DE10142189A1 - Device for increasing shifting forces in a transmission - Google Patents

Abstract

A device (1) for increasing shifting forces on a shifting shaft (3) in a gearbox that is longitudinally displaceable along its longitudinal central axis to a housing (3) at least from an initial position has an inner ring (10) which is activated by the action of at least one spring ( 8) and a ramp-like section (10a) on the inner ring (10) returns the selector shaft (2) from a switching position to an initial position.

Description

Field of the Invention

• - mit einer die Schaltwelle in Umfangsrichtung umgreifenden und zumindest zeitweise wenigstens längs in eine Richtung zu dem Gehäuse bewegungsfesten Hülse,
• - mit einem die Schaltwelle umgreifenden sowie zur Hülse zumindest längs bewegungsfest angeordneten Stützring,
• - mit einem längsverschiebbar zu der Hülse angeordneten sowie die Schaltwelle umgreifenden Schiebering,
• - mit am Umfang der Schaltwelle verteilt angeordneten und in der Ausgangsposition der Schaltwelle jeweils teilweise in eine der Schaltwelle bewegungsfest zugeordnete Ringnut eintauchenden Kugeln zwischen dem Stützring sowie einer Rampe an dem Schiebering und
• - mit wenigstens einer konzentrisch zu der Längsmittelachse der Schaltwelle angeordneten sowie den Schiebering gegen die Kugeln in Richtung des Stützringes vorspannenden Feder,

wobei die Schaltwelle relativ zu dem Stützring zumindest zeitweise aus der Ausgangsposition längs in Richtung des Stützringes relativ zu dem Stützring verschiebbar sowie dabei die Kugeln aus der schmaler werdenden Ringnut verdrängend angeordnet ist. The invention relates to a device for increasing shifting forces for a shifting shaft in a transmission that is longitudinally displaceable along its longitudinal central axis to a shifting housing at least from an initial position into a shifting position

• with a sleeve which grips around the switching shaft in the circumferential direction and at least temporarily at least lengthways in one direction to the housing,
• with a support ring encompassing the selector shaft and arranged at least longitudinally in a fixed manner relative to the sleeve,
• with a sliding ring arranged longitudinally displaceable to the sleeve and encompassing the selector shaft,
• - With balls arranged distributed around the circumference of the selector shaft and in the starting position of the selector shaft in each case partially immersed in an annular groove which is assigned to the selector shaft in a manner fixed against movement between the support ring and a ramp on the sliding ring and
• with at least one spring arranged concentrically to the longitudinal central axis of the selector shaft and biasing the sliding ring against the balls in the direction of the support ring,

wherein the switching shaft relative to the support ring is at least temporarily displaceable longitudinally in the direction of the support ring relative to the support ring from the initial position and thereby displacing the balls from the narrowing ring groove.

Background of the Invention

Such devices are mounted with shift shafts that are longitudinally displaceable and pivotable, in particular in or on manual transmissions for motor vehicles are arranged. For switching operations, switching shafts are selected when the Lane moved to the appropriate switch position, from which then in a Alley mostly chosen between two courses and the chosen course is then switched. To select and shift gears is the Depending on the application, the control shaft can be swiveled along its longitudinal axis or along it its pivot axis slidably arranged in the transmission. From the Depending on the application, the switching shafts move to select or Often switch automatically longitudinally by longitudinal displacement by means of spring force a neutral position or a central position.

When selecting or changing a gear, the operator should be in the vehicle be signaled before choosing the aisle or alley that they are in the Term is exactly the alley or the aisle, e.g. B. to select reverse gear. This signal is generated by the generic device. A Such a device is usually used where unintentional switching in a gear not adapted to the driving condition without mechanical Locking should be prevented. The device generates a signal for the Operator on the gear lever, which is usually a short-term and temporary increase in the shifting force of the selector shaft is generated. This Increasing the shifting force of the selector shaft manifests itself on the shift lever in an increase in the switching / selection force. For precise and comfortable switching, z. B. the forward gears, the shift shaft after switching the Reverse gear and the selection of lanes or switching of Forward gears can be operated with normal operating force.

In US 3,164,030 is a pivotable about its longitudinal central axis and along their longitudinal central axis to a housing movable shift shaft with a Provide device for increasing a switching force. The device for the increase in the switching force has one attached to the housing and to the Switching shaft stationary sleeve. The sleeve engages around the selector shaft in the circumferential direction. The selector shaft sits in the sleeve on the selector shaft encompassing support ring. A sliding ring is slidable in the sleeve recorded and encompasses the selector shaft. Between the lengthways to the Sliding ring facing end face on the support ring and the support ring facing contour on the sliding ring are distributed on the circumference of the selector shaft Balls arranged, each partially partially in an annular groove plunge. In this case, this contour is designed as a ramp. The ring groove is formed in the selector shaft. One concentric to the central longitudinal axis the shift shaft arranged coil spring in the sleeve is supported in the a longitudinal direction on the selector shaft. In the other direction it is outer coil spring in the direction of the switching movement of the selector shaft Reverse gear biased against the sliding ring. The sliding ring transfers the preload of the coil spring to the balls. The balls are pressed in the longitudinal direction against the support ring by the sliding ring. The Support ring in turn is supported in the longitudinal direction on the housing. The Balls are on the ramp and on the front of the support ring and are supported at least radially in the annular groove of the selector shaft. The outer Coil spring and the contour of the ramp cause the balls between the support ring, the sliding ring and the bottom of the ring groove are clamped and thus held in the ring groove. In the neutral 1-2- Gear position or if the reverse gear is not shifted, the Balls in the direction of the reverse gear Sidewall of the ring groove in the ring groove. The balls are supported on the other side on the end face of the support ring. It also acts on the balls Resistance of an inner coil spring. The inner coil spring is arranged concentrically to the shift shaft and is supported in one Longitudinal direction also from the sliding ring. In the other direction it is Coil spring supported on the selector shaft. Part of the ring groove is from that Support ring covered radially.

When shifting the shift shaft according to US 3,164,030 along to switch the Reverse gear moves the selector shaft and thus the ring groove relative to the fixed support ring. The ring groove plunges lengthways into the support ring further on. The balls are made from the increasingly narrow Ring groove displaced and rise on the ramp-like as well Switching direction of the reverse side wall of the ring groove radially outwards and out of the ring groove. The sliding ring is through the Balls slightly against the direction of movement of the selector shaft inner and outer coil spring moved. The sliding ring gives way to the Forced movement of the balls and creates the necessary radial Free space for the balls to escape from the ring groove. The bullets rise thus radially against the spring force of the inner and outer coil spring the annular groove and are supported in the longitudinal direction on the support ring.

In the device according to US 3,164,030, the resistance to this increases Moving the selector shaft by the forces of the outer coil spring and the inner coil spring as long as the balls come out of the side wall of the ring groove rise radially outwards. This one for a reverse gear Operator noticeable resistance to the normal state higher must Switching can be overcome by the operator. The resistance is for the operator receives the signal that the selector shaft is in the direction of Switching the reverse gear moves.

After the balls in the device according to US 3,164,030 the annular groove have left, the selector shaft moves the rest of the way to switch the Reverse gear in the longitudinal direction relative to the housing of the transmission stationary balls along. The balls are by means of the ramp on the sliding ring applied force of the coil springs against the cylindrical outer jacket of the selector shaft biased. The power to move the Switching shaft is on after leaving the ring groove by the balls Level dropped, which is far below the highest value for generating the increased Shifting force. However, the shifting force increases again from this point increasingly lightly until the reverse gear is engaged. That’s because of Effect of the inner coil spring, which is until the reverse gear is engaged the switching shaft opposes an increasing resistance. The inner one Coil spring is biased because one end is fixed to the The housing is supported on the support ring and its other end by the selector shaft is taken away. The balls pressed against the selector shaft and the Effect of the inner coil spring generate a switching force, the value of which the normal value for selecting other gears. The Resistance, however, is less than the resistance created by the ring groove ascending balls is generated. That is in the neutral 1-2 gear position inner coil spring not preloaded. When moving the selector shaft off the neutral position out in the switch position for switching the Reverse gear moves the selector shaft relative to the fixed support ring and compresses the inner coil spring. The potential of the inner Coil spring leads after removing reverse gear and after releasing the shift lever, the shift shaft in the longitudinal direction again in the 1-2 gear position and the coil spring is in this position relaxed again.

The balls in the device according to US 3,164,030 snap when reached the neutral position by the spring force of the outer coil spring on the Slide ring back into the ring groove.

When moving the selector shaft lengthways in the opposite direction the direction that can be selected for switching the reverse gear remains Balls locked in the ring groove. The preload of the outer Coil spring remains unchanged as in the 1-2 gear position and acts on the Sliding ring. The sliding ring in turn holds the balls longitudinally on the support ring. The outer coil spring and the contour of the ramp on the sliding ring cause the balls between the support ring and the sliding ring are clamped and at the same time pressed radially into the ring groove. The section of the Shift shaft with the ring groove moves relative to the remaining ones Balls and to the stationary sleeve. The width of the ring groove is in Longitudinal direction adapted to this switching path. The inner coil spring remains unstrung. This switching force is therefore from that through the ramp to the balls transferred radial portion of the preload of the outer coil spring affected. This part presses the balls into the ring groove and thus creates a resistance that also slightly increases the shifting force. This resistance can adversely affect shifting comfort.

Disadvantageous in the otherwise satisfactory solution according to the prior art Technology is further that the manufacture of such a device is relative is expensive. The holes and grooves for receiving the Resilient elements and securing elements must be carried out in individual work steps be introduced. The assembly of the individual parts in the switch housing or Gear housing is time consuming. This is particularly disadvantageous the large-scale or mass production of such devices in Driven out. Often, devices according to the prior art also increase much axial space is required. The location of the individual elements is different from that The location of the grooves determines the sum of the tolerances and can vary from the nominal size deviate greatly. The process of switching is then inaccurate. The device is firmly connected to the gearbox and is not interchangeable.

Summary of the invention

The object of the invention is therefore a device of the aforementioned To create genus that avoids the disadvantages of the prior art and which is particularly notable for its compact, space-saving design Construction and cost-effective production, especially in large series and distinguishes mass production.

This object is achieved according to the subject matter of claim 1 that the annular groove laterally through a contour facing the support ring ramp-like section on one on the shift shaft arranged inner ring and spaced by a this section opposite contour is limited to the support ring and that the spring of the Support ring is groundbreaking on the sleeve.

The device for increasing shifting forces is for one along their Longitudinal central axis to a housing at least from an initial position in a shift position longitudinally shiftable shift shaft in a gearbox Motor vehicle provided. The control shaft is either directly in the Housing of the gearbox added or by means of other housing parts to the Flanged gearbox. The device sits on the regardless of the housing Shift shaft and is attached to the shift shaft. The housing of the transmission but forms at least the stop for some elements of the device, preferably at least on one side of the housing, longitudinally into one In the direction of the fixedly arranged sleeve. The sleeve encompasses the Shift shaft in the circumferential direction on a portion of the shift shaft. The shift shaft is longitudinally movable in the sleeve to sleeve in both longitudinal directions added.

The device also has a switching shaft that encompasses and Sleeve on at least longitudinally fixed support ring. Moreover the device is arranged with a longitudinally displaceable to the sleeve and the sliding shaft encompassing the selector shaft. On the scope of the Switching shaft balls are distributed in the device. The balls are partially in the starting position of the selector shaft in one with the Switch shaft movable ring groove and sit between the support ring as well the contour facing the support ring on the sliding ring. One or several concentric to the longitudinal central axis of the shift shaft elastic springs tension in the starting position of the selector shaft Slide ring against the balls in the direction of the support ring. The balls are lying thereby also on the support ring. The sliding ring against the balls the biasing spring (s) is (are) preferably coil spring (s).

How an embodiment of the invention provides is the support ring facing contour formed on the sliding ring as a ramp. The ramp seen in cross section has one in its course from the inner diameter of the sliding ring increasing in the direction of its outer diameter Flat, curved or rectilinear, on. The surface points in the Sliding ring inwards and revolves in the circumferential direction. The support ring facing contour on the sliding ring is alternatively as a flat, perpendicular to Circumferential ring surface aligned with the center axis of the sliding ring educated.

The ramp on the sliding ring causes the balls in the Starting position of the control shaft in the ring groove pre-tensioned between the support ring and the sliding ring as well as on the side of the selector shaft are trapped. The ring groove is laterally through a facing the support ring Contour of a ramp-like section on one on the Switch shaft arranged inner ring and spaced by a section opposite contour limited on the support ring. The feather is on one Prestressed side on the support ring and on the support ring groundbreaking side on the sleeve.

The support ring, the sliding ring, the inner ring, the balls and the spring are preferably received in the sleeve to form an assembly summarized. Outside in the sleeve is supported on one side of the sleeve along the Support ring. One embodiment of the invention provides that the support ring is supported on a retaining ring in the sleeve or alternatively, that the support ring is located on a radially inward facing board of the Supports the sleeve. The balls are biased to one side on the support ring on. The spring can be moved against the other side of the balls biased sliding ring received in the sleeve. The spring rests in the direction facing away from the sliding ring on the sleeve. This The assembly can be mounted on the selector shaft, with the support ring extending from the Sliding ring is supported longitudinally on the sleeve. Such assemblies are on the selector shaft before the selector shaft is installed in the gearbox preassembled. The assembly of the device on the selector shaft and Assembly of the selector shaft together with the device is easy. The Assembly costs are reduced. The device according to the invention is on switching shafts retrofittable and interchangeable.

If the module is pre-assembled on a selector shaft, these are Components other than in the arrangement described above also preferably so arranged to each other that the device on the selector shaft in the Starting position of the control shaft to the sleeve is set. The balls engage this position biased into one side by the support ring and due to the ramp-like contour of the section of the inner ring on the other Ring groove on one side. They have in this groove between the support ring and the inner ring constraining balls the endeavor Push the support ring and the inner ring away from each other in the longitudinal direction. The However, the inner ring is supported in the device against in the longitudinal direction acting force component. A preferred embodiment of the invention provides before that the inner ring in the starting position of the selector shaft along the balls facing away from the sleeve.

A device according to the invention is in a further embodiment the shift shaft arranged so that the sleeve in the starting position their side with the support ring on a fixed to the housing of the transmission Stop of the gearbox is present. Alternatively, it is provided that the Device on the shaft shaft spaced from the fixed stop of the Gear is arranged. The control shaft is in the device in the Starting position and can be moved with the device up to the stop arranged. The entire device is through the shift shaft up to the Carried stop without anything moving in the device. This Switching movement is unaffected by the action of the coil spring as the whole device is taken. The device increases the switching force only when the sleeve is fixed to the housing of the gearbox Supports the stop. Only then can the selector shaft against the now stationary Sleeve and the stationary support ring can be moved further. Is the Device on the control shaft for such a stop in the transmission spaced apart, the selector shaft in the direction of the stop initially be shifted without increasing the switching force. On the way to the stop are switching positions, z. B. for that Shifting forward gears, ingestible or can be driven through, the choice of which is not announced by an increase in the shifting force. If these positions are passed through, then the sleeve hits the stop. The Switching position, e.g. B. to choose the reverse gear, is then by a Increased switching force announced by the device.

Another embodiment of the invention provides that the sleeve and the Sliding ring formed parts are made of sheet metal. Through forming technologies like Drawing, embossing and pressing are individual parts, especially in the large series and Mass production economically, preferably made of steel.

When the shift shaft is moved longitudinally in the device according to the invention the inner ring is turned from the starting position by the selector shaft taken. For this purpose, the inner ring is preferably tight, e.g. B. pressed on the Shift shaft. Alternatively, the inner ring is slidably seated on the selector shaft and is by a shaft shoulder behind the inner ring or Circlip in all conceivable designs in the direction of movement Shift shaft taken away.

If the selector shaft moves longitudinally from the starting position towards the Switching position moves, the inner ring is taken. The sleeve is in contact the stop of the housing. The inner ring detaches from its attachment, z. B. from the stop of the sleeve. The ring groove becomes narrower because the one with the Switching shaft entrained inner ring moves towards the support ring. The Balls are directed radially outwards from the narrowing ring groove the ramped section of the inner ring ascending from the Ring groove displaced or alternatively on the ramp-like section displaced towards the edge of the ring groove. The sliding ring is through the balls forced out of the ring groove against the Direction of movement of the control shaft slightly moved against the spring. He gives way to the bullets and creates the necessary space for those from the ring groove ascending balls. The balls rise against the spring force of the spring radially out of the ring groove. The spring is only slightly affected by that Dodge the sliding ring biased because its one end is on the Support sliding ring and its other end abuts the sleeve. The feather will thus not carried away by the sound wave.

Above it was mentioned that the inner ring on the stop of the sleeve is applied. A further embodiment of the invention then also sees this before that the inner ring, in particular in an encapsulated by the sleeve pre-assembled module, in the starting position of the selector shaft its longitudinal side facing away from the balls is supported on the sleeve. This The stop on the sleeve is optionally by a radially inward facing Board the sleeve or by a neck on a machined Sleeve formed. The radially inward facing shelf is optional a flanged rim formed in one piece with the sleeve, a perforated Bottom of the drawn sleeve or a perforated bottom of one in / on the sleeve pressed lid, or one in the sleeve, e.g. B. secured by flanging Washer.

The resistance to moving the selector shaft increases due to the forces of the Spring, e.g. B. a coil spring, as long as the balls on the side wall the ring groove rise radially outwards. This for a z. B. the Operator selecting reverse gear with a steep increase in the shifting force curve Noticeable higher resistance than normal must pass through when switching the operator is overcome and is the signal for the operator, that the selector shaft is in the direction of switching the reverse gear emotional.

After the balls have created the ring groove, the selector shaft moves the rest of the way to switch the reverse gear to the in Longitudinal balls relative to the housing of the gearbox along. The balls are against the cylindrical by a radial force component Prestressed outer jacket of the inner ring. This force component is through that Converting the force of the spring against the sliding ring generated on the ramp. The The spring preload remains almost unchanged and acts on the Sliding ring. The sliding ring in turn holds the balls on the ramp generated vertical force component on the support ring. The force required to The shift shaft has moved after the balls leave the ring groove have reduced to a relatively constant value. This value is at most slightly above the normal state when selecting other gears. The spring force implemented with the contact of the balls with the inner ring creates a resistance to the switching movement that is less than the resistance generated by the balls rising from the ring groove is.

With the device described above, the switching shaft after the Take out the reverse gear and after releasing the Switch lever is not automatically by the device in its starting position recycled. Only when the selector shaft by means of an outside of the Device acting force is returned so far that the inner ring with the the ramp-like section stands radially under the balls, the force Snap the balls into the ring groove. That's why it's one of those Alignment can be used particularly in applications in which the shift shaft with its longitudinal center axis vertical to the gearbox or the vehicle is installed in the gearbox. The movement of the Shift shaft leads from the starting position to the shift position Shift shaft vertically upwards. After removing the Reverse gear and after releasing the shift lever supports the dead weight the shift shaft the return of the shift shaft by gravity in their Starting position. Furthermore, such a device is designed Can be used especially in applications in which the control shaft is outside the device on the shift shaft restoring forces in the Starting position is returned.

An embodiment of the invention provides that at least on the inner ring a spring element rests, the spring element at least against itself shift shaft moving from the starting position into the shift position is biased. The selector shaft is operated by means of the restoring forces of the spring element returned to the starting position. The force of the inner ring acting spring leads after removing z. B. the reverse gear and after releasing the shift lever, the shift shaft in the longitudinal direction automatically return to the starting position. It leads the selector shaft so far back until the inner ring with the ramp-like section radially under the Balls stands and the balls by the force of the spring on the sliding ring supported by the force of the spring element on the inner ring in the Can snap ring groove.

In the latter device, after leaving the ring groove the balls also reduced the shifting force to a low level. The Switching force is then less than the increased switching force. The balls are there again by a radial component of the spring force generated on the ramp on the sliding ring against the cylindrical outer jacket of the inner ring pressed. However, the switching force is higher than that for selecting others Gears usual normal value, since the spring element on the inner ring of the Direction of movement of the shift shaft until it takes up its shift position counteracts. The counterforce generated by the spring element on the inner ring rises steadily after the balls have been displaced from the ring groove without However, to achieve the highest value of the switching force. That on the Inner ring acting spring element is biased because one end is fixed to the housing on the support ring and its other end The spring element is preloaded from the control shaft. The spring force creates a resistance to the switching movement, however is less than the resistance caused by the ascending from the ring groove Balls is generated.

The invention is further developed with a spring element that is different from the inner ring is supported on the sleeve. The spring element is as a Component integrated in the pre-assembled unit. The spring element or the Spring elements are preferably one or more coil springs.

The invention is further configured by a on the inner ring ramp-like section with a frustoconical cross section is provided. The smallest diameter of this section lies on the to the support ring facing side of the inner ring. At its largest diameter it goes Section in the cylindrical outer surface of the inner ring. there the outer contours of the section run from the smallest to the largest Diameter straight and thus actually form a truncated cone. alternative these outer contours of the section run radially inward or bulged outside. It is also conceivable that between the front of the Inner ring and the contour of the frustoconical section Locking contour is formed. The balls snap into this locking contour Starting position of the selector shaft. The inner ring and thus the selector shaft are in this Then position locked. A stop for the inner ring on the sleeve for The shift shaft can then be supported in the starting position under certain circumstances omitted.

A further embodiment of the invention makes it possible to use it to dispense with a second spring. This configuration provides that the ramp-like section on the inner ring of the selector shaft is frustoconical. The smallest diameter of this truncated cone lies here on the side of the inner ring facing the support ring. At its largest The cone-shaped section goes into the diameter cylindrical outer surface of the inner ring. The length of the section between the smallest diameter at the transition to the cylindrical area at largest diameter is larger than the distance the inner ring moves when moving the shift shaft from the starting position to the shift position relative to Sleeve and thus back to the support ring. The balls are thus after The switching shaft does not reach the switching position from the ring groove displaced, but only to the edge of this. You're still up to that ramp-like section of the inner ring. The radial component of the force of the Spring on the sliding ring is on the balls and on the truncated cone Section implemented in a component acting in the longitudinal direction. This Component urges after removing the gear and releasing the Shift lever in the longitudinal direction back to the starting position back. The sliding ring thus pushes the balls on the frustum of a cone trained portion of the inner ring towards its smallest Diameter. The balls have the aim anyway on the contour of the To move down the section. Supported by the component of Spring force on the sliding ring moves the selector shaft until the balls have reached their starting position in the ring groove and the Lock the control shaft in this position.

It is also conceivable to use a device with a combination of the previously described features. An interaction of the force of the spring on the sliding ring and the balls on the frustum-like elongated Section on the inner ring and the force of the acting on the inner ring Spring element leads after removing the reverse gear and Let go of the shift lever in the longitudinal direction back into the Starting position back. The sliding ring pushes the balls on the frustoconical section of the inner ring in the direction of its smallest diameter.

Brief description of the drawings

The invention is explained in more detail below on the basis of exemplary embodiments explained. Show it

FIG. 1a to 1c, an embodiment of a built-up in a housing of a transmission switching device according to the invention, longitudinal sections through the device in different switching positions,

FIGS. 2a and 2b one embodiment of an apparatus according to the invention with a coil spring on the sliding ring, longitudinal sections of the device with the control shaft in different switching positions,

FIGS. 3a and 3b, the apparatus of Fig. 2a, 2b with an alternative design of the ramp on the inner ring,

Fig. 4 to 6 of further embodiments equipped with two springs devices according to the invention in longitudinal section.

Detailed description of the drawings

Figs. 1a to 1c show a device 1 for increasing shift forces on a shift shaft 2. The selector shaft 2 sits in a housing 3 of a transmission, not shown. The control shaft 2 is mounted in the housing 3 by means of a bearing 4 so that it can be pivoted about its longitudinal central axis 2 a and can be moved longitudinally. The device 1 is a structural unit and sits on the selector shaft 2 . The structural unit is combined in a sleeve 5 of the device 1 . The sleeve 5 engages around a section of the selector shaft 2 and receives a sliding ring 6 , a support ring 7 , a coil spring 8 and balls 9 .

An inner ring 10 is pushed onto the selector shaft 2 and lies longitudinally in one direction on a stop ring 11 fixed to the selector shaft 2 .

In Fig. 1a, the switching shaft 2 is shown in its starting position for the device 1 . The helical spring 8 is supported on the inside of the sleeve 5 on its side facing away from the bearing 4 and prestresses in the direction of the bearing against the sliding ring 6 which is slidably received in the sleeve 5 . The sliding ring 6 transmits the spring force of the coil spring 8 to the balls 9 by means of a ramp 6 a. On the ramp 6 a, the spring force is broken down into radial and axial components. The axial components press the balls against the end face 7 a of the support ring 7 . The balls 9 are pressed into an annular groove 12 by means of the radial component. The annular groove 12 is laterally delimited by a ramp-like section 10 a on the inner ring 10 and by the end face 7 a of the support ring. The balls 9 are supported against the spring force of the helical spring 8 a on the end face 7 a and the ramp-like section 10 a in the annular groove 12 . The support ring 7 is supported against the axial components of the spring force applied by means of the balls 9 via a locking ring 13 in the sleeve 5 . The inner ring 10 is supported with its side facing away from the support ring against the axial components applied by the balls 9 on a stop 5 a of the sleeve. In the starting position according to FIG. 1a, the device with its side facing the bearing 4 is arranged at a distance d from the housing 3 .

The shift shaft 2 is shifted longitudinally into a shift position in the direction of the bearing 4 through the bearing 4 . The device 1 , which is preloaded in itself, is taken over the distance d by means of the stop ring 11 over the inner ring 10 until the device 1 strikes the housing 3 . This position is shown in Fig. 1b. The position of the control shaft 2 within the device 1 still corresponds to that of the starting position according to FIG. 1a.

Fig. 1c shows the shift shaft 2 in a shift position to which the shift shaft 2 is displaced with increased switching forces. For this purpose, the selector shaft 2 takes the inner ring 10 from its position according to FIG. 1b in the direction of the support ring 7 via the stop ring 11 . The balls 9 are displaced radially outward from the annular groove 12 by the constraining forces of the inner ring 10 and rise on the ramp-like section. The sliding ring 6 evades the forced movement of the balls 9 against the force of the coil spring 8 in order to create the space for the balls rising from the annular groove 12 . The balls are finally completely replaced in Fig. 1c by the moving in the direction of the support ring 7 inner ring 10 from the annular groove 12 and abut the cylindrical outer surface 10 b of the inner ring 10 at. The balls 9 are clamped between the sliding ring 6 and the support ring 7 .

FIGS. 2a and 2b show another embodiment of an apparatus 14 according to the invention. The device 14 is a structural unit accommodated in a sleeve 15 . The sleeve 15 is stepped and has a hole 15 a on the bottom through which the switching shaft is passed when the device 14 is mounted on a switching shaft, not shown. The remaining edge of the bottom is a stop 15 b for an inner ring 16 . Balls 17 act on the inner ring 16 and are preloaded by a sliding ring 18 . The sliding ring 18 is prestressed against the balls 17 by means of a helical spring 19 and presses the balls 17 into an annular groove 20 in the starting position according to FIG. 2a. The annular groove 20 is laterally limited by a ramp-shaped section 16 a on the inner ring and the end face 21 a of a support ring 21 . The support ring 21 is supported by a retaining ring 22 in the sleeve 15 .

An increased switching force is generated on the inner ring 16 when the inner ring 16 is displaced longitudinally away from the stop 15 b in the direction of the support ring 21 . The annular groove 20 narrows and forces the balls 17 on the ramp-like section 16 a ascending radially from the annular groove 20 . The sliding ring 18 dodges the balls 17 with a movement longitudinally opposite to the direction of movement of the inner ring 16 . The rising of the balls 17 on the ramp-shaped section 16 a generates an increased displacement force on the inner ring and thus an increased switching force on the selector shaft, not shown. The course of the increase in force is particularly steep if, as shown in FIG. 2, the contour of the ramp-like section increases progressively in the direction of the cylindrical outer surface 16 b of the inner ring.

In Fig. 2b, the balls have left 17, the annular groove 20 and abut the cylindrical outer surface 16 b of the inner ring 16. By means of the spring force of the helical spring 19 converted into radial and axial components on the ramp 18 a, the balls are clamped between the ramp 18 a of the sliding ring 18 , the end face 21 a of the sliding ring and the cylindrical outer surface 16 b of the inner ring. The radial component of the spring force of the helical spring 19 on the ramp 18 a allows the balls 17 to snap into the annular groove 20 when the inner ring 16 approaches the stop 15 b and presses the inner ring against the stop 15 b.

FIGS. 3a and 3b show a device 23 which is constructed substantially the same as the device 14 of FIGS. 2a and 2b. However, the device 23 has an inner ring 24 with a ramp-like section 25 that is elongated in the longitudinal direction. The section 25 is seen in cross section with an initially progressively increasing contour 25 a, which merges into a truncated cone 25 b. The largest diameter of the truncated cone 25 b merges into the cylindrical outer surface 24 a of the inner ring 24 .

In an initial position, the inner ring 24 and the inner ring 16 abut the stop 15 b of the sleeve 15 . The balls 17 are pressed into an annular groove 26 formed by the ramp-like section 25 on one side and the end face 21 a of the support ring 21 on the other side. For this purpose, the spring force of the coil spring 19 acts on the sliding ring 18 . In the switching position of the inner ring 24 or the switching shaft, not shown, the balls 17 rest against the truncated cone 25 b and are therefore not completely displaced from the annular groove 26 . The balls are inclined to move radially downward due to the bias of the coil spring 19 on the sliding ring 18 and due to their position on the truncated cone 25 . This generates a longitudinal force on the inner ring 24 , which facilitates the return of the inner ring 24 to its starting position on the stop 15 b according to FIG. 3a.

FIG. 4 shows a device 27 in which the same individual parts as in FIGS. 2a and 2b are installed. In addition to the inner ring 16 , the balls 17 , the sliding ring 18 , the support ring 21 and the coil spring 19 , a further spring 28 is installed in the device 27 . In the starting position of the inner ring 16 and the control shaft, not shown in FIG. 4, the spring 28 biases the inner ring in the longitudinal direction against the stopper 15 b before. The spring 28 is supported in the interior of the support ring 21 . When the inner ring 16 is displaced longitudinally in the direction of the switching position according to FIG. 2 b, the inner ring 16 moves relative to the stationary support ring 21 . The annular groove 20 is becoming narrower and the balls 17 are displaced from the annular groove 20 . The balls 17 rise on the ramp-shaped section 16 a radially outwards and out of the annular groove 20 . The sliding ring 18 is slightly moved by the balls 17 against the direction of movement of the inner ring 16 against the coil spring 19 . The radial clearance for the balls 17 to escape from the annular groove 20 is created. The switching force on the inner ring 16 is increased in the device 27 according to FIG. 4 on the one hand by the balls 17 rising from the annular groove 20 with a force peak and on the other hand by the potential of the spring 28 . After the balls 17 have left the annular groove 20 analogously to the illustration according to FIG. 2b, the inner ring 16 moves the rest of the way for switching into the switching position along the balls 17 which are stationary in the longitudinal direction relative to a transmission housing. The spring force of the spring 28 continues to act on the inner ring 16 until the inner ring 16 has reached the switching position. However, the spring force of the spring 28 creates a resistance to the switching movement of the inner ring 16 on the switching shaft, not shown, which is less than the resistance which is generated by the balls 17 rising from the annular groove 20 .

In comparison to FIG. 4, the inner ring 24 already described with FIGS . 3a and 3b is used in the device 29 according to FIG. 5. The sleeve 15 , the sliding ring 18 , the support ring 21 , the balls 17 and the coil spring 19 correspond to the arrangement according to FIG. 2. The ramp-like section 25 on the inner ring 24 is provided with the progressively increasing contour 25 a and the truncated cone 25 b. The progressively increasing contour 25 a merges into the truncated cone 25 b at its smallest diameter. The truncated cone 25 b runs out at its largest diameter on the cylindrical outer surface 24 a. The length I of the section between the smallest diameter to the transition into the cylindrical region 24 a is greater than the distance covered by the inner ring when moving the selector shaft from the starting position into the switching position relative to the sleeve 15 in the direction of the support ring 21 . Thus, the annular groove 26 is so wide that the balls 17 rest when the switching position is reached by the inner ring 16 on the outer surface of the truncated cone 25 a. The balls 17 tend to move down the contour of the section 25 . Supported by the spring force of the coil spring 19 on the sliding ring 21 and by the potential of the spring 28, the balls 17 move the inner ring 16 when the gear is removed and the shift lever is released, the inner ring 16 back against the stop 15 b.

Fig. 6 shows a further embodiment of the invention. The device 30 has a sleeve 31 with a continuously cylindrical lateral surface 31 a. A support ring 32 , the sliding ring 18 , the coil spring 19 , the spring 28 , the balls 17 and the inner ring 24 are received in the sleeve 31 . The device 30 functions like the device 29 from FIG. 5. The coil spring 19 is supported on the sleeve side on a thickened sleeve base 31 b. With the thickness of the bottom 31 b, the bias of the coil spring 19 in the sleeve 31 against the sliding ring 18 is predetermined. The support ring 32 is made by forming. In the longitudinal direction, the support ring 32 is supported on an inwardly facing rim 31 c. The board is folded from the cylindrical outer surface 31 a by crimping radially inward facing. Reference number 1 device
2 selector shaft
2 a longitudinal central axis
3 housing
4 bearings
5 sleeve
5 a sleeve
6 sliding ring
6 a ramp
7 support ring
7 a end face
8 coil spring
9 bullet
10 inner ring
10 a ramp-like section
10 b cylindrical surface
11 envelope ring
12 ring groove
13 circlip
14 device
15 sleeve
15 a hole
15 b stop
16 inner ring
16 a ramp-like section
16 b lateral surface
17 balls
18 sliding ring
18 a end faces
19 coil spring
20 ring groove
21 support ring
21 a end face
22 circlip
23 device
24 inner ring
24 a lateral surface
25 section
25 a contour
25 b truncated cone
26 ring groove
27 device
28 spring
29 device

Claims (14)

1. Device ( 1 , 14 , 23 , 27 ) for increasing shifting forces on a shifting shaft ( 2 ) which can be displaced longitudinally along its longitudinal central axis to form a housing ( 3 ) in a transmission, at least from an initial position
with a sleeve ( 5 , 15 , 31 ) which is fixed around the switching shaft in the circumferential direction and at least temporarily at least longitudinally in one direction to the housing ( 3 ),
with a support ring ( 7 , 21 , 32 ) which engages around the selector shaft ( 2 ) and is arranged at least longitudinally fixed to the sleeve ( 5 , 15 , 31 ),
with a sliding ring ( 6 , 18 ) arranged to be longitudinally displaceable relative to the sleeve ( 5 , 15 , 31 ) and encompassing the selector shaft ( 2 ),
with balls ( 9 , 17 ) between the support ring ( 7 , 21 ) and one of the support ring, which are distributed around the circumference of the control shaft ( 2 ) and in the starting position of the control shaft ( 2 ) are partially immersed in an annular groove ( 12 , 20 , 26 ) ( 7 , 21 ) facing contour on the sliding ring ( 6 , 18 ) and
with at least one concentric with the longitudinal central axis (2 a) of the switching shaft (2) is arranged, and the sliding ring (6, 18) against the balls (9, 17) in the direction of the support ring (7, 21, 32) biasing spring
the control shaft ( 2 ) being displaceable relative to the support ring ( 7 , 21 , 32 ) at least temporarily from the starting position in the direction of the support ring ( 7 , 21 , 32 ) relative to the support ring ( 7 , 21 , 32 ) and thereby the balls ( 9 , 17 ) is displaced from the narrowing ring groove ( 12 , 20 , 26 ), characterized in that the ring groove ( 12 , 20 , 26 ) laterally through a contour facing the support ring ( 7 , 21 , 32 ) of a ramp trained section ( 10 a, 16 a, 25 ) on an inner ring ( 10 , 16 , 24 ) arranged on the selector shaft ( 2 ) and by a contour opposite the section 10 a, 16 a on the support ring ( 7 , 21 , 32 ) is limited and that the spring ( 8 , 19 ) of the sliding ring ( 6 , 18 ) points against the sleeve ( 5 , 15 , 31 ). 2. Device according to claim 1, characterized in that the support ring ( 21 ) facing contour of the sliding ring ( 6 , 18 ) is a ramp ( 6 a, 18 a), the ramp ( 6 a, 18 a) in the circumferential direction circumferential surface extending in front of the inner circumference of the sliding ring ( 6 , 18 ), facing inwards and viewed in cross section from the inner circumference of the sliding ring ( 6 , 18 ) in the direction of the outer circumference of the sliding ring ( 6 , 18 ) is limited. 3. Device according to claim 2, characterized in that the support ring ( 7 , 21 , 32 ), the sliding ring ( 6 , 18 ), the inner ring ( 10 , 16 , 24 ), the balls ( 9 , 17 ) and the spring ( 8 , 19 ) accommodated in the sleeve ( 5 , 15 , 31 ) to form an assembly that can be mounted on the selector shaft ( 2 ), the support ring ( 7 , 21 , 32 ) facing away from the sliding ring ( 6 , 18 ) the sleeve ( 5 , 15 , 31 ) supports. 4. The device according to claim 3, characterized in that the support ring ( 7 , 21 ) is supported on a retaining ring ( 13 , 22 ) in the sleeve ( 5 , 15 ). 5. The device according to claim 3, characterized in that the support ring ( 32 ) is supported on a radially inwardly facing rim ( 31 c) of the sleeve ( 31 ). 6. The device according to claim 3, characterized in that the inner ring ( 10 , 16 , 24 ) in the starting position of the selector shaft ( 2 ) along the balls ( 9 , 17 ) facing away from the sleeve ( 5 , 15 , 31 ) is supported , 7. The device according to claim 1, characterized in that the inner ring ( 16 , 24 ) sits firmly on the control shaft. 8. The device according to claim 3, characterized in that the device ( 1 ) on the selector shaft ( 2 ) with the selector shaft ( 2 ) in the starting position is longitudinally displaceable in the direction of a switching position against the housing ( 3 ). 9. The device according to claim 1, 2 or 3, characterized in that the sleeve ( 5 , 15 , 31 ), the sliding ring ( 6 , 18 ) and the support ring ( 32 ) are formed parts made of sheet metal. 10. The device according to claim 1, characterized in that the spring ( 8 , 19 ) is a coil spring. 11. The device according to claim 1, characterized in that the ramp-like section ( 10 a, 16 a, 25 ) on the inner ring ( 10 , 16 , 24 ) of the selector shaft ( 2 ) is frustoconical, the smallest diameter of the section ( 10 a, 16 a, 25 ) lies on the side of the inner ring ( 10 , 16 , 24 ) facing the support ring ( 7 , 21 , 32 ) and its largest diameter in a cylindrical outer surface ( 10 b, 16 b, 24 a) of the inner ring ( 10 , 16 , 24 ) passes over. 12. The device for increasing switching forces on a longitudinally displaceable shift shaft along its longitudinal central axis from the starting position in the direction of the support ring into a shift position according to claim 1, characterized in that the inner ring ( 10 , 16 , 24 ) is at least on its from the balls ( 9 , 17 ) facing away from the side is firmly supported on the selector shaft ( 2 ) and that the ramp-like section ( 10 a, 16 a, 25 ) on the inner ring ( 10 , 16 , 24 ) of the selector shaft ( 2 ) is frustoconical, the smallest diameter of the section ( 10 a, 16 a, 25 ) being on the side of the inner ring ( 10 , 16 , 24 ) facing the support ring ( 7 , 21 , 32 ) and its largest diameter in a cylindrical outer surface ( 10 b, 16 b, 24 a) of the inner ring ( 10 , 16 , 24 ) passes over and the length of the section ( 10 a, 16 a, 25 ) between the smallest diameter to the transition into the cylindrical outer surface ( 10 b, 16 b, 24 a) is greater than the distance that the inner ring ( 10 , 16 , 24 ) travels from the starting position into the switching position relative to the sleeve ( 5 , 15 , 31 ). 13. The apparatus according to claim 1, characterized in that at least one spring element ( 28 ) rests on the inner ring ( 16 , 24 ), the spring element ( 28 ) at least against the inner ring ( 16 , 24 ) moving from the starting position into the switching position. is biased. 14. The apparatus according to claim 12, characterized in that the spring element ( 28 ) is a spiral wound spring and is supported on the support ring ( 21 , 32 ) facing away from the inner ring ( 16 , 24 ).