, is tensioned on the lever device on the differential gear by the Return spring exerts a force that tries to pull the lever device and that with it connected coupling member (sliding sleeve) back in their original position to pivot back or push back. However, this is not always the case under load immediately possible without further ado. As a rule, a certain amount of time will pass first before the return spring can pivot the lever device back again; pivoting back is only possible when the torque load on the coupled toothed components has just assumed a sufficiently low value, what during normal driving due to different frictional engagement between the two wheels or takes place continuously as a result of load changes or the like.

In the known arrangement, the operation of the operating lever must tensioned spring storage device for pivoting the lever device or for Moving the coupling member (sliding sleeve) not only the gear-related o. the like. Overcome resistance, but also'die spring force on the Rebelvorriohtung attacking return spring. Spring storage device and operating lever etc.

must be dimensioned accordingly large. The ones from. Vehicle driver the force to be used is comparatively large.

The object of the invention is to provide a spring safety device of the im Preamble of claim 1 mentioned. Kind to continue to improve and in particular to train so that the springs and the operating lever without affecting the Functioning of the spring storage device can be dimensioned weaker and the effort required to operate the operating lever is smaller will.

According to the invention, this object is achieved by the characterizing features of claim 1 solved. According to the invention, the spring storage device by using two functionally independent storage springs on both sides designed to act, depending on the pivot direction of the actuating lever in each case only one of the two storage springs is tensioned, while the other storage spring is also deflected without tension. The otherwise usually required special The return spring is no longer applicable and so is the one that is otherwise associated with this Retraction spring to take into account special circumstances.

Advantageous refinements and developments of the invention are specified in the subclaims.

Based on an embodiment shown in the drawing the invention is explained in more detail below.

The drawing shows a partially schematic representation Fig. 1 shows a side view of a spring storage device according to the invention, FIG. 2a a sectional view of this spring storage device along the sectional line II in Fig. 1 and Fig. 2b. and FIG. 20 shows the arrangement shown in FIG. 2a during different switching stages.

In the drawing are only those for understanding the invention necessary elements. shown and numbered. In particular, there are elements in the environment the spring storage device, for example the rotating components, which are torque-locked are to be coupled or decoupled with one another, not shown further.

In the illustrated embodiment, the spring storage device according to the invention is 1 Part of a switching device, with the help of which one of two axle drives one Motor vehicle to be switched on or off as required. With such a Motor vehicle, for example, the front axle is constantly driven. The rear axle on the other hand, it is only switched on temporarily, for example in difficult terrain, for which by means of a sliding sleeve, claw coupling or similar.

a torque-locked connection between a gearbox output shaft and a drive shaft (cardan shaft) leading to the rear axle drive must be what, for example, by pivoting a mounted on the transmission housing and lever device acting on the sliding sleeve or the like can take place.

The switching device shown consists essentially of one Operating lever 9 to be operated by the vehicle driver, numbered with 1 b e to f Spring storage device and a force transmission member that transmits tensile and compressive forces 20 for transmitting the pivoting movement of the actuating lever 9 to a no further Lever device shown (engagement lever) on the transmission housing.

The operating lever 9 is only indicated on the vehicle body 8, z. B. in a switching dome, mounted pivotably about a bearing axis 10. In its basic position he assumes the switching position shown in Fig. 1, which with regard to that then only the front axle should be driven, is numbered with V. If in addition the rear axle drive is to be switched on, i.e. the vehicle as all-wheel drive is to be operated, the operating lever is turned clockwise to the position numbered with A. Switch position swiveled.

The switch position selected in each case is activated by a spring pressure standing lock 14 fixed, which in numbered with 15 locking points of a switching segment 13 clicks into place.

The lower end of the actuating lever that can pivot about the bearing axis 10 9 is articulated to the spring storage device via a bolt arrangement 11 or the like 1 connected.

The spring storage device 1 is designed to act on both sides and contains, inter alia. an outer first sleeve 30 and an inner second sleeve 40, the interlock and are axially displaceable relative to one another. The outer first sleeve 30 is positively connected to the actuating lever 9 and is essentially axially displaced in the direction of their longitudinal axis when the operating lever 9 to a''Jagerachse 10 is pivoted.

At the opposite end of the bolt assembly 11 of the outer first Sleeve 30 is arranged a radially inwardly directed annular stop 31, which directly and indirectly for the axial support of a first storage spring 5 and a second storage spring 6 that is functionally independent of this is used. The first Storage spring 5 is designed as a compression screw spring and on the inner second Sleeve 40 mounted. It is caused by them that the two sleeves 30 and 40 when not actuated of the actuating lever 9 are axially pushed apart so far that an end of the inner second sleeve that protrudes into the outer first sleeve 30 40 arranged radially outwardly directed annular first flange 41 axially comes to rest on the annular stop 31. To that end is on the other end the inner second Sleeve 40 is a radially outwardly directed second annular flange 42 is arranged on which the first storage spring 5 is supported at its other end. In the exemplary embodiment, this second is annular Flange 42 with the aid of a bushing 43 pressed into the second sleeve and one thereon arranged snap ring 44 or the like. Axially supported.

The second accumulator spring 6 is also a compression coil spring formed and lies completely within the outer first sleeve 30. It supports one end axially on the first annular flange 41 of the inner first Sleeve 40 from. Your other end is supported on an annular abutment 25 of a massive end piece 22, with which the free end of the Eraft transmission member 20 axially protrudes through the inner second sleeve 40 into the outer first sleeve 30. If the actuating lever 9 is not actuated, the massive end piece 22 of the power transmission member becomes 20 axially drawn into the sleeves 30 and 40 and so far until one is at the end piece 22 arranged radially outwardly directed stop 24 axially on the first annular Flange 41 of the second sleeve 40 applies.

This constellation present when the operating lever 9 is not actuated can be seen well in Fig. 2a.

The mode of operation of the spring storage device according to the invention is the following. If, in addition to the permanent front-axle drive, the rear-axle drive is to be switched on, the operating lever 9 of the vehicle driver in the with A numbered switch position pivoted, the lock 14 in the associated "branch 15 clicks into place. The pivoting movement of the actuating lever 9 is carried out with it frictionally connected outer first sleeve 30 from its rest position shown in Fig. 2a in the new position shown in Fig. 2b and numbered 30 '. Under the prerequisite that the transmission does not happen to be so conclusive favorable spatial allocation of the components (gears) to each other, that the coupling member (sliding sleeve) coupling immediately without difficulty be moved can, but that, as usual, first "tooth on." Tooth "hits and the coupling member cannot be deflected immediately, remains the force transmission member that transmits not only tensile but also compressive forces 20 initially in its original position. That means that the inner second sleeve 40 as a result of the axial abutment of its first annular flange 41 on the annular stop 24 of the massive end piece 22 despite the axial displacement the outer first sleeve 30 must maintain its original spatial position, so that the first storage spring 5 arranged on it is compressed, d. H. tense will. The tensioned first storage spring is numbered 5 'in FIG. 2b. The inside the outer first sleeve 30 arranged second accumulator spring 6 remains through the axial displacement of the first sleeve unaffected, d. H.

untensioned.

The tensioned first storage spring 5 'as in this situation with a spring force predetermined by its spring characteristic via the inner second Sleeve 40, the first annular flange 41, the annular stop 24 and the Force transmission member 20 au £ the lever device, not shown, on Transmission. As well as the transmission output shaft and the one leading to the rear axle drive Drive shaft rotate at the same speed and its through the coupling link (sliding sleeve) Components that are to be coupled in a torque-locking manner are spatially appropriately assigned to one another have, therefore the lever device on the transmission is pivoted under this spring force and thereby the rear axle drive is switched on. The inner second sleeve and the power transmission member axially displaced accordingly. Your new location is shown in Fig. 2c and numbered 40 'and 20'. Along with the axial Displacement of the force transmission member 20 is also the second accumulator spring 6 shifted axially, but still remains untensioned.

In contrast to known switching devices must by the spring storage device only the coupling resistances are overcome here, but not any additional spring forces from return springs.

If the rear-axle drive is switched off again at a later point in time is to be, the processes proceed in the opposite direction. The actuating lever 9 is moved from its switching position A into the switching position V pivoted, whereby the outer first sleeve from the position shown in Fig. 2c is pulled axially to the right into the position shown in Fig. 2a. If again It is assumed that the lever device on the transmission as a result of the load of the Drive train can not be deflected immediately, the power transmission link 20 initially inevitably remain in the spatial position just assumed, d. H. this time in the position shown in FIG. 2c. When the outer first sleeve when the power transmission member remains and thus also when the abutment remains 25 is shifted to the right, in this case the second accumulator spring 6 compressed, .d. H. tense because the first annular flange 41 of the inner second sleeve 40 through the annular stop 31 of the outer first sleeve 30 is pulled to the right. In this situation, the second accumulator spring is under tension 6 a spring force caused by its spring characteristic on the force transmission member exercised, namely acting to the right, so that the aX not shown further other end of the power transmission link articulated lever device deflected will, as well as the force relationships between the coupled components allow this. The power transmission link is pushed to the right within the sleeves, until the constellation shown in Fig. 2a is present.

The first Speieherfeder 5 is not tensioned during this process; as was the case with the second accumulator spring, it is only deflected in an unstressed manner. Basically, only the accumulator spring is tensioned, which of the respective Switching direction is assigned.

In the embodiment, the power transmission member 20 is according to Art of a Bowden cable, the Bowden cable sleeve with 23 and the axially therein Slidably arranged Bowden cable core are numbered with 21. Here is the Bowden cable so dimensioned and arranged that over the Bowden cable core 21 not only tensile forces, but also sufficiently high compressive forces can be transmitted. The Bowden cable sleeve 23 is fixed in place with the vehicle body via an angle arrangement 7 8 connected. The inner second sleeve 40 is supported radially but axially displaceably on the Bowden cable sleeve 23.

Deviating from the illustrated embodiment, it can be used as a force transmission element Of course, also a rigid rod of a transmission rod or similar use find if. the spatial conditions allow this.

Of course, the spring storage device shown cannot only in a switching device of the type described, d. H. for switching on and off an additional axle drive can be used. She is in the same way too Can be used for switching differential locks or similar.

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Claims (6)

ANS PRU '0 RE 1. Spring energy storage device for a switching device for torque-locked coupling and decoupling of two with a toothing or rotating components provided with claws or the like, by means of a rebel device actuatable coupling member (sliding sleeve or the like), in particular for switching on and off a differential lock or a final drive of an Eraftfahrzeuges, in which Switching device the movement of an operating lever or the like with interposition the spring storage device via a force transmission element which transmits pressure and tensile forces (Linkage, Bowden cable) is transferred to the lever device (engagement lever), whereby by moving the operating lever initially only the spring storage device is tensioned and the rebel device under the action of the tensioned spring storage device is only deflected when the components to be coupled spatially one to another take a suitable position, characterized in that the spring storage device (1) double-sided acting and two functionally independent of one another Has storage springs (5, 6), and that the one storage spring only when actuated of the 3 actuating lever (9) in one switching direction and the other storage spring Can only be tensioned in the other switching direction when the actuating lever (9) is actuated is, while the other storage spring is also deflected in an unstressed manner. 2. Spring storage device according to claim 1, characterized in that that two interlocking sleeves (30, 40) which are axially displaceable against one another are provided, of which the outer first sleeve (30) frictionally with the actuating lever (9) is in connection and through this essentially in the direction of its longitudinal axis is axially displaceable that both sleeves (30, 40) by one acting on them first storage spring (5) are axially so far apart that one on the one end of the inner second sleeve (40) disposed and directed radially outward annular flange (41) arranged on one of the outer first sleeve (30) and radially inwardly directed annular stop (31) comes to rest axially, that the one end engaging the lever device (engagement lever) Power transmission member (20) with a massive end piece (22) of its free end axially through the inner second sleeve (40) into the outer first sleeve (30) protrudes and through an engaging on the end piece (22) and on the inner second sleeve the second accumulator spring (6) can be pulled axially into the sleeves (30, 40) so that that a stop arranged on the end piece (22) and directed radially outward (24) comes to rest axially on the annular flange (41) of the second sleeve (40). 3. Spring storage device according to claim 2, characterized in that that at the other end of the inner second sleeve (40) a radially outwardly directed second annular flange (42) is arranged, and that as a helical compression spring trained first memory spring (5) with one end to this second annular flange (42) and at its other end on the annular stop (31) the first sleeve (30) is supported. 4. Spring storage device according to claim 2 or 3, characterized in that that at the end of the massive end piece (22) of the power transmission member (20) a radial outwardly directed annular abutment (25) is arranged, and that the designed as a helical compression spring second storage spring (6) with its one End on this abutment (25) and with its other end on the first annular The flange (41) of the second sleeve (40) is supported. 5. Feaerspeichervorrichtung according to any one of claims 1 to 4, characterized characterized in that the power transmission member as a rigid rod of a linkage is trained. 6. Eederspeichervorrichtung according to any one of claims 1 to 4, characterized characterized in that the power transmission member (20) is designed in the manner of a 30wdenzuges is, with a .einer Bowdenzaghülle (23) arranged axially displaceable Bowden cable core (21), which is dimensioned and arranged such that sufficiently high Pressure forces can be transmitted that the massive end piece (22) of the force transmission member (2Q) is designed as an axial extension of the Bowden cable core (21) and that the inner second sleeve (40) is axially displaceable radially on the Bowden cable sleeve (23) supports.