DE717554C - Pre-selection switch for gear change gear - Google Patents

Description

Pre-selection direction for gear change gears The invention relates to an electrical forward switching device for gear change transmissions with four or more translations, which are in particular; for use in motor vehicles suitable.

There are already facilities of this type known in which one with a Gear member connected, displaceable switching member by springs in a central or the basic position is held in which the gear element is switched off, and by an electromagnetically pivotable one driven by a motor Actuating slide mounted shock member against the action of the springs in the one or the other of two switching positions is guided and the engagement of the gear member caused. The transmission member is thereby counteracted by the spring action by the shock member held in the engaged position while disengaging the gear member below Spring action takes place after the retraction of the shock link.

The return of the switching element to its central position by spring action but is not sufficient for controlling change gearboxes for motor vehicles Reliable. If any jamming occurs in the gearbox or linkage, it could the case occurs, i.e. that, despite the retraction of the push link, no or only a partial one Disengagement of the gear member takes place, which means that when another is subsequently engaged Transmission link can result in damage to the transmission. Besides, the must to the circuit force required of a gear member to be increased by the Irraft required to overcome the spring action.

The purpose of the invention is to address the shortcomings of this known electrical Pre-selection switching devices through an inevitable return of a transmission link to eliminate in its middle position before the initiation of a new circuit. This device has an actuating element that can be displaced to carry out the circuit with at least two switching elements assigned to each -two translations, the one Basic position and on both sides of it can each take a switch position in which they are supported by electromagnetically pivoted push rods on the actuating element to be brought. According to the invention are for each of the pivotable in parallel planes and switching elements each having two stop surfaces each two connected to form a pair Push elements provided, ..which at your perpendicular to the pivot axis of the switching elements displaceable actuator are pivotably mounted. Each of these pusher link pairs can assume a central position and a switch position on both sides of it, in which the impact member coming into effect is supported against a fixed stop is. The shock members «iron abutment surfaces, each with an associated stop surface the switching elements cooperate in such a way that when the actuator is advanced the one push member of the push member pair located in a switching position glass associated switching element swivels into a switching position and at the same time a already Schaltgliel located in a switching position of its associated push member is inevitably returned to the basic position before the first-mentioned switching element arrives in a switching position, while after completion of the switching the actuator returns to its rest position. The switching device is therefore during the duration the engagement of a gear member is ineffective and is in the rest position. The pivotable and paired arrangement of the push elements and the switching elements is permitted a direct pressure effect of the push elements with their end faces on the switching elements and in particular enables the inevitable return of the switching elements in their middle position by the contact surfaces of the push links automatically from the Stop surfaces of the switching elements fall off when they reach their central position.

The drawing shows some exemplary embodiments of the subject matter of the invention.

Fig. I shows a switching device with four adjusting members on vain change gears, not shown in the drawing, for four translations.

FIG. 2 is a side view of the switching device according to FIG.

3 is a front view of a shift member and others this cooperating parts of a switching device on a 'device finite several switching elements, the parts in their position before a switching movement are shown.

FIG. 4 shows parts of the device according to FIG. 3 in their position at the end of the switching movement.

In Fig. 3 the same parts as Fig. I are in their position before Returning the switching element shown in its basic position.

Fig. 6 shows them in their position immediately before being returned, and Fig.; shows these parts in their position at the end of the feed movement of the Actuator after the switching element has been returned to its basic position.

In Fig. I and z, the switching movements are on (read not shown Change gear via a shift shaft i. which z trues the gear lever, and about one Transfer hollow shift shaft 3 on which the shift lever 4 is attached and which can rotate freely on the shaft i. By means of the switching shafts i and 3 can In the change gearbox gears are brought into and out of engagement to four different ones Establish gear ratios. When the shift lever 4 is in the Basic position shown in the drawing and the shift lever 2 in its basic position parallel to it, all gears are disengaged, and the gearbox does not transmit any torque from its driving shaft to its driven shaft. at the position of the two shift levers shown in the drawing is a pair of wheels engaged, which forms a first ratio between these transmission shafts. A The other pair of gears is in mesh for the second transmission when the Shift lever 2 in a certain other shift position beyond its basic position is, while the shift lever d in its basic position shown in the drawing remains: In the third or fourth translation, the shift lever 2 is in his Basic position, while the shift lever d. with the third translation parallel the Position of the shift lever 2 at the first transfer and at the fourth translation is parallel to the position of the shift lever 2 in the second translation. Never two translations may be switched on at the same time, so that always one of the two Shift lever must be in its basic position. The gear lever 2 and 4 respectively have contact surfaces 5 and 6 and 7 parallel to the lever axis and 8 and guide surfaces 9 and Io or r i and 12 standing perpendicular thereto.

The switching movements of the shift levers 2 and -. are effected by the actuating member 13, which is carried out on the guide rod Id mounted on the selector shaft i with the same stroke for all these switching movements by a force acting on the pin 15 against the shaft i before and after the completion of these movements by the force of the spring 16 is pushed back. On the actuating member 13, adjusting cams i9, ho, 21 and 22 are pivotably mounted on pins 17 and 18. Each of these cams can assume three special positions with respect to the actuator 13, namely a return position in which the cams i9 and 2o are drawn, an evasive position as shown in the drawing of FIG. Cam 2 1 assumes, and on the other side of the return position a switched-on position, as it assumes the cam 22 in the drawing. The cams i9 and 20 are coupled by a rod 23 and the cams 21 and 22 by a rod 2: I so that the two coupled locks can only assume their return position at the same time. The actuating member 13 carries a resilient stop 25 for each cam, which tries to push it into the return position when pivoting after the evasive position, but cannot follow it from this position after the switched-on position. Because of the coupling rods 23 and 24: the cams of each pair, unless other forces act on them, are pressed into the return position. An electronic magnet 26 is also attached to the actuating member 13 for each adjusting cam. Each of these electromagnets can be excited via a special circuit; these circuits are controlled by a selector switch, not shown in the drawing, which allows only one of them to be closed at the same time, so that the other three remain de-energized.

Cam I9 works with the left, cam 2o with the right Arm of the shift lever 2, the cam 2i with the left and the cam 22 with the right Arm of the shift lever 4 together. Each of these cams has an end face 27, with which he the attack surface 5 or 6 when the actuator 13 is advanced, 7 or 8 of the relevant end of the shift lever hits when it is in its on position is located.

The deflecting surface 28 of each cam is approximately tangential to one Cylinder whose axis is the pivot axis of the cam in question; if this is in its return position and if yours, the gear lever end that works with it is closer than: the basic position of this shift lever is where the deflector surface hits 28 on the attack surface 5 or 6, 7 or 8 of this gear lever end. But stand the cam in its return position and the switching lever in its basic position, so lies this attack surface. next to the path of the deflecting surface 28; the guide surface 9 of the cam then lies on the same plane parallel to the feed direction as the guide surface 9 or Io, II or i2 of the corresponding shift lever end. In its Evasive position, the cam hits the end of the shift lever with which it works, not at all when the actuator is advanced.

The shift levers can have stroke limiting surfaces 3o; on which meet the end faces 27 of the cams at the end of the feed path of the actuator.

In Figs. I and 2 the device is shown at the moment, where the first gear ratio is switched on and the fourth gear ratio on the selector switch is selected and where the advancement of the actuator to switch over into this just begins. By choosing the fourth gear ratio, one's circuit is that Electromagnet 26 has been closed, which acts on the adjusting cam 22, so that it is in its on position. There the other electromagnets 26 are de-energized, the adjusting cams i9 and 2o are activated by the resilient stops 25 held in its return position: The adjusting cam 21, which is driven by the rod 2.I is coupled to the cam 22 is in its evasive position. Beien The adjusting cam 20 initially joins the actuating member 13 before it is clipped the common edge of its end face 27 and its deflecting surface 28 on the attack surface 6 of the shift lever 2 and returns it to its basic position, with first this attack surface along the said edge arid then that of the attack surface 6 and the guide surface Io of the shift lever 2 formed edge along the deflection surface 28 of the cam 20 slides. The latter edge reaches the edge that is on the cam 2o the deflection surface 28 and the guide surface limited, especially when the shift lever 2 has come to its basic position. Then lie the two guide surfaces 9 and iö of the shift lever 2 with the guide surfaces 29. of the adjusting piston i9 or 20 each in a plane parallel to the Vöischubrichtung and slide with further advancement the actuator on this; the shift lever 2 is thus in its basic position held. while the actuator 13 can be advanced further. Searches for any existing game along these sliding surfaces a of the two adjusting cams the corresponding arm of the shift lever by friction take with you, the guide surface of the shift lever arm concerned begins from Moving away that of the adjusting member thereby removes this frictional effect and comes to a standstill after an imperceptible shift. This is the case; because the axis of rotation of the shift lever, seen in the direction of movement of the adjusting cams, lies beyond the sliding point, and helps prevent adjustment cams from jamming and Sehaltliebel .hei.

Only after the shift lever 2 has been returned to its basic position and thus the gears of the transmission are out of engagement, the adjusting cam 22 with the edge 31 of its end face 27 reaches the engagement surface 8 of the shift lever d and then pushes it into its shift position for the fourth translation. After this has been done, the adjusting cams I9 and 2o hit the stops 3o .des shift lever 2 and thus prevent the further advancement of the actuating member 13. r actuating force acting on the pin i5, the spring 16 pushes the member 13 back into its rest position shown in the drawing; the shift levers 2 and .1 remain in the position for the fourth translation until (read organ 13 is actuated again to effect another switching movement.

The other switching movements are effected in a corresponding manner in front of you by optionally (for excitation of the electromagnet concerned for switching on the first translation of the Verstellnocken i9, for (read the second translation of the Verstellnocken 2o and for that brought the third translation of the adjusting cam 21 into its switched-on position and the second cam coupled to the relevant one is pulled into the evasive position w = ird, while the other adjusting cams suffer from the stops 2 5 in their Return position are held.

If the switching lever to be moved into a switching position is not in the basic position, as is the case with lever 2 in the example described, at the beginning of the switching movement, but in the opposite switching position with respect to this, then when the actuating member 13 is advanced, the edge 31 of the relevant adjusting cam first hits in its switched-on position on the engagement surface 5, 6, 7 or 8 of this switching lever and leads (nasty in the basic position and from there on into the desired switching position, the latter; as described for the cam 22 and the switching lever .1. In this case, the other switching levers in their basic position from the beginning of the movement; the corresponding adjusting cams are in their return position and hold the switching lever in this position for the last part of their feed path.

To return all shift levers to their basic position, it is sufficient to with de-energized electromagnet 26 to advance the actuator 13, since then all adjusting cams from the resilient stops. 25 in their return position are held.

The device can also have more than two shift levers, from each of which is mounted on one of several equiaxed shafts and two Mastered pairs of bicycles, of which one or the other depending on its position others or, in the basic position, none is engaged. The adjusting cams, via which the switching movements of the switching lever can be effected are all stored on the same actuator.

In FIGS. 3 to 7, such a device is made up of several Shift levers a vori these shown with the parts interacting with it. Parts that have the same function as those denoted by the same reference numerals Parts in Fig. I and 2 are not described in more detail below.

The shift lever 4o sits firmly on the hollow shift shaft 41 through which his movements are transferred to the pairs of gears he controls. The switching shafts of other pairs of gears can be located in the cavity of this shaft. The switching lever 4o has two parallel guide surfaces.: 12 and .I3 perpendicular to the lever axis .:1:;. and attack surfaces adjoining these guide surfaces at an obtuse angle .15 and .16 whose distance from the lever axis is different.

The adjusting cams .17 and -l9 have curved end faces .4p and 50 and guide surfaces 5i and 52; these are and remain parallel to one another, since the pivot pins of the bracket 53, which couples the adjusting cams .17 and 48, have the same distance as the pins 17 and 18. 54 and 55 are resilient. Attached to the adjusting cams, which seek to push the cams into their return position, where they are symmetrical to the direction of advance of the actuator i 3 and where the distance between their guide surfaces 51 and 52 is equal to the distance between the guide surfaces and 43 of the shift lever .4o.

In addition to this return position, each adjustment cam can assume a switch-on position and an evasive position; in Fig. 3 the cam is d .; Drawn in the Einschaft- and -der Nocken.l8 in the evasive position. In the switched-on position, the end face of the cam strikes an engagement surface of the switching lever 4o when the loading member 13 is advanced; in the evasive position it does not strike it at all. When the electromagnet 26 assigned to it is energized, it assumes its switched-on position and pulls the other cam by means of the tab 53 into its evasive position.

In Fig. 3, the shift lever 40 is drawn in its basic position. When the actuator 13 is advanced, the end face 49 of the adjusting cam 47 meets the engagement surface 45 of the shift lever and, at the end of the feed path, brings it into the shift position shown in FIG. 4, which corresponds to a certain transmission ratio of the transmission. The angle by which the shift lever is rotated from its basic position with a certain feed path of the organ 13 is determined in the manufacture of the shift lever by the distance between the shift lever axis 44 and the engagement surface 45 and can be different for the two gear ratios that the shift lever controls .

In Fig. 5 the shift lever is in the shift position for the other of these two gear ratios and should be brought into its basic position will. The adjusting cams are therefore by not energizing their electromagnets 26 has been left in the return position into which it is held by the resilient stops 54 and 55 are pressed.

When the actuating member 13 is advanced, the common edge of the surfaces 49 and 51 of the adjusting cam 47 comes to rest against the engagement surface 45 of the shift lever. As the actuating member 13 is further advanced, the latter slides on the said edge, while the switching lever 40 is rotated into its basic position. At the moment when this is reached, the mentioned edge slides from the engagement surface 45, whereby the switching lever 4o is withdrawn from the adjusting effect of the cam 47, and the guide surface 42 of the switching lever comes to lie in the same plane as the guide surface 51 of the adjusting cam 47 At the same time, the guide surface 43 of the shift lever rests against the guide surface 52 of the cam 48, as can be seen from FIG.

The actuator 13 continues its path, one of which is not drawn shift lever can be brought into a switched-on position. Meanwhile The surface 5 r of the cam 47 slides aal of the surface 42 and the surface 52 of the cam 48 along the surface 43 of the shift lever 4o, whereby this is in its basic position is held (Fig. 7). The path of the adjusting cam is only through the des Actuating member 13 limited, which in turn can o leg eating that the Switching on each gear ratio is carried out to the end.

Claims (2)

PATENT CLAIMS: r. Electrical preselector for gear change transmissions with four or more gear ratios, with one that can be shifted to perform a circuit Actuator and at least two switching elements each assigned to two ratios, which can assume a basic position and a switch position on both sides, into which they pivoted electromagnetically from those mounted on the actuating element Bumpers are brought, characterized in that for each of the in parallel Pivotable levels and each having two stop surfaces (5, 6; 7, 8 or 45, 46) Switching elements (2, 4 or 4o) each have two connecting links (i9, 2o or 2a, 22 or 47, 48) are provided, which on the perpendicular to the pivot axis of the switching elements (2, 4 or 4o) displaceable actuator (z3) four-pivotable are stored, each pair of pusher members having a central position and on both sides of it can each occupy a switch position in which the impact member coming into effect is supported against a fixed stop (r6), and that the joint members joint surfaces (27, 28 or 49, 5o), each with an associated stop surface of the Switching elements cooperate in such a way that when the actuator is advanced the one push member (22) of the push member pair located in a switching position the associated switching element (4) pivots into a switching position and at the same time a switching element (2) already in a switching position of its associated The thrust link (2o) is inevitably returned to the basic position before the Switching element (4) moves into a switching position while after switching is completed the actuator returns to its rest position. 2. Pre-selector switch device according to claim i with switching elements designed as double-armed levers, characterized in that the stop surfaces (5, 6;;, 8 b: between. 45, 4.6) of the switching elements each at the ends of the against the push members (z9, 2o or 2i, z2 or 47, 48) directed lever arms are provided, the two lever arms of a switching element having such a mutual distance that when the actuating element (i3) is advanced, the pushing element pair in the basic position is within the lever arms of the associated switching element in the basic position can penetrate, and that when a switching element located in a switching position is returned to the rest position, the abutment surface ( 2 7, 28 bz «- drops as soon as 1 the switching element has reached the rest position, whereupon the push-button is activated when the actuating element is advanced further 1 pair slides by means of guide surfaces (a9 or 51, 52 along corresponding guide surfaces (io, ii or 42, .43) of the lever arms of the switching element and holds the same in place in the 1,> i basic position during the switching of a second switching element.