NL8301265A - Direction reversing drive mechanism for tape cassette recorder - readjusts pivot position of head plate as it approaches magnetic tape - Google Patents

Abstract

The drive mechanism has guide slots on each side of the audio head on the mechanism's chassis. Guide pins (86,87) on the head plate (74) travel the guide slots. A control device (88) deflects the pins in the slots such that after each return of the head plate from the imaginary connection line (a) of the audio spindle when an approach occurs again towards the line the pins enter alternately into the one or the other set of guide slots that blocks the approach travel of the pins. The pressure rollers (78,79) of the pivoted head plate whose associated guide pin has not been blocked can approach the associated audio spindle (9,10). The guide slots are roughly U and Y-shaped.

Description

c PHD.83-Ο35 1 4.4.83 N.V. Philips * Incandescent lamp factories in Eindhoven Magnetic tape cassette device with a device for reversing the tape formation.

The invention relates to a magnetic tape cassette apparatus with a device for reversing the tape running direction, wherein the magnetic tape is guided past at least one magnetic head, which is arranged on a pivotable head plate which can be moved in the direction of the cassette. a controlled weakening each time one of two pressure rollers mounted thereon moves against the respective tone axis and thereby the belt running direction ΐ36ρ3,3.Χ1 / 1 10

Such a device is known and has been used in the magnetic tape cassette apparatus of the company Grundig, type WKC 3 3857 VD. The known device operates with a reversible driving device, which during operation rotates control dishes provided with cams. Depending on the position of these cams, the head plate, when moving towards the cassette, can bump against the cams removed at different distances from the front wall of the cassette, so that the respective pressure roller determining the tape running direction is pressed against the tone axis.

Using a reversible drive device to drive the head plate is more expensive and complicated than using a drive with only one driving direction. The known device is essentially not suitable for using a motor operating in only one direction of rotation.

The object of the invention is to provide a device for reversing the tape running direction of a magnetic tape device, wherein the pivoting of the head plate is determined by the movement of the head plate relative to the cassette.

8301265 ♦ s PHD.83-035 2 4.4.83 ♦ 4 This is achieved according to the invention by - guide slot devices provided on the frame of the device on both sides of the magnetic head, 5 - guide pins provided on the head plate, which the guiding slot devices can run in the direction of an imaginary tone-axis connecting line, - control means co-operating with the guiding slot devices - which direct the guiding pins in the guiding slot devices such that the guide pins move away from the connecting line after each displacement of the head plate upon repositioning. the direction of the connecting line is alternately fed into one guide slot device in one or the other in a guide slot leg, which leg blocks the way for the respective guide pin, whereby the pressure roller of the pivoting head plate, of which the associated guide pin does not blocked road, is moved to the corresponding pitch axis and therewith e determines the 20 belt running direction.

The essential advantage of this device consists in that the head plate itself mechanically positions a stop each time the cassette is moved back and when it is pushed back in the direction of the cassette, which, by cooperation of the guide pins with parts of the guide slot devices. The control means mechanically ensure that the stop switches reliably from one side to the other side of the magnetic head, with which only one pressing roller of the head plate can alternately press against the respective tone axis and the tape direction is determined. A further advantage of this device consists in that the displacement of the head plate and the alternating application of the pressure rollers against the counter axes can take place with a drive device which rotates only in one direction, so that the drive device can be economically operated. .83-035 3 4.4.83 are manufactured.

According to another embodiment of the device according to the invention, it is provided that the guide slot devices consist of guide slots in the frame provided with fork-shaped mutually mirror-symmetrically arranged, with two legs corresponding to the fork teeth, one leg of which is shorter than the other leg and wherein a funnel-shaped fork foot connects a lead-in slot corresponding to the fork stem, lying centrally between the 10 legs.

The pivoting of the head plate is thus controlled by simple means. It is further provided that the steering means consist of a steering plate, which is displaceable parallel to the connecting axes connecting line between two end positions and provided with U-shaped guide slots on both sides of the magnetic head, in each end position of the steering plate at least partly with the associated fork-shaped guide slots in the 2Q frame, the mutual distance of the legs of the U-shaped guide slots being smaller than that of the fork-shaped guide slots and for alternately steering the guide pins in the short or the long leg has pointed tapered tongues located between the legs of the U-shaped guide slots, which are located laterally with respect to the lead-in slots in the end position of the control plate, calculated in the direction of displacement of the control plate.

Thus, the only part important for the pivoting direction of the head plate is the control plate, which part has only a small height. Therefore, this construction is extremely suitable for flat devices such as, for example, car cassette players. The guide pins can be designed in a simple manner as pushpin-shaped pins 35 or as elastic tongues with pin-shaped protrusions arranged at the free ends.

The smaller distance between the legs of the U-shaped slots in the control plate means that the 8301265 9 ♦% PHD.83-035 4 4.4.83 guide pins, which end up in the entry slots when the head plate is retracted of the steering plate is always displaced laterally, so that a control of the guide pins in ® is achieved in the desired direction.

According to another embodiment of the device according to the invention, it is provided that the control plate is provided with at least one stop and that the device comprises a stop button and an operating rod connected thereto, which is provided with a nose, which is operated when the stop button hits the stop and the steering plate always moves to one of the end positions. This gives rise to a preferred situation of the control plate, which has the result that the magnetic tape is always only transported in one specific direction of travel after the stop button has been actuated. In the case of a car cassette player, the stop button can simultaneously be the eject button, which ensures that after pressing the eject button, removing the cassette and inserting a new cassette, it is ensured that the tape is conveyed in a certain tape running direction.

In another embodiment of the device according to the invention, it is provided that the guide slot devices consist of U-shaped grooves provided on the frame, each with a short and a long leg and with a double base groove on the base connecting the legs. provided, the control means being designed as guide surfaces located on the bottom of the grooves, which slope upwards relative to the bottom and end in guide contours, which the guide pins each time move back into the head plate and move forward again in the only allow direction of the key axes connecting line, to run through one of the base 35 groove from the short leg into the long leg and then move back and forward through the other base groove from the long leg into the short leg, 8301265 i » PHD.83-035 5 4.4.83 «t in which the short and long legs of the two grooves are arranged in such a way that in case of return moving the head plate one of the lead pins is in a short leg while the other j ® guide pin is in the long leg and when it is | next move back and forward this one guide pin in the long and the other guide pin in the short leg j. No moving control means are required with these guide slot devices. The control means in the form of the ascending guide surfaces and the guide; contours can be formed on the frame as a single part by injection molding, for example by so-called outsert-molding. The only moving elements are the j guide pins on the top plate.

15

The invention is explained in more detail with reference to a number of exemplary embodiments shown in the drawing. Hereby show;

Figure 1 shows a view of the drive side of a magnetic tape cassette apparatus according to the invention in a first embodiment.

Figure 2a shows an enlarged perspective view of a locking mechanism of the device in a first position,

Figure 2b the locking mechanism according to figure 2a in a second position,

Figure 3 shows a view of the magnetic head side of the magnetic tape cassette apparatus in a first tape direction,

Figure 4 shows the magnetic tape cassette apparatus as in Figure 3 »but in a second, opposite tape transport direction,

Figure 5 the co-operation of a guide slot device with control means and head plate in an exploded view,

Figure 6 shows the various positions of a control plate for guiding the guide slot device and the head plate, 8301265> * PHD.83-035 6 4.4.83

Figure 7 is a perspective view of the handlebar plate and of a co-operating stop button for setting a preferred tire orientation.

Figure 8, in a second embodiment of the device, another guide slot device and control means for pivoting the head plate.

The magnetic tape cassette apparatus according to the invention has, as shown in Fig. 1, a frame 1 which, via a support 2, carries a drive motor 3 rotating only in one direction. The drive wheel 4 of the motor 3 guides a belt 5, which is guided via a guide roller 6 over flywheels 7 and 8 such that the flywheels rotate in opposite directions. The flywheels 7 and 8 are rotatably mounted in the frame 1. The flywheel 7 is fixedly connected to a tone shaft 9 and the flywheel 8 is fixedly connected to a tone shaft 10. Furthermore, the flywheel 7 is connected to a gear wheel 11 and the flywheel 8 is connected to a gear wheel 12. Via a slip coupling, parallel to relative to the gear wheel 12, another gear wheel 13 is rotatably mounted on the flywheel 8.

With the gear wheel 12 on the flywheel 8, a gear wheel 14 designed as a gear wheel is in continuous engagement. This gear wheel 14 is pivotable about an axis 15. The shaft 15 Z5 carries a pivoting arm 16 schematically shown in fig. 1, on which the shift wheel 14 is rotatably mounted. Likewise, a gear 17 is in continuous engagement with the gear wheel 11. This gear wheel 17 is rotatable about a pivot axis 18 by means of a schematically shown pivot arm 19.

As also shown in Figs. 3 and 4, winding mandrels 20 and 21 are rotatably mounted in the frame 1. These winding mandrels 20 and 21 are fixedly connected with fast-spool wheels 22, 35. Play wheels 24, 25 are connected to the wrapping spindles 20, 21 via slip couplings.

Fig. 3 shows how the play wheel 25 is driven by the gear wheel 12 via the gear wheel 14. 8301265 PHD.83-035 7 4.4.83 + t. Xn Fig. 4 shows in the same way how the play wheel 24 is driven via the gear 17 by the gear 11.

A bracket 26, which is slidably guided in the frame 1 ®, carries two sprockets 28, 29 · side by side.

A spring 30 always rotates the bracket 26 about the bearing 27 to the starting position shown in Fig. 1. The bracket 26 carries pins 28a, 29a, which are slidably guided in a triangular recess 28b and a slot 29¾ in the frame 1, respectively.

Two buttons 31 and 32 are provided for fast forwarding and rewinding. These buttons 31 »32 are connected to sliders 35» 36 via the operating or key bars 33 and 34. These sliders 35 and 36 cooperate with the bracket 26. To this end, the slide 35 is provided with a projection 37 and the slide 36 carries a contact surface 38. The projection 37 and the contact surface 38 cooperate with the pin 26 with a pin 39 °.

2Q When the protrusion 37 presses against the pin 39 on the bracket 26 by pressing the key 31, the gear wheel 29 first engages with the gear wheel 13. The pins 28a and 29a move according to arrow b and c1 respectively in the recess 28b and slot 29b, respectively. With further movement, the pin 29a moves further into the slot 29b according to the arrow b1, as a result of which the gear wheel 29 also engages in the fast-spool wheel 23. The winding mandrel 21 is hereby driven quickly and the magnetic tape is wound up quickly. If the 3Q presses other fast winding button 32, the run-up surface 38 slides along the pin 39. The pins 28a and 29a move according to the arrows c and c ', respectively, so that the gear 29 with the gear 13 and the gear 28 with the fast-reel 22 intervention. This drives the other winding mandrel 20 for fast rinsing.

A detection element 40, consisting of two discs 41, 42 and a connecting rod 43, is connected to the winding mandrels 20, 21 via slip 8301265 PHD.83-035 8 4.4.83 φ ft couplings. A pin 44 is provided on the disc 42, which lies in a shift fork 45. The shift fork 45 is mounted on a shift element 46, which is rotatable about a bearing 47 (see also fig. 2A and 2B). The shift wheel 14 carries a protruding and slightly elliptical cam 48 in the center. The shift element 46 grips the shift wheel 14 and carries a pin 49 which slides around the circumference of the cam 48 when the shift element 46 is pivoted inward. of the gear wheel in the direction of an arrow 50 · A spiral control wall 51 is located at a fairly great distance on the gear wheel 14 around the cam 48.

This control wall 51 can also cooperate with the pin 49 on the switching element 46, that is, when the detection element detects that the belt is stationary. In that case the pin 44 no longer presses against the shifting fork 45, so that the pin 49 on the shifting element 46 is no longer loaded inwards in the direction of the cam 48, but remains in position and with a continuous rotation of the shifting wheel 14 in the direction of the arrow 50 against the outside of the switch wall $ 1. Since the switch wall 51 is spiral-shaped, the switch element 46 is pivoted clockwise around the bearing 47, whereby the switch element 46 is pressed against a connecting element 52.

The connecting element 52 is a double-arm lever which can be pivoted about a bearing 53. As can be seen from Figs. 2A and 2B, the connecting element 3Q 52 is loaded clockwise by the influence of a spring 54. As a result, the movement of the switching element 46 tensions the spring 54.

The lever arm 55 of the connecting element 52 remote from the point of engagement of the switching element 46 carries a heart-shaped projection 56, which forms part of a locking mechanism 57. The locking mechanism 57 also includes a locking lever 58, which is arranged about an axis 59 with respect to the frame can be pivoted. Deas 59 8301265 * - * PHD.83-035 9 4.4.83 is parallel with respect to the surface of the frame 1 and with respect to an imaginary connecting line a between the axes 9 and 10. The locking lever 58 carries to the heart-shaped cam 56 faces a guide pin 60, which is inserted into a guide slot 61 in an operating rod 62 of a stop / eject button 63. The guide slot 61 is designed such that the detent lever 58, as also appears from Fig. 2B, is pivoted in the direction of an arrow 54 when the stop / eject button is extended. The stop / eject button 63 and the operating rod 62 are slid outwards in a manner not shown, by inserting a magnetic tape cassette into the device. Fig. 2A shows the rod 62 in the retracted position, while FIG. 2B shows the rod 62 in the retracted position.

The detent lever 58 carries a detent pin 65 which can be brought into the engagement area of the heart-shaped cam 56 and move around the cam, which movement is enabled, for example, by a film hinge 66. In Fig. 2A, the pin 65 is pivoted out of the engagement area of the heart-shaped boss 56 since the rod 62 is depressed. In Fig. 2B, when the operating rod 62 has been displaced, the pin 65a is brought within the engagement area of the heart-shaped boss 56. As a result, the pin 65 can cooperate with the heart-shaped projection 56 when the switching element 46 pivots the connecting element 52 counterclockwise in the direction of the arrow 67 as shown in Fig. 2B. During this pivoting away, the pin 65 has run along a side wall 68 of the heart-shaped projection 56.

A guide cam 69 ensures that the pin 65 enters a recess 70 of the heart-shaped cam 56.

A cam 71 is arranged on the lever arm 55.

As shown in FIGS. 3 and 4, this cam 71 cooperates with a spring / spring element formed by a leaf spring 72 and is guided in a longitudinal slot 73 in the frame 1. The leaf spring 72 8301265 PHD.83-035 10 4.4.83 presses with the free ends against holders 76 and 77 which are pivotally mounted on a head plate 74. This head plate 74 carries a magnetic head 75 in the middle and on both sides of the head 75 holders 76, 77 »in which press-on rollers 78, 79 are mounted. Due to the spring force of the leaf spring 72, the holders are pressed against stops 74a and 74b, respectively, on the head plate 74.

The head plate 74 has flanged ends 80, 81. The flanged end 80 has a slot 82 in which a pin 83 is slidable, which is mounted on the pivot arm 16. As a result, in the position according to Fig. 3, the swivel arm 16 is pivoted about the shaft 15 in such a way that the switching wheel engages with the play wheel 25 and with the gear wheel 12. In a corresponding manner, in Fig. 4, that the flanged end 81 of the head plate 74 has pivoted the pivot arm 19 about the pivot shaft 18, whereby the gear 17 engages the play wheel 24 and the gear 11. Furthermore, in the position according to Fig. 3, the pressure roller 79 is against the display shaft 10, while in the position according to Fig. 4 the pressure roller 78 is pressed against the display shaft 9.

Longitudinal slots 84, 85 in which guide pins 86, 87 are slidable are provided in the head plate 74 parallel to the connecting line between the tone axes 9, 10.

Fig. 5 shows, on the basis of an exploded view in the head plate 74, guide pins 86, 87 »which are guided in the longitudinal slots 84, 85. The guide pins can hereby be displaced parallel to the connecting line a 30 between the tone axes. The holder of the guide pins 86, 87 on the head plate 74 is not shown in detail in the drawings. In a simple embodiment, the guide pins are attached to a cap-shaped plate as with thumbtacks. However, it is also possible to arrange the 35 guide pins on the free ends of resilient tongues which are mounted on the head plate 74.

Between the head plate 74 and the top of the 8301265; % PHD.83-035 11 4.4.83 frame 1, a control plate 88 serving as control means is provided. This control plate 88 is provided with longitudinal slots 89 »90» through which guide cams 91 »92 protrude from the chassis plate. As a result, the control plate 08 is displaceable parallel δ with respect to the imaginary connecting line a between the axes 9 »10. The displaceability is indicated in Fig. 5 by a double arrow 93.

The control plate 88 is provided at both ends with mutually mirror-symmetrically arranged U-shaped guide slots 94, 95. Of the U-shaped slots 94 and 95, one slotted leg $ 6.97 is shorter and one slotted leg 98.99 longer. The shorter legs are on the sides facing each other and the longer legs are on the facing sides of the slots. The connecting base 100 and 101 between the shorter and longer legs is greatly widened.

Between the longer and shorter legs are material tongues 102 and 103, which are pointed at the ends facing the base 100, 101.

In the frame 1, mutually mirror-symmetrically arranged fork-shaped guide slots 104 and 105 serving as guide slot devices are provided with two legs corresponding to the fork teeth, of which one leg 106, 107 is each shorter than the other leg 108, 109. Here too, the short legs lie the sides of the slots facing away from each other and the long legs on the sides facing each other. A central entry slot 3q 110, 111 is provided on the fork stem, which connects to the funnel-shaped base 112, 113 of the guide slot 104, 105. The distance 114 between the legs of the U-shaped guide slots 94, 95 in the control plate 88 is smaller than the distance 115 between the legs of the fork-shaped guide slots 104, 105

Fig. 7 shows, by means of a perspective view, the control plate 88. The control plate 88 is provided with a stop 116, 8301265 PHD.83-035 12 4.4.83, against which a nose 117 of an intermediate slide 118 can strike, which is parallel to is displaceable relative to the imaginary connecting line a between the tone axes 9 and 10. The intermediate slide 118 is provided with two stops 119, 120, against which a driver 121 of the stop button operating rod 62, which also serves as an ejector, can press. When the stop ejection button 63 has been moved outwards with the rod 62, it has brought the intermediate slide 118 outwards, because the driver 121 has collided with the stop 120. As a result, the nose 117 is pushed away from the stop 116. The control plate 88 can hereby be slid freely in the direction of the double arrow 93 according to Figs. 5 and 7. If, on the other hand, the stop / eject button 63 is pressed, the driver 121 hits the stop 119 and the nose 117 against the stop 116. The control plate 88 is therefore positioned in a preferred situation according to Fig. 6B.

The operation of the device can be described as follows. When a cassette is loaded, the stop / eject button 63 moves from the position of Fig. 2A to the position of Fig. 2B. In a manner also not shown, the electric switch of the motor 3 is closed and the motor starts to run. As a result, the flywheels 7 and 8 also rotate in the opposite direction. The gears 11 and 12 and the associated gears 14 and 17 rotate as well.

By the movement of the stop / eject button 62, the detent lever 58 of FIG. 2A pivots about the axis 59 and the detent pin 65 enters the engagement area of the heart-shaped cam 56 of FIG. 2B.

Since the gears 14 and 17 are not engaged with the gears 24 and 25, the two winding mandrels 20 and 21 do not rotate. The discs 41 and 42 are connected to the winding mandrels 20, 21 by means of their separate slip clutches and are therefore also stationary. Since a torque on the switching element 46 is missing when the cassette is introduced, since the 8301265 PHD.83-035 13 4.4.83 tape wraps do not rotate and the tape is stationary, the switching element 46 remains in the position shown in fig. 1. and thereby comes into contact with the pin 49 against the outside of the strut wall 51 · As a result, the switching element 46 5 makes a clockwise movement according to the arrow 46a and the connecting element 52 swings counterclockwise according to the arrow 67 . Because the locking lever 58 has been pivoted and the pin 65 has entered the engagement area of the heart-shaped boss 56, the pin 65 now moves around the wall 68 of the heart-shaped boss 56 and enters the recess 70. locking element locked in a pivoted position (see fig. 2B).

By pivoting the connecting element 52 counterclockwise in the direction of the arrow 67, the cam 71 is moved inwards and pressed against the leaf spring 72. The leaf spring presses against the head plate 74 via holders 76 and 77 and tries to slide it in the direction of the axes 9 »10. The operation of the control plate 88 now occurs.

Before pivoting the cam 71 inward, the head plate 74 was spaced from the pitch axes. The guide pins 86, 87 had therefore run into the entry slots 110 and 111 (see Fig. 5). The control plate 88 is in the position shown in Fig. 6a. When the head plate 74 is moved against the tone axes 9> 10, the guide pins 86, 87 move forward and contact the left side of the tongues 102, 103 and also in the left legs 106 and 109 of the guide slots 104, 105. The left guide pin 86 therefore has a stop in the shorter leg when moving 30, while the right guide pin 87 freely moves in the direction of the pitch axis 10 (see fig. 6b).

As a result, the pushed-forward head plate 74 on the right-hand side pivots forward such that the right-hand pressure roller 79 comes into contact with the right-hand axis 10. The other 35 axle axis remains unloaded. As a result, the belt runs in the direction shown in Fig. 3.

When the tire end is reached, the 8301265> PHD.83-035 14 4.4.83 tire remains. As a result, the switching element 46 is pivoted clockwise again with the pin 49, and the connecting element 52 is pivoted again counterclockwise (Fig. 2B) in the direction 5 of the arrow 67. connecting element 52 is pivoted even further during this movement after the normal pivoting, which is present in the locked position. This additional pivoting is possible, since the cam 71 presses against the leaf spring 72 on the head plate 74 and thus has deflection clearance in the direction of the head plate. At this additional pivoting, the pin 65 emerges from the recess 70 and the detent mechanism 57 is unlocked. Under the influence of the spring 54, the unlocked connecting element 52 now pivots clockwise, so that the cam 71 extends outwards. In this position, the head plate has moved away from the cassette and the guide pins 86, 87 have again entered the lead-in slots 110 and 111. The control plate 88 has remained in the last occupied position.

2Q The tongues 102 and 103 are therefore still in a left-shifted position relative to the center of the entry slots 110 and 111 (Fig. 6c).

Now the reversal of the belt running direction follows.

The shift wheel 14 is still rotating. Since the head plate 74 is retracted, it has also pulled the bent end 80 outward, thereby pivoting the pivot arm 16 such that the shift wheel 14 does not cooperate with the play wheel 25. Detection element 40 detects tire standstill. Again, the switching element 46 is pivoted clockwise. The switching element 46 presses against the connecting element 52 and again pivots it counterclockwise in the direction of the arrow 67. As a result, the pin 65 again revolves around the heart-shaped cam 56 and finally falls back into the recess 70 and locks the connecting element 52. The cam 71 has now been pushed forward again and the head plate jh takes on the position shown in fig. 4 after the movement forwards. The tooth 8301265 PHD.83-035 15 4.4.83 wheel 17 is in engagement with the gear 11 and the playing wheel 24 via the bent end 81 of the head plate 74. In this position according to Fig. 4, the pressure roller J8 lies against the PTO shaft 9 and the belt is conveyed in the opposite ® direction.

Reversal of the tape running direction is caused by the guide slot device, which is shown in various positions in Fig. 6. The last described position was the position according to Fig. 6C. In this position, the control plate 88 has shifted to the left and the gel pins 86, 87 are located in the entry slots 110 and 111. As the head plate 74 is moved forward again, the guide pins 86, 87 are also moved forward and run against the right oblique planes of the pointed 15 tongues 102 and 103 · The guide pins 86, 87 are thereby shifted to the right and run in the legs 108 and 107 ·

The transverse shifting of the guide pins 86, 87 is possible by sliding the guide pins 86, 87 into the longitudinal slots 84, 85. When walking in the legs 107, 20 and 108, the guide pins 86, 87 have taken the control plate 88 to the right, so that the legs 108 and 98 as well as 107 and 97 now cover each other. As a result, the tongues 102 and 103 are again displaced such that when the guide pins 25 are moved back and forward, they can again come into contact with the left oblique surfaces of the pointed tongues 102 and 103. The position of the guide slot device in this case is shown in Fig. 6D. The guide pin 87 has encountered a stop in the shorter legs 107 and 97, which prevents the head plate 30, 74 from continuing on the right side. On the left side, the guide pin 86 has not found a stop and this pin could extend in the legs 108 and 98 so far that on the left side of the head plate 74 the spring 72 pressed the pressure roller 78 against the tone shaft 9. This position is shown in Fig. 4. It should be noted that, while not maintaining the beneficial effect, it is also possible to fit the short legs of the slots 8301265 PHD.83-035 16 4.4.83 94, 95 and 104, 105 close to the mutually facing sides of the slots the long legs near the sides that are facing each other.

Fig. 8 shows a derived embodiment of the guide slot device and of the control means. The guide slot device consists of U-shaped grooves 122, 123, which are provided in the frame 1. The U-shaped grooves again cooperate with the guide pins 86, 87. The U-shaped grooves 122 and 123, as in the embodiment according to Figs. 5 and 6, have long legs 124, 125 and short legs 126, 127. The connecting base between the respective legs is designed as double base groove 128a, 128b and 129a, 129b. In the vicinity of these double grooves 128 and 129 guiding surfaces I30 and 131 as well as 132 and 133 acting as control means are provided. The guiding surfaces 130 -. 133 are designed as sloping ramps, which gradually extend upwardly from the bottom of the grooves and terminate at the guide contours 130a, 131a, 132a and 133a. These guide contours also belong to the control means for the guide pins 86 and 87.

The function of the guide slot devices 25 and control means according to Fig. 8 is as follows. The head plate 74 is believed to be in the position retracted from the cassette. In this starting position, the guide pin 86 rests in the recess 134 of the upper double groove 128b. The guide pin 87 rests in a recess ring 35 of the lower double groove 129a. Above the guide pins 86 and 87, the walls of the grooves 128b and 129a, respectively, are provided with guide points 136b and 137a. These guide points are slightly left with respect to the centers of the guide pins 86, 87 at the bottom groove and slightly right at the top groove. Therefore, when the head plate 74 is moved forward again, the guide pins in the upper groove can only move to the left along 8301265%. PHD.83-035 17 4.4.83 the guide surface 130 and in the lower groove can only move to the right along the guiding surface 133 This means that with this shift the guiding pin 86 slides into the shorter leg 126 and the guiding pin 87 into the longer leg 125. The guide pin 86 therefore encounters a stop when sliding after a relatively short displacement path, while the guide pin 87 can slide freely. This corresponds to the position of the head plate 74 according to Fig. 3. If the head plate fk is again shifted back to the starting position, the guide pin 86 extends through the leg 126 to the bottom groove 128a and the guide pin 87 to the top groove 129b. Thus, in the fully retracted position of the head plate, the guide pin 86 is located in a recess 138 and the guide pin 87 in a recess 139 in FIG. 8 is shown in dotted lines. If the head plate is now shifted again in the direction of the tone axes, the guide pin 86 moves in the direction of the guide plane 131 in the long leg 124 as a result of a guide point 136a. The guide pin 87 moves in the direction of the guide point 137b in the direction of the guide surface 132 in the short leg 127 · This means that in this case the guide pin 87 in the short leg 127 finds a shorter path of movement with a stop, while the guide pin 86 can move freely in the leg 124. The head plate thereby acquires a position, which can be seen in Fig. 4. When the head plate 84 is brought back again, the guide pins 86 and 87 return to the initial position described above.

The advantage of this guide slot device consists in that no moving parts are necessary for controlling the movement paths of the guide pins. The groove egg and the guide surfaces as well as the guide contours can be sprayed onto the frame in plastic.

8301265

Claims (6)

1 · Magnetic tape cassette apparatus with a device for reversing the tape running direction in which the magnetic tape is guided past at least one magnetic head which is mounted on a pivotable head plate which can be moved in the direction of the cassette and which is actuated by one of two pressure rollers arranged thereon move against the respective tone axis and thereby determine the belt running direction, characterized by - guide slot devices provided on the frame of the device, arranged on both sides of the magnetic head, - guide pins provided on the head plate, which are arranged in the guide slot devices in in the direction of an imaginary tone axis connecting line, - control means co-operating with the guide slot devices, which steer the guide pins in the guide slot devices - such that the guide pins move away from the connection line after each displacement of the head plate when they are repositioned in the direction of the connecting line is alternately fed into one guide slot device in one or the other in a guide slot leg, which leg blocks the path for the respective guide pin, whereby the on-2Q pressure roller of the pivoting head plate, the associated guide pin of which finds an unblocked path, in each case, is moved to the corresponding pitch axis and thereby determines the tape running direction. 2. Device as claimed in claim 1, characterized in that the guide slot devices consist of guide slots in the frame provided with fork-shaped, mutually mirror-symmetrically arranged guide slots with two legs corresponding to the fork teeth, one leg of which is shorter than the other leg and w. Connect to a funnel-3q shaped fork base that a lead-in groove corresponding to the fork stem is located in the middle between the legs. Device according to claims 1 and 2, characterized in that the control means consist of a control plate, 8301265 PHD.83-035 19 4.4.83, which is displaceable parallel to the connecting axes connecting line between two end positions and on both sides of the magnetic head with U-shaped guide slots is provided, in each end position of the control plate at least partially covered by the associated fork-shaped guide slots in the frame, the distance between the legs of the U-shaped guide slots being smaller than that of the fork-shaped guide slots and in which, for alternately steering the guide pins in the short or long legs, the pointed tapers, located between the legs of the U-shaped guide slots, are present, which, in each end position of the steering plate, counted in the direction of displacement of the steering plate are located laterally with respect to the entry slots. 4. Device as claimed in claim 3, characterized in that the control plate is provided with at least one stop and in that the device comprises a stop button and an operating rod connected thereto, which is provided with a nose, which is pressed against the stop button when the stop button is pressed. stop and the steering plate always shifts into one of the end positions. 3. Device according to claim 1, characterized in that the guide slot devices consist of U-shaped grooves provided on the frame, each of which is provided with a short and a long leg and with a double base groove on the base connecting the legs. the control means being formed as guide surfaces located on the bottom of the grooves, which are inclined relative to the bottom 30 and end in guide contours, which the guide pins each time after the head plate has been moved back and moved forward again in allow only the direction of the pitch axes connecting line, to run through one of the base grooves from the short leg into the long leg and in the subsequent back and forward movement through the other base groove from the long into the short leg, the short and long legs of 8301265 * PHD.83-035 20 4.4.83 the two grooves are arranged in such a way that when moving back and spark pane the head-plate one of the guide pins runs in a short leg, while the other guide pin runs in the long leg ® and when moving back and forward this one guide pin runs in the long and the other guide pin in the short leg. Device according to any one of the preceding claims, characterized in that the guide pins in the head plate 10 are displaceable in longitudinal slots running parallel to the tone axes connecting line. 15 25 1 35 8 301 265