DE102011052400A1 - Switching element, switching device and method for their preparation - Google Patents

Abstract

The invention relates to a shifting element (2) for the axial displacement of a sliding sleeve of a gear change transmission, which forms a U-shaped base body which has a base element (15) and shift cheeks (16a, 16b) protruding therefrom, wherein in the transverse plane of the shifting element (2 ) a shift jaw is formed between the shift cheeks (16a, 16b). The base element (15) and / or the switching cheeks (16a, 16b) of the base body are formed by a profile body. The shift cheeks (16a, 16b) are connected to the base element (15) by means of an integral joint connection. The invention also relates to a method for producing a switching device and a switching device comprising the switching element (2) and a transmission element, the transmission element having a switching recess through which the base element (15) is guided.

Description

The invention relates to a switching element, in particular a rocker arm or shift fork, for axial displacement of a sliding sleeve and a switching device for a change-speed gearbox and a method for producing a switching device, as described in the preambles of claims 1, 23, 27, 32, 34 and 36.

In gear change gears, a synchronizer body and a sliding sleeve are arranged between two gear wheels rotatably mounted on a gear shaft. The sliding sleeve is provided with an internal toothing, which engages in an introduced into the synchronizer outer teeth. The synchronizer body is rotatably connected to the transmission shaft. When switching a gear, the sliding sleeve is moved in the axial direction on one of the gear wheels until their internal teeth engage in a gear wheel mounted on the coupling teeth. The internal toothing of the sliding sleeve is then engaged both with the coupling teeth and with the external toothing of the synchronizer body. The gearboxes comprise for axial displacement of the sliding sleeve switching elements, in particular shift forks or shift rockers. In this case, the switching elements engage with driver elements in a circumferential groove of the sliding sleeve, wherein a movement of the switching element is transmitted relative to a housing on the sliding sleeve.

A shift fork is either axially displaceable mounted on a stationary switching axis or fixedly connected to this and together displaceable. Such shift forks are for example from the DE 103 60 715 A1 and DE 100 45 506 A1 known.

By contrast, a rocker arm is pivoted about an axis of rotation to move the sliding sleeve in the axial direction.

There are already different versions of such rocker arm is known, which has a U-shaped base body with switching cheeks and interconnecting base element, wherein on the base member, a driver element is provided, which can be moved by a sidelock actuator for pivoting the rocker arm about an axis of rotation. The main body is made in one piece from sheet steel.

After EP 0 384 158 B1 the driver element is fastened with a pin-shaped extension via a press fit in a recess in the base element. From the EP 1 746 312 B1 It is known that the cam member is formed from a punched-out portion which is bent out of the plane of the base member or the shift cheek.

The DE 199 19 270 B4 and DE 199 19 271 B4 disclose a rocker arm, which has a U-shaped base body with switching cheeks and these interconnecting base element. The basic body is manufactured in one piece from sheet steel in the punching and bending process.

The DE 10 2007 010 362 A1 discloses a rocker arm, which forms a multi-part main body, which has switching cheeks and a base element connecting them together. The base member is formed as a mold rail and comprises perpendicular to their longitudinal direction bent shift cheeks which engage around the sliding sleeve laterally. The shift cheeks and the base element are rigidly connected to each other via a joint connection.

The invention has for its object to provide a switching element that allows production with tightest manufacturing tolerances and is characterized by its high rigidity.

The object of the invention is solved by the features of claim 1. It is advantageous that the base element and / or the shift cheeks are made in lightweight construction and can withstand high torsional and modulus even at low wall thicknesses. Thus, high switching forces can be transmitted to a sliding sleeve with the switching element. In addition, the prefabricated base element and the prefabricated shift cheeks, which are produced separately from each other, can be joined together by positioning or alignment operations in their aligned relative positions. In the joining process, such as beam welding, the shift cheeks and the base member are fixed in their relative positions, so that the prefabricated with high individual accuracy components can be joined to form a switching element, which compared to such known from the prior art switching elements with one-piece body, with far from higher Manufacturing accuracy can be produced. Likewise, a cost-effective production of the switching element is possible.

If the base element is formed by a self-contained tube profile, as described in claim 2, this has a very high resistance moment and generates a high rigidity in the switching element. In addition, a tubular profile with circular cylindrical circumference can be made very easily.

The embodiments according to claims 3 and 4 are advantageous because the positioning or alignment processes are facilitated via the contact surface (s). The (automated) joining system can be set up with simpler clamping devices and operated reliably.

If the base element is equipped with a guide device as described in claim 5, the size of a switching device can be minimized, since an additional guide device can be omitted separately from the switching device in the transmission housing. In addition, the switching device forms a self-contained unit with all the switching operation serving functional elements / areas. For axially securing a transmission element on the base element, the guide device has at least two guide elements receiving the transmission element between them, as described in claim 6.

The guide elements can be produced in different ways. In an advantageous embodiment of the invention, the guide elements are formed by the base element, as described in claim 7. The guide elements are formed by a forming process of the material of the base member. For example, according to one embodiment, the guide elements are each formed from a partially stamped or punched-out material section, which is bent out of the base element in at least one of its processing steps in a forming process. According to another embodiment variant, the guide elements are each formed from a material section of the base element produced exclusively by forming, which is designed by an example crescent-shaped setting and forms a guide nose. According to another embodiment, the guide elements are formed by components produced separately from the base element, which are joined with a cohesive joint connection with the base element.

According to the statements in claims 8 and 9, a pivot angle between a switching element and a transmission element can be limited by means of the assembly and / or transport lock. As a result, on the one hand, the assembly of a device equipped with at least one or two switching element (s) switching device in a transmission housing and on the other hand, the packaging of a variety of switching elements or switching devices on containers (pallets) is facilitated. It is particularly advantageous that now the packaging can also be taken over by an automated packaging handling. According to one embodiment variant, the locking element is formed from a material section of the base element produced exclusively by deformation, which is designed by an example crescent-shaped adjustment.

Another advantage is the embodiment according to claim 10, according to which the base element is a formed from thin sheet metal forming part. The base element can be produced at low cost, especially in mass production. The consumption of material for the production of such a base element is low. The thin sheet material allows almost unlimited designs. It can non-cutting forming processes, in particular methods for cold forming of sheets, such as bending, pressing, embossing and the like., Are used. The deformation of the sheet takes place in an accuracy that can be realized within narrow position and shape tolerances of the switching elements. Machining can usually be omitted.

In accordance with claim 11, the shift cheek (s) is a console-shaped formed from thin sheet metal formed forming part and thus can transmit high switching forces on the sliding sleeve.

The embodiment according to claim 12 provides that the switching cheeks are formed by a self-contained tube profile with a substantially rectangular or trapezoidal cross-section. As a result, the shift cheeks can withstand the highest torsional and resistive torques. Likewise, the switching cheeks give the switching element a high rigidity. The switching cheeks therefore have four wall parts. According to one embodiment, the shift cheek having a one-piece U-profile body, which is at least partially covered on its open side with the fourth wall part. The fourth wall part is connected via a cohesive joint connection, in particular welding, adhesive or soldered seams, with the other wall parts of the U-profile body to the tube profile. According to another embodiment, the switching cheek can have four separate wall parts, which are connected to one another via a cohesive joint connection, in particular welding, adhesive or soldered seams to the pipe profile.

Advantageous developments of the shift cheeks are described in claims 13 to 16. In particular, it is advantageous if the profile body of the switching cheek (s) is formed in the longitudinal and / or transverse plane of the switching element with changing in the longitudinal direction of the cross-sectional dimensions. The longitudinal plane extends between the switching cheeks parallel to the switching direction and the longitudinal axis parallel to the transverse plane of the switching element. The cross-sectional dimensions of the profile body may vary depending on the rigidity and application requirements of the switching element can be selected. The design and arrangement of the shift cheek as a U-profile or pipe profile with adapted to the mechanical stresses in the longitudinal extent of the switching cheek cross-sectional dimensions cross-sectional dimensions causes a significant stiffening of the switching element both in the transverse plane of the switching element and in the longitudinal plane of the switching element (switching direction 21 ). Due to the special shape of the switching cheeks and / or the base element and the stiffening of the switching element thus obtained now the shift cheeks or their wall parts can be formed with thin walls, so even compared to the switching elements known from the prior art, a significant reduction in the weight of the switching element is reached.

If the shift cheeks are constructed in several parts, as described in claim 17, the wall parts are initially produced separately, for example, by stamping and optionally forming and then joined together in an automated joining system. Although more complex clamping devices are required by the higher number of separate wall parts, but the punching and forming processes for the wall parts can be made simpler and the wall parts are made as such with a high dimensional and dimensional accuracy.

If, in contrast, the shift cheeks are configured in one piece, as described in claim 18, the joining process following the punching and forming process is simplified.

A particularly simple possibility of positioning or alignment of the relative positions on the one hand between the shift cheeks and on the other hand between the shift cheeks and the base element is achieved via the contact portions, as described in claims 19 and 20.

An advantageous embodiment of the invention is also described in claim 21, since the brackets can be positioned relative to the shift cheeks or base element for setting a distance measure between the brackets and for the mutual alignment process on the receiving surface. The receiving surface of the switching cheeks and mounting surface of the brackets each have a surface dimension, wherein the surface dimension of one of the receiving and mounting surfaces is sized larger than the surface dimension of the other receiving and mounting surface, so that the recording and mounting surfaces overlap each other. Preferably, a surface dimension of the receiving surface is greater than a surface dimension of a mounting surface of a holder. The separate production of the brackets of the shift rails and the subsequent joining process of the brackets on the shift cheeks, now allows independent of any form and / or dimensional variations of the shift cheeks exact positioning or alignment of the brackets. Are the brackets positioned and aligned with each other, are receiving holes of the brackets opposite each other and their bore axes are aligned with each other and parallel to the longitudinal axis of the base member. Thus, the guiding accuracy of the (r) driver elements (s) is significantly improved in a circumferential groove of the sliding sleeve and thus reduces the wear due to friction between the driver element and the sliding sleeve.

An advantageous embodiment of the switching element is described in claim 22.

The invention is also based on the object of specifying a switching element and a method for the production thereof, which allows a simple and cost-effective production of the formwork element in the context of tightest manufacturing tolerances.

The object of the invention is achieved by the features and measures of claims 23 and 36. It is advantageous that by the separate production of the holder or

Brackets of the main body and the subsequent joining process of the holder (s) with the body now allows independent of any shape and / or dimensional deviations of the body exact positioning or alignment of the holder (s). If the base body is equipped with two holders and the holders are positioned on the base body and aligned with one another, receiving bores of the holders face each other and their bore axes are aligned with one another. Thus, the guiding accuracy of the (r) driver elements (s) is significantly improved in a circumferential groove of the sliding sleeve and thus reduces the wear due to friction between the driver element and the sliding sleeve.

An advantageous embodiment is described in claim 24. The receiving surface on the base body and mounting surface of the holder each have a surface dimension, wherein the surface dimension of the receiving or mounting surface is sized larger than the surface dimension of the mounting or receiving surface, so that the recording and mounting surfaces overlap each other. Preferably, a surface dimension of the receiving surface is greater than a surface dimension of the mounting surface of a holder. In the bearing bore a bearing journal is held by a driving element connected thereto.

According to a preferred embodiment, the main body is designed in several parts, as described in claim 25 and 28. This makes it possible to produce a base body with very high dimensional and / or dimensional accuracy. In the joining process, such as beam welding, the shift cheeks and the base member are fixed in their relative positions, so that the prefabricated with high individual accuracy components can be joined to form a switching element, which compared to such known from the prior art switching elements with one-piece body, with far from higher Manufacturing accuracy can be produced.

In an advantageous embodiment, the base member and / the shift cheek is formed by a profile body, as described in claim 26 and 29.

An advantageous embodiment is also described in claim 30, since a switching movement generated by an actuating element can be transmitted directly to the switching element via the transmission element and from a driver element to a sliding sleeve. This achieves a very high level of comfort.

According to the embodiment according to claim 31, a transmission element is proposed, which has a high rigidity due to the special shape design and can now be formed with thin wall thicknesses, so that a significant reduction of the weight of the transmission element with respect to the transmission elements known from the prior art is achieved.

The invention is also based on the object of specifying a switching device and a method for the production thereof, which allows a simple and cost-effective production of the switching device.

The object of the invention is achieved by the features and measures of claims 27, 32 and 34. It is advantageous that the base element of the base body is additionally used for mounting a transmission element. In this case, the base member and the transmission element are pivotally coupled together. The additional function of the base member further components for storage of the transmission element can be saved and the switching device is characterized very compact. Also, the space volume and weight of the switching device can be optimized by the compact design.

Advantageous embodiments of the switching device are described in claim 33.

An advantageous measure is also described in claim 35, since the prefabricated with at least one switching recess transmission element is arranged to a suitable in the manufacturing process of the switching device assembly time on the base member, in particular postponed. Thus, it is possible that the transmission element is arranged on the base member and then the switching cheeks are joined in parallel at the opposite end portions with the base member. Otherwise, the transmission element can be arranged on the base element after one of the switching cheeks has already been joined to the base element. If the transmission element is located on the base element, the other switching cheek is joined to the base element. According to another embodiment, it would also be conceivable that the base element and the switching cheeks are joined together and the transmission element has a mounting opening, via which the transmission element can be arranged on the base element. The mounting opening is closed after the positioning of the transmission element on the base element via a closure element. The closure element forms in this case a portion of the shift gate.

The main body can be prepared by its multi-part design according to the measures in claims 37 and 38 with very high dimensional and / or dimensional accuracy. Even form and / or dimensional deviations on the shift cheeks and the base member can be compensated to a limited extent by specific positioning or alignment operations on the one hand between the first and second shift cheek and on the other hand between the shift cheeks and the base member. In the subsequent joining process, such as beam welding, the switching cheeks and the base element are fixed in their relative positions.

For a better understanding of the invention, this will be explained in more detail with reference to the following figures.

Each shows in a highly schematically simplified representation:

1 a switching device with switching elements, in particular switching rockers, for the axial displacement of sliding sleeves and these coupling elements together, in a perspective view;

2a . 2 B different views of a first switching element, in perspective view;

3a . 3b different views of a second switching element, in perspective view;

4 the switching device with the transmission elements according to 1 in plan view;

5 the transmission elements in side view according to the lines A, B, C in 4 ;

6 another embodiment of a transmission element, in sectional view.

By way of introduction, it should be noted that in the differently described embodiments, the same parts are provided with the same reference numerals or the same component names, wherein the disclosures contained in the entire description can be mutatis mutandis to the same parts with the same reference numerals or component names. Also, the location selected in the description, such as. B. top, bottom, side, etc. related to the immediately described and illustrated figure and are mutatis mutandis to transfer to a new position on a change in position.

In the 1 is a switching device 1 a particular manually switchable motor vehicle change gear shown, which has multiple gear ratios and is designed in this embodiment for a 5-speed change gear. The switching device 1 includes a first switching element 2 , a second switching element 3 and the switching elements 2 . 3 articulated interconnecting transmission elements 4 . 5 . 6 . 7 as well as a shift and selector shaft 8th , With the first switching element 2 and the transmission element 6 can be changed between the first and second gear. With the second switching element 3 and the transmission element 5 can be changed between the third and fourth gear. With the transmission element 4 can be a fifth gear and with the transmission element 7 a reverse gear (R) can be selected. The number of switching elements 2 . 3 and transmission elements 4 . 5 . 6 . 7 thus varies depending on the number of gear ratios to be switched. The shift and selector shaft 8th is rotatable about its longitudinal axis (switching movement) and displaceable in the axial direction (Wählbewegung) mounted in a gear housing, not shown, and has at least one attached to this actuator 9 , in particular a shift finger on. The transmission elements 4 . 5 . 6 . 7 are each with a recess 10 provided, which is limited at least in sections by locking and buttons to be described later.

In cooperation with the actuator 9 Optionally one of the transmission elements 4 . 5 . 6 . 7 be subjected to a switching force by the actuator 9 initially by a selection movement of the shift and selector shaft 8th in the axial direction in one with one of the recesses 10 aligned adjustment plane shifted and then by a switching movement of the switching and selector shaft 8th is rotated about its longitudinal axis. The actuator is running 9 against one of the buttons ( 5a - 5d ) of a transmission element 4 . 5 . 6 . 7 on and shifts a gear.

In the jointly described 2a and 2 B is the first switching element 2 shown in different views. The switching element 2 , which is formed by a shift rocker according to this embodiment, is fork-shaped and forms a substantially U-shaped, multi-part body, which is a base element 15 and shift cheeks 16a . 16b includes. Both the basic element 15 as well as the shift cheeks 16a . 16b are formed by a profile body.

The profile body of the base element 15 is formed in a preferred embodiment by a tubular profile. Preferably, the tube profile is in a chipless forming process, in particular cold forming, such as bending / pressing, made of a flat sheet steel portion in one piece and its opposite longitudinal edges in a parting plane via a cohesive joint, in particular by beam welding, such as laser welding or electron beam welding, produced joining seam 17 , are joined together. On the other hand, it is also possible that the tube profile is formed by a seamless drawn tube.

As can be seen from the figures, the base element 15 in each case additionally formed in the end-side end regions with a connection region and a guide device formed between the end regions. The connection areas have diametrically opposite contact surfaces 18 on, which in each case between the opposite end portions in the axial direction over a longitudinal portion of the base member 15 extend. The contact surfaces 18 become integral with the base element in a chipless forming process, in particular cold forming, such as embossing 15 produced.

The guide device has between the end-side end regions at least two with mutual axial distance radially to the base element 15 extending guide elements 19 on. After shown execution are the guide elements 19 diametrically opposite two other guide elements 19 , The guide elements 19 form opposing and parallel aligned guide surfaces 20 out. The axial distance between the facing each other guide surfaces 20 the guide elements 19 is slightly larger than a width dimension "B" ( 4 ) between the guide elements 19 mounted transmission elements 4 . 5 . 6 . 7 , As a result, on the one hand, a "clean" guiding function of the transmission elements 4 . 5 . 6 . 7 between the guide elements 19 on the base element 15 in the axial direction of the base element 15 and on the other hand, a smooth adjustment of the transmission elements 4 . 5 . 6 . 7 in shift direction 21 ( 4 ). The basic element 15 also forms one at least between the guide elements 19 trained and over a peripheral portion of the base member 15 extending guide surface or storage area 22 out. The guide elements 19 and the storage area 22 form the guide device. The guide elements 19 with the guide surfaces 20 and the storage area 22 become integral with the base element in a chipless forming process, in particular cold forming, such as embossing 15 produced. On the other hand, it is also possible that the guide elements 19 as one or more separate component (s) separate from the base member 15 manufactured and each with a cohesive joint connection to the base element 15 be joined with mutual axial distance. Such guide elements 19 are formed for example by disks, each having a passage opening, which on the base element 15 be deferred. Such guide elements 19 are also at the switching element 3 used.

According to the embodiment shown, the left shift cheek 16a a forming part made of thin sheet steel with a console-like shape. The shift cheek 16a has a first wall part 24a , a molded on this second and third wall part 25a . 26a as well as in a base element 15 facing first end portion formed fastening receptacle 27a and in a base member 15 remote from the second end portion trained support receptacle 28a on. Between the first end portion and second end portion is a storage area for the shift cheek 16a educated.

The first wall part 24a extends continuously between the first and second end portions of the shift cheek 16a wherein a wall portion adjacent to the first end portion 29 and a wall portion adjacent to the second end portion 30 in staggered planes and over an angled to this intermediate section 31 connected to each other.

The second and third wall part 25a . 26a are each through from the first wall section 29 angled in the same direction, in particular approximately at right angles bent wall sections 32 . 33 . 34 educated. The shift cheek 16a forms in the direction of its longitudinal extension between the end regions of an approximately U-shaped cross-sectional profile with over the longitudinal extent of changing cross-sectional dimensions.

The inclined to each other extending (upper) wall sections 32 extend starting from the first end portion in the direction of the second end portion to a maximum width dimension in a formed between the first and second end portion bearing portion of the shift cheek 16a ,

The to the (upper) wall sections 32 subsequent (middle) wall sections 33 extend in the direction between the first and second end region in offset planes approximately parallel to a longitudinal extension of the shift cheek 16a , As can be seen in the figures, form the wall sections 32 . 33 the wall parts 25a . 26a Overlapping sections, in which the wall sections 32 . 33 via joining seams produced by beam welding, in particular electron beam welding or laser welding 35 connected to each other.

The to the (middle) wall sections 32 subsequent (lower) wall sections 34 run in staggered planes and taper from the storage area towards the second end area.

The first wall part 24a and the other wall parts 25a . 26a are in sections via joining seams produced by beam welding, in particular electron beam welding or laser welding 36 connected with each other. Preferably, the joining seams 36 in the area between the (lower) wall section 30 of the first wall part 24a and the (lower) wall section 34 the other wall parts 25a . 26a appropriate.

The joining seams 35 . 36 form a fluid connection. The described joint seams may alternatively be formed by adhesive or soldered seams to the welds.

Furthermore, the shift cheek 16a in the area of the edges between the first wall part 24a and the other wall parts 25a . 26a each bead-like formations 37 on, which lead to an additional stiffening of the formed sheet steel part. To simplify the bending operations can, if necessary, in a transition zone between the first wall part 24a and second wall part 25a and / or first wall part 24a and third wall part 26a an exemption 38 , in particular free-punching, are provided. To save weight can in one or more of the wall parts 24a . 25a . 26a additionally recesses are provided.

The shift cheek 16a is also on the wall part 24a in the storage area with a sleeve-shaped bearing seat 39a provided in which a warehouse 40a for pivotal mounting of the switching element 2 is arranged.

The attachment holder 27a , which is the left connection area of the base element 15 is assigned, is shown by execution in a the base element 15 adjacent first end portion of the shift cheek 16a on the wall parts 25a . 26a complementary to the contact surfaces 18 trained and the base element 15 partially enclosing investment sections 42a educated. The investment sections 42a each form a contact surface 41 out. On the other hand, it is also possible that the shift cheek 16a only one on one of the wall parts 24a . 25a . 26a formed complementary to a contact surface and the base element 15 partially encompassing investment section is formed. The investment section 42a forms a contact surface 41 out.

The holder holder 28a , which in a the base element 15 remote from the second end portion of the shift cheek 16a is arranged, is shown by execution of the wall parts 25a . 26a one-piece tabs produced in a stamping and / or forming process 43a educated. The holder holder 28a forms a receiving surface 44a out, on which a bracket 45a in one of the longitudinal extent of the shift cheek 16a vertical direction across the base element 15 (ie, in the switching direction 21 ) and / or in a longitudinal extent of the shift cheek 16a vertical direction parallel to the base element 15 is positionable. The reception area 44a preferably runs approximately perpendicular to the longitudinal extent of the shift cheek 16a , The holder 45a comes with a mounting surface on the receiving surface 44a attached and over by welding, in particular laser welding or electron beam welding, produced joining seams 46 with the shift cheek 16a , especially at the tabs 43a with the first and second wall part 25a . 26a connected. The holder 45a has a mounting base with one of the receiving surface 44a facing mounting surface and a (not shown) receiving bore for a journal 47a a driving element connected to this 48a on, so that the driver element 48a opposite the bracket 45a is rotatably mounted. The driver element 48a is through a circlip 49a in the holder 45a held in the axial direction.

According to the embodiment shown is the right shift cheek 16b a forming part made of thin sheet steel with a console-like shape. The shift cheek 16b has a first wall part 24b , a molded on this second and third wall part 25b . 26b as well as in a base element 15 facing first end portion formed fastening receptacle 27b and in a base member 15 remote from the second end portion trained support receptacle 28b on. Between the first end portion and second end portion is a storage area for the shift cheek 16b educated.

The first wall part 24b extends continuously between the first and second end portions of the shift cheek 16b wherein a wall portion adjacent to the first end portion 50 and a wall portion adjacent to the second end portion 51 in angularly aligned planes.

The second and third wall part 25b . 26b are each through from the first wall section 50 angled in the same direction, in particular approximately at right angles bent wall sections 52 . 53 educated. The shift cheek 16b forms in the direction of its longitudinal extension between the end regions of an approximately U-shaped cross-sectional profile with over the longitudinal extent of changing cross-sectional dimensions.

The inclined to each other extending (upper) wall sections 52 extend in staggered planes and extend starting from the first end region in the direction of the second end region to a maximum width dimension in a bearing region of the switching cheek formed between the first and second end region 16b ,

The to the (upper) wall sections 52 subsequent (lower) wall sections 53 extend in the direction between the first and second end region in offset planes approximately parallel to a longitudinal extension of the shift cheek 16b ,

The first wall part 24b and the other wall parts 25b . 26b are in sections via joining seams produced by beam welding, in particular electron beam welding or laser welding 54 connected with each other. Preferably, the joining seams 54 in the area between the (lower) wall section 51 of the first wall part 24b and the (lower) wall section 53 the other wall parts 25b . 26b appropriate.

The joining seams 54 form a fluid connection. The described joint seams may alternatively be formed by adhesive or soldered seams to the welds.

Furthermore, the shift cheek 16b to simplify the bending operations when needed in a transition zone between the first wall part 24b and second wall part 25b and / or first wall part 24b and third wall part 26b with an exemption 38 , in particular free-punching trained. To save weight can be in one or several of the wall parts 24b . 25b . 26b additionally recesses are provided.

The shift cheek 16b is also on the wall part 24b in the storage area with a sleeve-shaped bearing mount 39b provided in which a warehouse 40b for pivotal mounting of the formwork element 2 is arranged.

The basic element 15 runs parallel to one of the bearing receptacles 39a . 39b the shift cheeks 16a . 16b defined pivot axis.

The attachment holder 27b , which is the right connection area of the base element 15 is assigned, is shown by execution in a the base element 15 adjacent first end portion of the shift cheek 16b on the wall parts 25b . 26b complementary to the contact surfaces 18 trained and the base element 15 partially enclosing investment sections 42b educated. The investment sections 42b each form a contact surface 41 out. On the other hand, it is also possible that the shift cheek 16b only one on one of the wall parts 24a . 25a . 26a formed complementary to a contact surface and the base element 15 partially encompassing investment section is formed. The investment section 42b forms a contact surface 41 out.

The holder holder 28b , which in a the base element 15 remote from the second end portion of the shift cheek 16b is arranged, is shown by execution of the wall parts 25b . 26b one-piece tabs produced in a stamping and / or forming process 43b educated. The holder holder 28b forms a receiving surface 44b out, on which a bracket 45b in one of the longitudinal extent of the shift cheek 16b vertical direction across the base element 15 (ie, in the switching direction 21 ) and / or in a longitudinal extent of the shift cheek 16b vertical direction parallel to the base element 15 is positionable. The reception area 44b preferably runs approximately perpendicular to the longitudinal extent of the shift cheek 16b , The holder 45b comes with a mounting surface on the receiving surface 44a attached and over by welding, in particular laser welding or electron beam welding, produced joining seams 46 with the shift cheek 16b , especially at the tabs 43b with the first and second wall part 25b . 26b connected. The holder 45b has a mounting base with one of the receiving surface 44b facing mounting surface and a (not shown) receiving bore for a journal 47b a driving element connected to this 48b on, so that the driver element 48b opposite the bracket 45b is rotatably mounted. The driver element 48b is through a circlip 49b in the holder 45b held in the axial direction.

As in the 2a and 2 B Obviously, the shift cheeks 16a . 16b with the mounting shots 27a . 27b , in particular their abutment sections 42a . 42b at the contact surfaces 18 in the opposite end regions of the base element 15 applied and via seam welding produced by beam welding, in particular laser welding or electron beam welding 55a . 55b connected.

In the jointly described 3a and 3b is the second switching element 3 shown in different views. The switching element 3 , which is formed by a shift rocker according to this embodiment, is fork-shaped and forms a substantially U-shaped, multi-part body, which is a base element 65 and shift cheeks 66a . 66b includes. Both the basic element 65 as well as the shift cheeks 66a . 66b are formed by a profile body.

The profile body of the base element 65 is formed in a preferred embodiment by a tubular profile, which in the manner described above as the base element 15 in a chipless forming process, in particular cold forming, such as bending / pressing, made in one piece from a flat sheet steel section and the opposite longitudinal edges in a parting plane via a cohesive joint, in particular produced by beam welding joint seam 17 are joined together. On the other hand, it is also possible that the tube profile is formed by a seamless drawn tube.

As can be seen from the figures, the base element 15 in each case additionally formed in the end-side end regions with a connection region and a guide device formed between the end regions. The connection areas have diametrically opposite contact surfaces 18 on, which in each case between the opposite end portions in the axial direction over a longitudinal portion of the base member 65 extend and prepared as described above.

The guide device has, as described above, between the end-side end portions at least two with mutual axial distance radially to the base member 65 extending guide elements 19 on. After shown execution are the guide elements 19 diametrically opposite two other guide elements 19 , The guide elements 19 form opposing and parallel aligned guide surfaces 20 out. The axial distance between the mutually facing guide surfaces 20 the guide elements 19 is slightly larger than a width dimension "B" ( 4 ) between the guide elements 19 mounted transmission elements 4 . 5 . 6 . 7 ,

The basic element 65 also forms one at least between the guide elements 19 and over a peripheral portion of the base member 15 extending guide surface or storage area 22 out. The guide elements 19 and the storage area 22 form the guide device.

A particularly economical production of the base element 15 . 65 can be realized if for each base element 15 . 65 a flat metal strip, preferably endless of a coil, a punching and forming device, in particular a follow-on composite tool, on and is passed through them and progressively passes punching and forming stations. In this process, a large number of blanks or blanks is punched out of the metal strip in a stamping process and this in a forming process (bending, pressing, rolling, embossing, calibrating) in one or more successive forming step (s) with the contact surfaces 18 , Guide elements 19 and guide surfaces 20 shaped and the described base element 15 . 65 rolled. The production of the base element 15 . 65 can be done almost without waste. By optionally subsequent calibration of the formed into a tube profile blank, the base element 15 . 65 in the functional areas, therefore in the connection area 18 or leadership area 19 . 20 . 22 , are processed to the required dimensional and form tolerance. The design of the base element 15 . 65 provides that this does not require any mechanical reworking after all forming operations have been carried out.

In a joining process subsequent to the stamping and forming process, the blank, which is shaped into a tube profile and whose longitudinal edges abut one another in a parting plane, is joined in a joining region defined by the adjoining longitudinal edges by means of a cohesive joining connection 17 joined together. The wall thickness of the base element made of thin sheet steel 15 . 65 is between 1 mm and 4 mm, for example 2 mm.

According to the embodiment shown, the left shift cheek 66a and the right shift cheek 66b in each case a forming part made of thin sheet steel with a console-like shape. The shift cheek 66a . 66b has a first wall part 67a . 67b a formed on this second and third wall part 68a . 68b . 69a . 69b as well as in a base element 65 facing first end portion formed fastening receptacle 70a . 70b and in a base member 65 remote from the second end portion trained support receptacle 71a . 71b on. Between the first end portion and second end portion is a storage area for the shift cheek 66a . 66b educated.

The first wall part 67a . 67b extends with a wall section 72 continuously between the first and second end portions of the shift cheek 66a ,

The second and third wall part 68a . 68b . 69a . 69b are each through from the first wall section 72 angled in the same direction, in particular approximately at right angles bent wall sections 73 . 74 . 75 educated. The shift cheek 66a Forms in its longitudinal extent between the end regions of an approximately U-shaped profile with over the longitudinal extent of changing cross-sectional dimensions.

The inclined to each other extending (upper) wall sections 73 extend starting from the first end portion in the direction of the second end portion to a maximum width dimension in a formed between the first and second end portion bearing portion of the shift cheek 66a . 66b ,

The to the (upper) wall sections 73 subsequent (middle) wall sections 74 extend in the direction between the first and second end region in offset planes approximately parallel to a longitudinal extension of the shift cheek 66a . 66b ,

The to the (middle) wall sections 74 subsequent (lower) wall sections 75 run in staggered planes and taper from the storage area towards the second end area.

Furthermore, the shift cheek 66a . 66b to simplify the bending operations when needed in a transition zone between the first wall part 67a . 67b and second wall part 68a . 68b and / or first wall part 67a . 67b and third wall part 69a . 69b with an exemption 38 , in particular free-punching trained. To save weight can in one or more of the wall parts 68a . 68b . 69a . 69b additionally recesses are provided.

The shift cheek 66a . 66b is also on the wall part 67a . 67b in the storage area with a sleeve-shaped bearing mount 39a . 39b provided in which a warehouse 40a . 40b for pivotal mounting of the switching element 3 is arranged.

The basic element 65 runs parallel to one of the bearing receptacles 39a . 39b the shift cheeks 66a . 66b defined pivot axis.

The mounting shots 70a . 70b , which the opposite connection areas of the base element 65 are assigned, are shown by execution in each case by a base element 65 adjacent first end portion of the shift cheek 66a . 66b on the wall parts 68a . 68b . 69a . 69b complementary to the contact surfaces 18 trained and the base element 65 partially enclosing investment sections 42a . 42b educated. On the other hand, it is also possible that the shift cheek 66a . 66b only one on one of the wall parts 67a . 67b . 68a . 68b . 69a . 69b formed complementary to a contact surface and the base element 65 partially encompassing investment section is formed.

The bracket mounts 71a . 71b , each in a base element 65 remote from the second end portion of the shift cheek 66a . 66b are arranged, are shown by execution of the wall parts 68a . 68b . 69a . 69b one-piece tabs produced in a stamping and / or forming process 43a . 43b educated. The holder holder 71a . 71b forms a receiving surface 44a . 44b out, on which a bracket 45a . 45b in the manner described above relative to the shift cheek 66a . 66b is positionable. The reception area 44a . 44b preferably runs approximately perpendicular to the longitudinal extent of the shift cheek 66a . 66b ,

The holder 45a . 45b comes with a mounting surface on the receiving surface 44a attached and over by welding, in particular laser welding or electron beam welding, produced joining seams 46 with the shift cheek 66a , especially at the tabs 43a with the second and third wall part 68a . 69a connected. About these joints 46 are at the same time the first wall part 67a . 67b and the other wall parts 68a . 68b . 69a . 69b connected with each other. The joining seams 46 form a fluid connection. The described joint seams 46 may alternatively be formed by adhesive or soldered seams to the welds.

The brackets 45a . 45b each have a mounting base with one of the receiving surface 44a facing mounting surface and a (not shown) receiving bore for a journal 47a each one (not shown) receiving bore for a journal 47a . 47b a connected with these, arcuate or sickle-like driver element 76 on, so that the driver element 76 opposite the brackets 45a . 46b is rotatably mounted. The driver element 78 will be between the brackets 45a . 46b held in the axial direction.

A particularly economical production of the shift cheeks 16a . 16b . 66a . 66b can be realized if for each of the shift cheeks 16a . 16b . 66a . 66b a flat metal strip, preferably endless of a coil, a punching and forming device, in particular a follow-on composite tool, on and is passed through them and progressively passes punching and forming stations. In this case, a plurality of blanks or blanks is punched out of the sheet metal strip in a stamping process and this in a forming process (bending, pressing, stamping, calibrating) in one or more successive forming step (s) with the wall parts 24a to 26b . 67a to 69b with the formations 37 , Recesses, exemptions 38 , Bearing shots 39a . 39b , Plant sections 42a . 42b , Tabs 43a . 43b , Reception areas 44a . 44b shaped. The production of the shift cheeks 16a . 16b . 66a . 66b can be done almost without waste. By an optionally subsequent calibration of the formed into a tube profile blank, the shift cheeks 16a . 16b . 66a . 66b in the functional areas, therefore the bearing mounts 39a . 39b , Plant sections 42a . 42b and / or receiving surfaces 44a . 44b , are processed to the required dimensional and form tolerance. The design of the shift cheeks 16a . 16b . 66a . 66b provides that this does not require any mechanical reworking after all forming operations have been carried out.

In a joining process following the punching and forming process, the blank, which has been shaped into a U-profile, for example, becomes the switching cheeks 16a . 16b . 66a . 66b in defined joining areas via cohesive joining connections 46 joined together.

Preferably, the shift cheeks 16a . 16b . 66a . 66b in the described non-cutting punching and forming process of a flat sheet steel section made in one piece and their wall parts 24a to 26b . 67a to 69b in sections via cohesive joints 35 . 36 . 46 . 54 are joined together to form a profile body. The entire shift cheek 16a . 16b . 66a . 66b is thus formed from a stamped and formed sheet steel part of approximately constant wall thickness. The wall thickness of the switching cheek made of thin sheet steel 16a . 16b . 66a . 66b is between 1 mm and 4 mm, for example 2 mm.

Another not shown embodiment of the shift cheeks 16a . 16b . 66a . 66b is that the wall parts 24a to 26b . 67a to 69b , the mounting shots 27a . 27b and / or bracket mounts 28a . 28b each produced separately as stamped and / or formed parts and the individual punched and / or formed parts are connected to one another via a cohesive joint connection, in particular welding, adhesive or soldered seams. Is the shift cheek 16a . 16b . 66a . 66b formed by a tubular profile, this has in addition to the wall parts 24a to 26b . 67a to 69b a fourth wall part 23a . 23b on, as exemplified in 2a only on the shift cheek 16b entered in dotted lines. The fourth wall part 23a . 23b is manufactured as a stamped and / or formed part and over a cohesive joint connection with the projecting end edges of the second and third wall part 25a . 26a . 25b . 26b . 68a . 69a . 68b . 69b connected. The fourth wall part 23a . 23b can also be formed by a plurality of separate wall sections, wherein the (upper) first wall portion with the wall portion 32 . 52 the shift cheeks 16a . 16b or wall section 72 the shift cheeks 66a . 66b and the (lower) second wall portion with the wall portion 33 . 34 . 53 the shift cheeks 16a . 16b or wall section 75 the shift cheeks 66a . 66b connected is.

As in the 3a and 3b Obviously, the shift cheeks 66a . 66b with the mounting shots 27a . 27b , in particular their abutment sections 42a . 42b at the contact surfaces 18 in the opposite end regions of the base element 65 applied and via seam welding produced by beam welding, in particular laser welding or electron beam welding 55a . 55b connected.

The shift cheeks described above 16a . 16b . 66a . 66b can over the contact surface (s) 18 in the connection area and / or contact area (s) 41 of the investment section (s) 42a . 42b (in a first direction) in the direction of a longitudinal extent of the base element 15 . 65 to a required distance 55 (Switching mouth width) and / or (in a second direction) in the tangential direction to the base element 15 . 65 to a required reference level 56 and / or (in a third direction switching direction 21 ) in the circumferential direction of the base member 15 . 65 to a required reference level 57 be positioned. This positioning can be done via a positioning device having, for example, opposing positioning pins with a diameter shoulder, the positioning pin section with a smaller diameter in the bearing receptacle 39a . 39b is introduced while the positioning pin portion of larger diameter against the end edge of the bearing support 39a . 39b is created. Are the prefabricated shift cheeks 16a . 16b . 66a . 66b and the prefabricated base element 15 . 65 aligned in the three spatial directions in their relative position to each other, the shift cheeks 16a . 16b . 66a . 66b and the base element 15 . 65 over the joining seams 55a . 55b connected with each other.

After that, the brackets 45a . 45b on the receiving surfaces 44a . 44b relative to the shift cheeks 16a . 16b . 66a . 66b (in a first direction) in the direction of a longitudinal extent of the base element 15 . 65 to a required distance 58 and / or (in a second direction switching direction 21 ) in the circumferential direction of the base member 15 . 65 to a required reference level 59 positioned. Are the brackets 45a . 45b positioned and aligned with each other, are the mounting holes of the brackets 45a . 45b opposite each other and their bore axes are aligned with each other.

Due to the additional positioning possibility of the brackets 45a . 45b relative to the shift cheeks 16a . 16b . 66a . 66b can a particularly high manufacturing accuracy of the switching element 2 be achieved. Thus, it is also possible that the rotatable in the mounting receptacles 45a . 45b mounted driver elements 48a . 48b . 76 each precisely engages in a circumferential groove not shown sliding sleeves of the transmission form-fitting and thus wear phenomena are significantly reduced. Between the shift cheeks 16a . 16b of the first switching element 2 a Schaltmaul is formed, in which the first sliding sleeve are partially received and between the shift cheeks 66a . 66b of the second switching element 3 a switching jaw is formed in which the second sliding sleeve are partially received.

On the other hand, according to another embodiment (not shown) it is also possible that the shift cheeks 16a . 16b . 66a . 66b , in particular at least one of the wall parts 24a to 26b . 67a to 69b each holder 45a . 45b form, which one-piece with the shift cheek 16a . 16b . 66a . 66b in a non-cutting punching and / or forming process, in particular cold forming, such as bending / pressing / deep drawing, are produced. The holder 45a . 45b has according to this embodiment, only a receiving device, in particular a sleeve-like shaped bearing mount, in which the bearing pin 47a . 47b is stored.

In the 4 and 5 are the switching device 1 according to 1 with the exception of the shift and selector shaft 8th in plan view and the transmission elements 4 . 5 . 6 . 7 shown in side view.

In 5a (Sectional view A) is the transmission element 4 shown for the fifth gear. This is designed as a shift rail and has a rail body and in a first end portion of this angled shift lever 80 on. In the rail body are Schaltausnehmungen 81 and between these a shift gate 82 educated. The switching recesses 81 have at mutual distance mutually parallel guide surfaces 83 and a switching movement in the switching direction 21 limiting stop surfaces 84 on. Thus form the Schaltausnehmungen 81 Elongated holes. After shown execution run the guide surfaces 83 arcuate. The shift gate 82 , which sections by the contour of the recess 10 is formed in sections by buttons 85 and restricted areas 86 limited. The buttons 85 are aligned plane-parallel to each other and transmit a switching force from the actuator 9 ( 1 ) on the transmission element 4 , The clear distance between the buttons 85 is slightly larger than a width of the actuator 9 so that this between the buttons 85 can be included when the shift and selector shaft 8th with the actuating element 8th relative to the transmission element 4 was positioned. By a switching movement, the switching and selector shaft 8th twisted about its longitudinal axis, so that the actuator 9 against the left or right button 85 runs up and the transmission element 4 between a neutral and switching position relative to the switching elements 2 . 3 or basic elements 15 . 65 in shift direction 21 emotional. The restricted areas 86 are formed by an exemption and enclose an angle between them. In a switching position of one of the other transmission elements 5 . 6 . 7 can the shift and selector shaft 8th engage in the release and with its outer periphery a movement of the transmission element 4 lock or prevent from a neutral position.

In 5b (Sectional view B) is the transmission element 5 shown for the third and fourth gear. This is designed as a shift rail and has a rail body. In the rail body are Schaltausnehmungen 87 . 88 and between these a shift gate 82 educated. The switching recess 87 is through a hole with on the outer circumference of the base member 65 at least partially complementary guide surface 89 educated. The switching recess 88 corresponds to the above-described Schaltausnehmung 81 and has at mutual distance mutually parallel guide surfaces 83 and a switching movement in the switching direction 21 limiting stop surfaces 84 on. Thus forms the Schaltausnehmung 88 a slot recess.

By a switching movement, the switching and selector shaft 8th twisted about its longitudinal axis, so that the actuator 9 against the left or right button 85 runs up and the transmission element 5 by the coupling connection with the base member 65 the switching element 3 in shift direction 21 either switched to a shift position for the third or fourth gear. In this case, the transmission element 5 between a neutral position and one of the switching positions relative to the switching element 2 or basic element 15 in shift direction 21 emotional.

In 5c (Sectional view C) is the transmission element 6 shown for the first and second gear. This is designed as a shift rail and has a rail body. In the rail body are the Schaltausnehmungen 87 . 88 mirrored to the switching recesses in the transmission element 5 arranged and is between these a shift gate 82 educated.

By a switching movement, the switching and selector shaft 8th twisted about its longitudinal axis, so that the actuator 9 against the left or right button 85 runs up and the transmission element 6 by the coupling connection with the base member 15 the switching element 2 in shift direction 21 switched either in a switching position for the first or second gear. In this case, the transmission element 6 between a neutral position and one of the switching positions relative to the switching element 3 or basic element 65 in shift direction 21 emotional.

In 5d (Sectional view D) is the transmission element 7 shown for reverse. This is designed as a shift rail and has a rail body and arranged in a first end region hinge axis 90 on. A shift fork 91 is via an articulated arm 92 on the one hand via the joint axis 90 with the transmission element 7 and on the other hand via another joint axis 93 with a fastening device 94 articulated. The fastening device 94 is in turn connected to the transmission housing.

In the rail body are Schaltausnehmungen 81 and between these a shift gate 82 educated. The switching recesses 81 have at mutual distance mutually parallel guide surfaces 83 and a switching movement in the switching direction 21 limiting stop surfaces 84 on, as in above 5a described.

By a switching movement, the switching and selector shaft 8th twisted about its longitudinal axis, so that the actuator 9 against the left or right button 85 runs up and the transmission element 7 between a neutral and switching position relative to the switching elements 2 . 3 or basic elements 15 . 65 in shift direction 21 emotional.

As in 5d also visible, is the base element 65 equipped with a transport safety device. This has at least one particular cam-like locking element 98 which, in a chipless forming process, in particular cold forming, such as embossing, integral with the base element 65 manufactured or as a separate component with the base element 65 is connected. The transmission element 7 is with a recess 99 provided, in which the locking lug 98 can protrude. The recess 99 has a (arc) length which is several times the length of the locking element 98 equivalent. As in 1 shown schematically, the switching cheeks can for transport and / or assembly purposes 16a . 16b . 66a . 66b around the longitudinal axes 100 the basic elements 15 . 65 from a month position indicated by a fixed line 101 in a direction indicated by a dashed line transport and / or mounting position 102 be panned. On the pivoting movement becomes the base element 65 in the switching recess 81 towards the recess 99 moved so that the locking element 98 and the recess 99 engage in each other in the radial direction to the base element. By the (arc) length of the recess 99 becomes a swivel angle 103 limited and thus an angular position of the switching element 3 relative to the transmission element 7 Are defined. Also, the base element 15 additionally equipped with a transport safety device.

As shown in the figures, the rail body of the transmission element 5 at its opposite side surfaces with projecting in these opposite direction support elements 95 . 96 and the rail body of the transmission element 6 at one of its opposite side surfaces with on this projecting support elements 96 Mistake. The transmission element 4 . 5 . 6 . 7 are about the support elements 95 . 96 , in particular support cams, with one another in the longitudinal direction of the base element 15 . 65 guided.

How out 4 can be seen, is between the closely juxtaposed transmission element 4 . 5 . 6 . 7 and the guide elements 19 formed a clearance, so as to allow a particularly smooth shifting. The guide elements 19 facing side surfaces 97 but can be at the guide surfaces 20 come to the plant.

Preferably, the transmission elements 4 . 5 . 6 . 7 each in a non-cutting punching and forming process, in particular cold forming, such as (bending, pressing, rolling, embossing, calibrating) made in one piece from a flat sheet steel section. The wall thickness of the transmission elements made of thin sheet steel 4 . 5 . 6 . 7 is between 4 mm and 6 mm, for example 5 mm.

A particularly economical production of the transmission elements 4 . 5 . 6 . 7 can be realized if for each transmission element 4 . 5 . 6 . 7 a flat metal strip, preferably endless of a coil, a punching and forming device, in particular a follow-on composite tool, on and is passed through them and progressively passes punching and forming stations. In this case, a plurality of blanks or blanks is punched out of the sheet metal strip in a stamping process and this in a forming process (bending, pressing, rolling, embossing, calibrating) in one or more successive forming step (s) with the Schaltausnehmungen 81 . 87 . 88 , Recesses 10 or shift gate 82 , Support elements 95 . 96 , Side surfaces 97 and optionally the recess 99 shaped. The production of the base element 15 . 65 can be done almost without waste. The design of the transmission elements 4 . 5 . 6 . 7 provides that this does not require any mechanical reworking after all forming operations have been carried out.

Another based on the transmission element 6 in 6 schematically illustrated embodiment of the transmission elements 4 . 5 . 6 . 7 is that these, for reasons of weight reduction, one of thin sheet metal, less than 4 mm, for example, between 2 mm and 3 mm, non-cutting shaped forming part 104 are formed. The formed part 104 has an angled edge of the sheet metal, circumferential edge 105 on. It is also possible that at the edge of the Schaltausnehmung 87 . 88 and / or recess 10 an angled edge web angled away from the sheet plane 106 is formed without cutting, as shown in dotted lines.

It is also possible that the transmission element 4 . 5 . 6 . 7 is formed in several parts and the forming part 104 with a graduation part 107 is added to a hollow body. For the sake of clarity, is the final part 107 in one of the forming part 104 drawn separately. The joining is preferably carried out by beam welding, in particular electron beam welding or laser welding. The final part 107 has a to the circumferential contour of the forming part 104 or edge 105 largely adapted outer contour and is formed by a simple design by a flat stamped part. An additional stiffening of the transmission element 4 . 5 . 6 . 7 is achieved, although the final part 107 is formed as a non-cutting shaped forming part and an angled from the sheet plane, circumferential edge 108 has, as indicated in dashed lines. The final part 107 also shows congruent with the Schaltausnehmungen 87 . 88 and / or the recess 10 trained recesses 109 on, which are punched out of the sheet. Also, those may be the recesses 109 each bounding edges by an angled from the sheet plane, surrounding non-cutting shaped edge web 110 be formed as shown in dotted lines.

The formed part 104 and final part 107 have the same or different wall thickness. Is the final part 107 with circumferential edge 108 formed, the wall thickness of the forming part 104 and final part 107 be reduced and in this case less than 3 mm, for example, between 1.5 mm and 2.5 mm.

Even if, according to the above statements, steel sheet is the starting material for the production of the switching elements 2 . 3 and transmission elements 4 . 5 . 6 . 7 is, any other can instead Sheet metal material may be used, for example aluminum and the like.

Furthermore, it is possible that the shift cheek 16a . 16b . 66a . 66b to increase the torsional rigidity and increase the buckling resistance on the wall parts 24a to 26b . 67a to 69b with one or more beads, doubling produced without cutting, embossing, adjustments of the sheet or folds of the sheet on the projecting edges of the wall parts 25a . 25b . 26a . 26b . 68a . 68b . 69a . 69b Mistake.

The embodiments show possible embodiments of the switching element 2 . 3 , It should be noted at this point that the invention is not limited to the specifically illustrated embodiments thereof, but rather also various combinations of the individual embodiments are possible with each other and this possibility of variation due to the teaching of technical action by objective invention in the ability of this on this technical Area professional. So are all conceivable embodiments, which are possible by combinations of individual details of the illustrated and described embodiment variant, includes the scope of protection.

In the 3 is another and possibly independent embodiment of the switching element 3 shown, again for like parts, the same reference numerals or component names as in the preceding 2 be used. To avoid unnecessary repetition, the detailed description in the previous one 2 referred or referred.

For the sake of order, it should finally be pointed out that for a better understanding of the structure of the switching device 1 or of the switching element 2 . 3 these or their components have been partially displayed off-scale and / or enlarged and / or reduced.

Above all, the individual in the 1 to 5 shown embodiments form the subject of independent solutions according to the invention.

LIST OF REFERENCE NUMBERS

1

switching device

2

switching element

3

switching element

4

transmission element

5

transmission element

6

transmission element

7

transmission element

8th

Switching and selector shaft

9

actuator

10

recess

15

base element

16a

switching cheek

16b

switching cheek

17

joint seam

18

contact surface

19

guide element

20

guide surface

21

switching direction

22

storage area

23a

wall part

23b

wall part

24a

wall part

24b

wall part

25a

wall part

25b

wall part

26a

wall part

26b

wall part

27a

mounting fixture

27b

mounting fixture

28a

bracket jig

28b

bracket jig

29

wall section

30

wall section

31

intermediate section

32

wall section

33

wall section

34

wall section

35

joint seam

36

joint seam

37

formation

38

exemption

39a

bearing seat

39b

bearing seat

40a

camp

40b

camp

41

contact surface

42a

contact section

42b

contact section

43a

flap

43b

flap

44a

receiving surface

44b

receiving surface

45a

bracket

45b

bracket

46

joint seam

47a

pivot

47b

pivot

48a

dogging

48b

dogging

50

wall section

51

wall section

52

wall section

53

wall section

54

joint seam

55a

joint seam

55b

joint seam

55

Pitch

56

reference level

57

reference level

58

Pitch

59

reference level

65

base element

66a

switching cheek

66b

switching cheek

67a

wall part

67b

wall part

68a

wall part

68b

wall part

69a

wall part

69b

wall part

70a

mounting fixture

70b

mounting fixture

71a

bracket jig

71b

bracket jig

72

wall section

73

wall section

74

wall section

75

wall section

76

dogging

77

78

79

80

gear lever

81

switching recess

82

shift gate

83

guide surface

84

stop surface

85

button

86

blocking surface

87

switching recess

88

switching recess

89

guide surface

90

joint axis

91

shift fork

92

articulated arm

93

joint axis

94

fastening device

95

support element

96

support element

97

side surface

98

locking element

99

recess

100

longitudinal axis

101

mounting position

102

Transport and / or installation position

103

swivel angle

104

remolded

105

edge

106

edge web

107

final part

108

edge

109

recess

110

edge web

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 10360715 A1 [0003]
• DE 10045506 A1 [0003]
• EP 0384158 B1 [0006]
• EP 1746312 B1 [0006]
• DE 19919270 B4 [0007]
• DE 19919271 B4 [0007]
• DE 102007010362 A1 [0008]

Claims (38)

Switching element ( 2 . 3 ), in particular shift rocker or shift fork, for the axial displacement of a sliding sleeve of a gear change transmission, which forms a substantially U-shaped, multi-part main body which forms a base element ( 15 . 65 ) and protruding from this switching cheeks ( 16a . 16b . 66a . 66b ), wherein in the transverse plane of the switching element ( 2 . 3 ) between the shift cheeks ( 16a . 16b . 66a . 66b ) a switching jaw is formed, characterized in that the base element ( 15 . 65 ) and / or the shift cheeks ( 16a . 16b . 66a . 66b ) of the main body formed by a profile body and the shift cheeks ( 16a . 16b . 66a . 66b ) with the base element ( 15 . 65 ) are connected via a cohesive joint connection. Switching element according to claim 1, characterized in that the profile body of the base element ( 15 . 65 ) is designed as a self-contained tube profile. Switching element according to claim 1, characterized in that the base element ( 15 . 65 ) in its opposite end regions a connection region, each having at least one contact surface ( 18 ) for the positioning of a shift cheek ( 16a . 16b . 66a . 66b ) relative to the base element ( 15 . 65 ) trains. Switching element according to Claim 3, characterized in that the connection regions are diametrically opposite each other and extend over an axial section of the base element ( 15 . 65 ) extending contact surfaces ( 18 ), in particular flattening, form. Switching element according to claim 1, characterized in that the base element ( 15 . 65 ) with a guide device for at least one transmission element ( 4 . 5 . 6 . 7 ) is equipped for transmitting a switching movement. Switching element according to claim 5, characterized in that the guide device in the axial direction of the base element ( 15 . 65 ) with distance at its outer periphery projecting guide elements ( 19 ) having. Switching element according to claim 5 or 6, characterized in that the guide elements ( 19 ) in each case by a material section of the base element ( 15 . 65 ) and formed from the material of the base element ( 15 . 65 ) are formed. Switching element according to claim 5 or 6, characterized in that the base element ( 15 . 65 ) with an assembly and / or transport lock for the limitation of a swivel angle ( 103 ) between a switching element ( 2 . 3 ) and a transmission element ( 4 . 5 . 6 . 7 ) Is provided. Switching element according to claim 8, characterized in that the assembly and / or transport locking a locking element ( 98 ), which by a material portion of the base element ( 15 . 65 ) and formed from the material of the base element ( 15 . 65 ) is shaped. Switching element according to one of claims 1 to 9, characterized in that the base element ( 15 . 65 ) is formed by a stamped and formed part, on which functional areas, in particular the connecting areas and / or the guiding device and / or the assembly and / or transport securing, are already co-formed, and which at its in the direction of the longitudinal axis of the base element ( 15 . 65 ) extending longitudinal edges at least partially joined via a cohesive joint connection to the profile body. Switching element according to claim 1, characterized in that the profile body of the shift cheek ( 16a . 16b . 66a . 66b ) forms an approximately U-shaped profile in cross-section or at least over a longitudinal section has an approximately U-shaped profile. Switching element according to claim 1 or 11, characterized in that the profile body of the shift cheek ( 16a . 16b . 66a . 66b ) has at least over a longitudinal section in a self-contained in cross-section tubular profile, in particular box profile with polygonal cross-section. Switching element according to one of claims 1 to 11, characterized in that the profile body of the shift cheek ( 16a . 16b . 66a . 66b ) a first wall part ( 25a . 25b . 68a . 68b ), second wall part ( 26a . 26b . 69a . 69b ) and a third wall part (FIG. 24a . 24b . 67a . 67b ) having. Switching element according to claim 1, 11, 12 or 13, characterized in that the profile body of the shift cheek ( 16a . 16b . 66a . 66b ) in the direction of its longitudinal extension between the end regions forms a cross-sectional profile with over the longitudinal extent of changing cross-sectional dimensions. Switching element according to one of claims 1 to 14, characterized in that the profile body of the shift cheek ( 16a . 16b . 66a . 66b ) has an end wall. Switching element according to claim 15, characterized in that the end wall of at least one of the wall parts ( 24a to 26b . 67a to 69b ) is formed and a tab ( 43a . 43b ) having. Switching element according to one of claims 1 to 16, characterized in that the profile body of the shift cheek ( 16a . 16b . 66a . 66b ) is formed in several parts and the first wall part ( 25a . 25b . 68a . 68b ), second wall part ( 26a . 26b . 69a . 69b ) and third wall part ( 24a . 24b . 67a . 67b ) are connected to each other via cohesive joint connections. Switching element according to one of claims 1 to 16, characterized in that the profile body of the shift cheek ( 16a . 16b . 66a . 66b ) is formed in one piece and the first wall part ( 25a . 25b . 68a . 68b ) and second wall part ( 26a . 26b . 69a . 69b ) from the third wall part ( 24a . 24b . 67a . 67b ) Angled and optionally connected by at least partially with this via cohesive joint connections to the profile body. Switching element according to one of claims 1 to 18, characterized in that the switching cheek ( 16a . 16b . 66a . 66b ) in a base element ( 15 . 65 ) facing first end region at least one to the contact surface ( 18 ) on the base element ( 15 . 65 ) at least partially complementarily formed conditioning section ( 42a . 42b ) having. Switching element according to one of claims 1 to 19, characterized in that the shift cheek ( 16a . 16b . 66a . 66b ) each with the first wall part ( 25a . 25b . 68a . 68b ) and second wall part ( 26a . 26b . 69a . 69b ) the basic element ( 15 . 65 ) at least partially surrounds and the the base element ( 15 . 65 ) facing surface portions of the wall parts ( 25a . 25b . 68a . 68b . 26a . 26b . 69a . 69b ) partial contact surfaces ( 41 ), which against an outer periphery of the base element ( 15 . 65 ) and with the base element ( 15 . 65 ) via cohesive joint connections ( 55a . 55b ) are connected. Switching element according to one of claims 1 to 20, characterized in that the switching cheek ( 16a . 16b . 66a . 66b ) in a base element ( 15 . 65 ) facing away from a second end region a receiving surface ( 44a . 44b ), on which a holder ( 45a . 45b ) for a driver element ( 48a . 48b . 76 ) is engageable for engagement in the sliding sleeve. Switching element according to one of claims 1 to 21, characterized in that the switching element ( 2 . 3 ) Is formed by a pivotally mounted in a transmission housing shift rocker. Switching element ( 2 . 3 ), in particular shift rocker or shift fork, for axial displacement of a sliding sleeve of a gear change transmission, comprising a one-piece or multi-part main body, in the transverse plane of the switching element ( 2 . 3 ) between shift cheeks ( 16a . 16b . 66a . 66b ) forms a switching mouth, and at least one driver element ( 48a . 48b . 76 ) for engagement in a circumferential groove of the sliding sleeve, characterized in that the basic body, in particular its shift cheeks ( 16a . 16b . 66a . 66b ), at least one receiving surface ( 44a . 44b ), on which a holder ( 45a . 45b ) for the driver element ( 48a . 48b . 76 ) is positionable, and the holder ( 45a . 45b ) is attached to the body via a joint connection. Switching element according to claim 23, characterized in that the holder ( 45a . 45b ) a mounting base with one of the receiving surface ( 44a . 44b ) facing mounting surface and a bearing bore for receiving a journal ( 47a . 47b ) of the driver element ( 48a . 48b . 76 ) having. Switching element according to claim 23, characterized in that the base body is designed in several parts and a base element ( 15 . 65 ) and at this via a cohesive joint connection connected switching cheeks ( 16a . 16b . 66a . 66b ) having. Switching element according to claim 25, characterized in that the base element ( 15 . 65 ) and / or the shift cheeks ( 16a . 16b . 66a . 66b ), in particular the profile body, are formed according to one of claims 1 to 22. Switching device ( 1 ) with at least one switching element ( 2 . 3 ), in particular shift rocker, for the axial displacement of a sliding sleeve of a gear change transmission, and at least one with the switching element ( 2 . 3 ) cooperating transmission element ( 4 . 5 . 6 . 7 ), in particular shift rail, wherein the switching element ( 2 . 3 ) forms a substantially U-shaped main body, which is a base element ( 15 . 65 ) and protruding from this switching cheeks ( 16a . 16b . 66a . 66b ), characterized in that the transmission element ( 4 . 5 . 6 . 7 ) at least one switching recess ( 81 . 87 . 88 ), through which the base element ( 15 . 65 ) is guided through. Switching device according to claim 27, characterized in that the base body is designed in several parts and a base element ( 15 . 65 ) and at this via a cohesive joint connection connected switching cheeks ( 16a . 16b . 66a . 66b ) having. Switching device according to claim 28, characterized in that the base element ( 15 . 65 ) and the shift cheeks ( 16a . 16b . 66a . 66b ), in particular the profile body, are formed according to one of claims 1 to 22. Switching device according to claim 27, characterized in that the transmission element ( 4 . 5 . 6 . 7 ) further a shift gate ( 82 ) for engaging an actuating element ( 9 ) having. Switching device according to claim 27, characterized in that the transmission element ( 4 . 5 . 6 . 7 ) a non-cutting formed from sheet metal forming part ( 104 ), the at least one angled from the sheet edge ( 105 ) trains. Switching device ( 1 ) for a multi-speed change-speed gearbox of a motor vehicle, with a first switching element ( 2 ), in particular shift rocker, for the axial displacement of a first sliding sleeve, and a second switching element ( 3 ), in particular shift rocker, for the axial displacement of a second sliding sleeve, and at least one with the switching elements ( 2 . 3 ) cooperating transmission element ( 4 . 5 . 6 . 7 ), in particular shift rail, each shift element ( 2 . 3 ) forms a substantially U-shaped main body, which is a base element ( 15 . 65 ) and protruding from this switching cheeks ( 16a . 16b . 66a . 66b ), characterized in that the transmission element ( 4 . 5 . 6 . 7 ) a first switching recess ( 81 . 87 . 88 ) and second switching recess ( 81 . 87 . 88 ), wherein the base element ( 15 ) of the first switching element ( 2 ) through the first switching recess ( 81 . 87 . 88 ) and the base element ( 65 ) of the second switching element ( 3 ) through the second switching recess ( 81 . 87 . 88 ) are passed through. Switching device according to Claim 32, characterized in that the switching device ( 1 ) is designed according to one of claims 27 to 31. Method for producing a switching device ( 1 ) for a multi-speed change-speed gearbox of a motor vehicle, with at least one switching element ( 2 . 3 ) for the axial displacement of a sliding sleeve and at least one with the switching element ( 2 . 3 ) cooperating transmission element ( 4 . 5 . 6 . 7 ), in which a basic element ( 15 . 65 ), a first shift cheek ( 16a . 16b . 66a . 66b ) and second shift cheek ( 16a . 16b . 66a . 66b ) and then connected to one another via a joining process, characterized in that the transmission element ( 4 . 5 . 6 . 7 ) before the joining process via a switching recess ( 81 . 87 . 88 ) on the base element ( 15 . 65 ) is arranged. A method according to claim 34, characterized in that at least one of the shift cheeks ( 16a . 16b . 66a . 66b ), after which the transmission element ( 4 . 5 . 6 . 7 ) on the base element ( 15 . 65 ), with the base element ( 15 . 65 ) is added. Method for producing a switching element ( 2 . 3 ) for a switching device ( 1 ) of a gear change transmission in which a U-shaped base body produced and at least one driver element ( 48a . 48b . 76 ) is attached to the base body, characterized in that on the base body at least one receiving surface ( 44a . 44b ) and a holder ( 45a . 45b ) for the driver element ( 48a . 48b . 76 ) relative to the receiving surface ( 44a . 44b ) is positioned and connected to the body. A method according to claim 36, characterized in that for the time being a base element ( 15 . 65 ) and shift cheeks ( 16a . 16b . 66a . 66b ) are joined to the U-shaped body. A method according to claim 36 or 37, characterized in that the switching cheeks ( 16a . 16b . 66a . 66b ) and the base element ( 15 . 65 ) opposite contact surfaces ( 18 . 41 ) in a first direction to each other in a tangential direction to a reference level ( 56 ) and in a second direction to each other in the longitudinal direction to a distance measure ( 55 ) and in a third direction to each other in the circumferential direction of the base element ( 15 . 65 ) to a reference level ( 57 ) are positioned / aligned and that the shift cheeks ( 16a . 16b . 66a . 66b ) in their aligned relative positions with the base element ( 15 . 65 ).

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