DE2812935A1 - Magnetic tape direction reversing mechanism - has levers assigned to directions of running and pivotable symmetrically on frame - Google Patents

Abstract

The tape-direction reversing mechanism has levers which bring the magnetic tape into the playing position in one or other direction of turning. A common drive is provided to actuate either the lever for the one direction of running or the lever for the other direction. The drive consists of a carriage (17) which can move to and fro on the frame (1). This carriage may be operated by hand. The electro-motive drive of the carriage may be effected by the drive motor of the magnetic tape.

Description

Device for switching the direction of travel of a magnet

The subject of the invention is a device for changing the direction of travel of a magnetic tape, formed from each one assigned to a direction of travel, symmetrically arranged on the chassis pivotable levers that the magnetic tape in one or other direction in the play position, and a common either drive actuating the lever assigned to one or the other direction of travel is provided.

The purpose of the device mentioned above is a so-called Ensure auto-reverse operation of a magnetic tape, as is the case especially with modern ones Cassette recorders, especially required for built-in devices for motor vehicles will.

There are previously known devices for changing the direction of travel, in which the operating levers are operated with an eccentric, which in turn Via a gearbox and a clutch to the drive motor of the magnetic tape recorder connected is. However, these devices require an extremely high Space requirements and also require relatively large release forces for actuation the Lever, which in turn uses rubber pressure rollers to press the Actuate the magnetic tape on the capstand shaft, as well as via the corresponding engagement clutches Couple the winding plate with the drive motor.

The object of the present invention is to provide a device for changing the direction of travel of the type mentioned so that the actuation of the switch necessary lever is motorized and takes up little space, and only low release forces are required.

According to the present invention, this object is achieved by that the drive for actuating the lever is a reciprocable on the chassis Sledge is.

The carriage can be driven by an electric motor or can also be manually operated. It is preferred if the electromotive drive of the Slide takes place by the drive motor of the magnetic tape.

With the solution according to the invention there are significant advantages over achieved the known devices for changing the direction of travel. All devices the common problem is how to turn the rotating motion of the drive motor into one oscillating movement of an actuating element (within the scope of the present invention this is a reciprocating slide) converts this arrangement as small and space-saving as possible should be built, and for the levers should only require low actuation forces Invention now proposes a system in which the drive elements for the levers is a reciprocating slide that has either the one set of levers that assigned to one direction of travel, or the other set of levers assigned to the other Are assigned running direction, applied with a release force and holding force.

The present invention goes a completely new way in electromotive Drive of the carriage, which is characterized in that the electromotive Drive the slide to operate the lever by an approximately perpendicular to the direction of movement the slide takes place on the slide slidably arranged cross slide, which has an elongated hole in which a pinion coupled to the drive motor engages, this by moving the cross slide on the slide either with a first on the side of the elongated hole attached rack or with a second on the opposite side of the elongated hole attached rack can be brought into engagement is.

To reverse the direction of rotation, you now only have to ensure that that the pinion engages either in the first rack and the rack in Direction of displacement of the slide moved together with the slide, or in the second opposite rack engages, and the carriage in the opposite one Direction drives to allow the second set of levers to operate the rubber pressure roller and to operate the To apply the engagement clutch on the winding plate.

It is particularly advantageous that the displacement of the transverse slide takes place on the carriage electromagnetically, by an electromagnet whose pivotable armature is connected to a lever which engages the cross slide and moves it.

In this way it is possible with simple means to reduce the rotational Movement of the drive motor into a translatory movement of the slide for application of the two sets of levers.

It is now only operated an electromagnet with a Lever cooperates that the cross slide either in one direction or the other moves and thereby the pinion in engagement with one or the other Rack brings.

Does the pinion have the rack (and thus the slide for actuation the lever) pushed into the end position, means are provided that the pinion disengage from the rack so that the slide is in its end position is locked.

When converting the rotational movement of the drive motor into a translational movement of the slide, as explained above, there is a problem that the pinion forces into engagement with the rack generated that tend to disengage the pinion from the rack bring. To avoid this, the present invention is through this characterized in that the angle between the direction of displacement of the cross slide and the perpendicular to the direction of displacement of the carriage is greater than that Angle of the tooth flanks to these perpendiculars.

It is therefore essential that the cross slide is not exactly vertical to the direction of movement of the slide is moved up or down, but at an angle to the direction of movement of the slide. This results in opposing forces which outweigh those forces that disengage the rack again Want to bring pinions. A major advantage of the solution according to the invention is that the cross slide is held in its position in a self-locking manner, so that an unintentional Disengaging the rack with the pinion is no longer possible. Another The advantage of this measure is that the holding force is increased by this arrangement according to the invention of the magnet, which moves the cross slide up or down, supports so that a secure locking of the cross slide in the end positions (i.e. either Position of engagement of the upper rack with the pinion or the lower rack with the pinion) is guaranteed.

Other essential features and advantages of the present invention will now be explained in more detail using an exemplary embodiment.

Show it: Fig. 1 schematically drawn plan view of a device for switching the direction of travel of a magnetic tape, Fig. 2 top view to a detail according to Fig. 1 (slide with attached cross slide) Fig. 3 shows a detail from Fig. 2 (representation of the cross slide with a partially pinion shown in the meshing position and a drawn parallelogram of forces).

InFig. 1 is shown with 1 the chassis of a magnetic tape recorder, its The drive mechanism is essentially symmetrical to the line of symmetry 3. Of simplicity for the sake of the following description on the right side of the device for Reference is made to the direction of travel switchover, but it is found that the same-drawn Parts to the left of the line of symmetry 3 have the same functions. Where there is for explanation is necessary, those drawn on the left side of the line of symmetry 3 are drawn Parts with the same reference number and marked with a prime line.

The drive mechanism of the tape recorder is known from a capstan shaft lo, to which a rubber pressure roller 21 can be pressed, wherein between the capstan shaft lo and rubber pressure roller 21, the magnetic tape, not shown is guided and is driven by it. Furthermore are for everyone Running direction Winding plate 16,16 'provided that the magnetic tape roll either in the one or other direction. In the position shown in Fig. 1 is straight the winding plate 16 is driven, this is done by means of a coupling support 24 gears 51 in a manner not shown on the one hand with the winding plate 16 are brought into engagement, and on the other hand via a slip clutch, not shown be coupled to the drive motor (not shown).

The direction of travel change is that the winding plate 16 on the right side of the illustration out of engagement with the clutch support 24 is brought, at the same time the rubber pressure roller 21 from the capstan shaft lo is removed. By moving the mentioned parts on the right side of the illustration the same parts are engaged on the left side i.e. the rubber pressure roller 21 'is pressed against the capstan shaft lo', while at the same time via the coupling support 24 'the gear 51' is brought into engagement with the winding plate 16 ', and in not is coupled to the drive motor as shown in more detail.

The actuation of the rubber pressure rollers 21,21 'and the clutch of the Winding plate 16,16 'with the drive motor, not shown, now takes place via the shown in the drawing Lever.

The rubber pressure roller 21 is rotatably mounted on a lever 6, which is arranged pivotably on the chassis 1 at the pivot point 20.

The lever 6 has at its free end opposite the pivot point 20 a return spring 9 which exerts a force in the direction indicated by the arrow Position on the free lever end of the lever 6 exerts. The lever 6 is in the directions of the arrows 7.8 pivotable.

On the chassis 1, a second lever 13 can be pivoted at the pivot point 22 stored, which carries the coupling support 24 via a bracket 14, which in turn consists of a spring 32, and a lever, at the free end of which gears 51 are arranged. By pivoting the lever 13 in the direction of arrow 52,53 either the gears 51 brought into engagement with the winding plate 16 or disengaged Intervention.

The actuation of the levers 6,13 is now carried out according to the invention via a Carriage 17 which can be moved back and forth on the chassis 1 in the direction of the arrow 18, 18 '.

First, the manual operation of the carriage 17 is explained, and then the electromotive actuation.

The carriage 17 has elongated holes not shown in detail, whose Longitudinal axis is aligned in the displacement direction 18,18 '. Through the elongated holes engage stud bolts, which are not shown in detail and which are fastened to the chassis 1. By moving the carriage 17 in the direction of the arrow 18, a wedge surface 19 abuts on the bolt 12 attached to the lever 6, and leaves the lever 6 in the direction of the arrow Swivel 7 upwards.

In the end position, the bolt 12 then engages in a locking recess 41 behind the wedge surface. The main advantage of this arrangement is that due to the wedge surface 19 a very small release force is required to operate the lever 6, which is a significant advantage over the previously known arrangements.

In order to maintain the locking position of the bolt 12 in To ensure the locking recess 41, it can also be provided that the carriage 17 is connected to a bolt on which a spring engages, on the one hand with is connected to the bolt and on the other hand to the chassis. The pen then exercises one such a spring force that the bolt 12 is even more secure in the locking recess 41 is held.

Simultaneously with the displacement of the carriage 17 in the direction of the arrow 18 strikes the stop surface 35 of the carriage 17 against the associated stop 36 of the lever 13. The lever 13 is thus pivoted in the direction of arrow 53, see above that the gears 51 on the coupling support 24 are out of engagement with the winding plate 16 are brought. The displacement of the carriage 17 in the direction of the arrow 18 # has so the consequence that the rubber pressure roller 21 from the capstan shaft lo is removed, at the same time the gears 51 out of engagement with the winding plate 16 are brought. At the same time, they arrive on the left side of the line of symmetry 3 drawn analog parts into engagement, i.e. the rubber pressure roller 21 'becomes on the capstan shaft lo ', and the gear 51' is in engagement with the winding plate 16 'brought.

To secure the end positions of the levers 13, 13 'there are also spiral springs 11.11 'provided.

The electromotive drive of the carriage 17 in the arrow directions 18,18 'described in more detail.

According to FIG. 2, a transverse slide 25 is displaceable on the slide 17 arranged. In a first embodiment of the present invention, the Cross slide 25 in the arrow directions 26, 26 ', i.e. perpendicular to the direction of displacement 18, 18 'of the carriage 17 can be displaced. In the embodiment shown in FIG the transverse slide 25 can be displaced in the directions of the arrows 48, 48 '. The postponement of the cross slide 25 on the carriage 17 takes place in that with the carriage 17 stud bolts 40 are connected, which are in corresponding elongated holes 43 of the cross slide 25 intervene (see also Fig. 3).

The transverse slide 25 has a central elongated hole 2, the longitudinal boundaries of which Form racks 33,34, and with a pinion 4 engages in the elongated hole 2, the connected in a manner not shown with the drive motor of the magnetic tape recorder is. The drive pinion 4 always rotates in the direction of arrow 5.

To now turn this rotational movement into a translational movement either in the direction of displacement 18 or in the opposite direction in direction 18 ' to convert, it is provided that either the upper rack 33 or the lower Rack 34 can be brought into engagement with pinion 4. For example, if the Cross slide 25 is moved downward in the direction of arrow 48, then the pinion 4 arrives in engagement with the upper rack 33 and immediately moves the cross slide and thus the slide 17 connected to the transverse slide 25 in the direction of arrow 18 to the right. If the pinion 4 has arrived at the end of the rack 33 on the left, then it arrives it into a Fposition 42, i.e. out of engagement with the rack 33. The length the rack 33 and the arrangement of the clearance 42 is chosen so that with the arrival of the pinion 4 in the clearance 42 at the same time the stud bolts (see Fig. Fig. 1) 12 of the lever 6 engages in the locking recess 41. That is, the pinion 4 becomes is held in a stable end position within the clearance 42 vice versa the carriage 17 moves in the direction of arrow 18 'to the left as soon as the pinion is out of the left exposure 42 came out and engaged with the left end of the lower Toothed rack 34 by moving the cross slide 25 in the direction of arrow 48 brought will.

It is clear from the illustration explained above that simple Displacement of the transverse slide 25 in the arrow directions 48,48 'the pinion 4 either can be brought into engagement with the upper or the lower toothed rack 33,34, wherein thereby the rotational movement of the pinion 4 into a translational movement of the cross slide 25 and thus of the carriage 17 in the directions of the arrows 18,18 ' will.

To move the cross slide 25 in the directions of the arrows 48,48 ' to be able to operate remotely as well, is the one in the left part of the illustration of the Fig. 2 shown electromagnet 28 is provided. This electromagnet 28 has a Core 29 on which an anchor 27 is opposite. The anchor can be swiveled over the Driving pin 30 connected to a lever 37, which in turn is in the pivot point 38 is pivotably mounted. If the electromagnet 28 is now flowing through with current, then the armature 27 assumes the position shown in Fig. 2, i.e. the lever 37 engages into an elongated hole 47 of the transverse slide 25 via a bolt 39 connected to it and exerts a force on the cross slide 25 in the direction of the arrow 48 ', so that the cross slide is held in the position shown in FIG.

If the electromagnet 28 is switched off, then the spring 31 exerts a in the direction of arrow 54 acting force on the lever 37, so that this in the direction of the arrow 48 is pivoted downwards, and the cross slide 25 in the shifts another layer downwards.

The entire system is characterized by low release forces and low holding forces, because according to the present invention for switching the direction of travel now only the electromagnet 28 is required, which corresponds to its switching state either the transverse slide 25 in the direction of the arrow 28 'upwards or in the direction of the arrow 48 moves down.

By the arrangement of wedge surfaces 19 and adjoining them Latching recesses 41 on the carriage 17, the release forces are further reduced, because the slide now covers a relatively large displacement path 18, 18 ' and the release force acting on the bolt 12 accordingly over the entire movement of the carriage is distributed in the direction of displacement 18,18 '.

It was already stated above that it is particularly favorable, if still special measures are taken to ensure that the pinion 4 in The position of engagement with the upper or lower rack 33, 34 remains provided that the carriage 17 is to be shifted in the shifting directions 18, 18 '. For a more detailed explanation reference is made to FIG.

In Fig. 3, the plan view of the cross slide 25 is shown.

There the pinion 4 is just in engagement with the upper one Rack 33. It is important here that the tooth flank of the pinion 4 is associated with an Tooth flank So of the rack 33 a force Fu exerts, which to it tends to disengage the pinion 4 again from the tooth flanks So of the rack Bring 30.

To avoid this, an inclined position of the displacement path 46 of the cross slide 25 is provided. Namely, the longitudinal axis of the elongated holes 43 Set obliquely opposite to the direction of rotation 5 of the pinion 4, so acts a force F1 and F2 exert a force F1 and F2 on the stud bolts 40 connected to the slide 17 the decomposition of these forces, and the formula given in the drawing becomes it can be seen that the forces F1 and F2 are equal to the force Fu. The trigger force, the pinion 4 again out of engagement with the tooth flanks So of the rack 33 wants to bring is denoted by FR. The formula entered in FIG. 3 becomes it can be seen that the sum of the subcomponents Fly and F2y is greater than this release force FR is, provided that the angle 45 is selected to be greater than the angle 44. I.e. that the Angle 45 between the direction of displacement 46 of the transverse slide 25 and the vertical relative to the direction of displacement 18, 18 ′ of the slide 17 is greater than the angle 44 the tooth flanks so to this perpendicular.

With this special arrangement, a self-locking position of the Cross slide 25 guaranteed in one or the other end position, whereby the holding force of the magnet 28 does not have to be chosen so large, and thus the magnet itself can be made smaller. This contributes to a space-saving structure.

The actuation of the electromagnet 28 thus becomes easier Wise an auto-reverse operation is achieved. The relatively small magnet 28 is the reversal of the levers 6, 13 or 6 ', 13' accomplished, with a comparison the holding force of the magnet 28 is relatively large actuation forces to be mastered. In the current-free state of the magnet 28, the magnetic tape is then, for example always on track I, while with a current-carrying electromagnet 28 the magnetic tape runs on track II. This has the great advantage that each time you insert the Cassette can control the electromagnet 28 so that always the desired side the cassette is playing. The above arrangement has the further advantages that the switchover is reliable, and the production is relatively simple and can be done economically. The assembly is also simple and the whole Arrangement is vibration-proof, so that this circuit esp.

for mobile use, especially suitable for car cassette recorders is.

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Claims (15)

Claims device for switching the direction of travel of a magnetic tape, formed from each one assigned to a running direction, symmetrically on the chassis arranged pivotable levers that move the magnetic tape in one direction or the other bring into play position, and a common either one or the other Running direction associated lever actuating drive is provided, d a d u r c it is noted that the drive is a back and forth on the chassis (1) movable carriage (17) is. 2. Apparatus according to claim 1, d a d u r c h g e k e n n z e i c n e t that the slide (17) is manually operated. 3. Apparatus according to claim 1 and 2, d a d u r c h g e k e n n z e i c h n e t that the electromotive drive of the carriage (17) by the Drive motor of the magnetic tape takes place. 4. Apparatus according to claim 3, d a d u r c h g e k e n n z e i c hn e t that the electromotive drive of the carriage (17) for actuating the Lever (6,13,24; 6 ', 13', 24 ') takes place by an approximately perpendicular to the direction of movement of the slide (17) on the slide (17) displaceably arranged cross slide (25), which has an elongated hole (2) into which a Pinion (4) engages by moving the cross slide (25) on the slide (17) either with a first rack attached to the side of the elongated hole (2) (33) or with a second attached to the opposite side of the elongated hole (2) Rack (34) can be brought into engagement. 5. Apparatus according to claim 4, d a d u r c h g e k e n n z e i c h n e t that the displacement of the cross slide (25) on the carriage (17) is electromagnetic takes place by an electromagnet (28), the pivotable armature (27) with a Lever (37) is connected, which engages the cross slide (25) and moves it. 6. Apparatus according to claim 4, d a d u r c h g e k e n n z e i c hn e t that the displacement (40) of the transverse slide (25) obliquely to the direction of displacement (18,18 ') of the carriage (17) takes place. 7. Apparatus according to claim 6, d a d u r c h g e k e n n z e i c h n e t that the angle (45) between the direction of displacement (46) of the cross slide (25) and the perpendicular to the direction of displacement (18, 18 ') of the slide q h otler (17 is greater than the angle (44) of the tooth flanks (50) to this perpendicular. 8. Device according to one of the preceding claims, d a d u r c h g e k e n n n n e i c h n e t that the cross slide (25) has elongated holes (43), engage in the stud bolts (40) connected to the slide (17). 9. The device according to claim 4, d a d u r c h g e k e n n z e i c h n e t that the elongated hole (2) of the cross slide (25) at the ends exemptions (42) in which the pinion (4) rotates freely. lo. Devices according to one or more of the preceding claims, d a d u r c h e k e n n n z e i c h n e t that the carriage (17) wedge surfaces; 19 ') has which, when the carriage (17) is moved, also on the lever (6; 6 ') fastened bolts (12; 12 ') cooperate. 11. The device according to claim lo, d a d u r c h g e k e n n z e i c h n e t that the wedge surfaces (19,19 ') in locking recesses (41,41') for receiving the bolt (12,12 ') pass over. 12. The device according to claim 7, d a d u r c h g e k e n n z e i c h n e t that the pinion (4) has straight teeth. 13. The apparatus of claim 7, d a d u r c h g e k e n n z e i c h n e t that the pinion (4) has an involute toothing. 14. The apparatus of claim 7, d a d u r c h g e k e n n z e i c h n e t that the angle between the direction of displacement (46) of the cross slide (25) and the perpendicular to the direction of displacement (18,18 ') of the carriage (17) Is 0 to 500. 15. The apparatus of claim 5, d a d u r c h g e k e n n z e i c h n e t that the displacement of the cross slide (25) in one direction Actuation by the electromagnet (28) and in the other direction by a Spring (31) takes place.