CS207583B2 - Drive of the magazine magnetophone - Google Patents

Abstract

A spring (52) adjustable from outside is provided between two rubbing surfaces (48, 49). A freewheel disc (53) between the rubbing surfaces (48, 49) is so designed, that the spring (52) and the two rubbing surfaces (48, 49) rotate at the same speed. A winding up spindle has a U-shaped contact. A spring is provided between the main spindle and a hexagonal driving spindle for torque transmission. A control plate is either hinged to or directly coupled with all movable or operating components. At least two gears are mounted on mechanical components.

Description

BACKGROUND OF THE INVENTION The present invention relates to the drive of a cassette recorder by means of which a cassette tape is wound and unwound by means of a gear system and the setting of the program recorded on the tape is carried out quickly by pressing the button.

In order to solve this technical problem, it is generally required to ensure constant tensile forces of the tape, easy adjustability, slight variations in speed and control of the controls.

Cassette tape drives are designed according to known solutions with a variety of design elements designed to perform a variety of functions. Known solutions have these drawbacks. The clutch forces can only be adjusted by expensive assembly. The M tape is rotated on the main shaft of the cassette or couplings in the event of a failure and is damaged. The variation in tape speed for cheaper drives such as motor drives is no better than 0.2%. A specific program on the tape can only be found by periodically pressing the following buttons: play button, stop button, play button. These numerous actions are inconvenient. It is mtnoheim more useful - press the play button and - the specific program should be search by pressing - the high-speed button. The rotating components used to wind or unwind the tape are designed as a friction drive and are therefore abraded quickly. Due to the mechanical design, a force of over 1 kp is required when the buttons are pressed.

SUMMARY OF THE INVENTION The object of the present invention is to provide construction. a cassette recorder drive, whose winding and quick winding couplings are adjustable without mounting, and in which the built-in winding spindle is provided with a winding control device. This object is achieved by driving a cassette recorder according to the invention, the principle being that a flywheel is provided between two friction surfaces, which comprises an externally adjustable pressure spring, a U-shaped contact is built into the spindle and between the a winding spindle and a hexagonal drive spindle is provided with a torque transmission spring having a control plate to which the right-turn control arm and the left-turn control arm, the pivot lever and the play arm are directly connected. The control plate is provided with two stabilizing springs.

It is also an object of the invention that the clutch flywheel is provided on both gray front faces with hemispherical recesses arranged side by side.

It is also an object of the invention that the winding spindle is supported by the contact in the

4 is rotatable and is made of a conductive material, in contact with the conductive. a surface formed to be push-button switched and provided with three terminals.

A further β-sown invention is that one end of the torsion spring is pressed against the winding spindle, the other end abutting the hexagonal drive spindle.

It is a further object of the invention that the gear wheel attached to the articulated arm is arranged. adjustable, by jumping.

The drive of the cassette recorder according to the invention removes the drawbacks of prior art cassette systems, thereby providing these important advantages in comparison with prior art solutions.

Precise adjustment, both during assembly and repair. The Morse contact, built into the winding spindle and consisting of two simple components, allows the spindle to be rotated by simple electrical means. The variation of the tape speed is less than 0.2 o / _o due to the retracting spindle and specially designed friction surfaces. The search for a particular program is very easily solved using a control board. A long-life drive is achieved with geared drive. The use of the so-called control plate makes it easy to operate the button.

The drive according to the invention is explained in more detail by way of example with reference to the drawings, in which Fig. 1 is a diagram of the principal function of the drive according to the invention; Fig. 2 shows schematically a torque limiting clutch; 4 shows the winding spindle in cross-section, FIG. Fig. 5 shows the freewheel of the take-up clutch of Fig. 2, Fig. 6 is the so-called morse contact, Fig. 7 shows the engagement of the gears by jump, Fig. 8 shows schematically the construction elements connected directly to the control plate;

The main shaft 1, pressed into the flywheel 2, is driven from the motor pulley 3'by a rubber belt 4. The same rubber belt 4 drives the winding clutch 5 and the disc 6 of the quick winding clutch. The main shaft 1 and the rubber roller 7 move the tape in the cassette at normal speed. The tape is pulled off by the winding spindle 8. The fast-winding is always dependent on the desired direction and is performed by rotation; the winding spindle 8 by the winding spindle 9. In the case of rapid winding forward, the quick coupling gear 11 is connected to the winding gear spindle 12 by means of the gear 10. If a quick rewinding is required, the quick coupling gear 11 is required. With the entire clutch unit, move it to the toothing wheel of the unwinding spindle 9. When the strip is switched off, the jumps generated by the dynamic forces are removed by the braking system. The brake arms 13 and 14 respond by purposefully selecting the center of rotation to the direction and the gap between the tongues ensures mutual delay. The various operating modes are activated by the respective adjustable mounting units controlled by the control plate 15. The control plate 15 is held in the initial position by the spring 16. The forward movement at normal speed, i.e. the playplate, is started by pressing the arm 17 against the spring 18. When the spring 16 has exceeded the center of rotation of the control plate 15, the control plate 15, caused by the force of the spring 16, continues to swing. This means that the control plate pin 15 is released from the contact surface. the fork 17 is long and by the action of the spring 16 assumes a stop position on the other side. In this case, a gap exists between the fork of the plate 17 and the pin of the control plate 15. Therefore, the control plate 15 can assume a stop position on the opposite wiped one. However, this has the effect that the arm 19 is moved by the spring 20 until the rubber roller 7 abuts the main axis 1. Because the armrest has been moved in the arm leg extension 19, the arm 21 remains under the action of the spring 22. In this case, thus, the tape was moved by the pressure roller 7 and the winding coupling. By rotating the control plate 15, the control lever 23 is rotated, according to the curve path made therein, into the working position.

The curve path in the lever 23 is formed so that the aforementioned stop position of the control plate 15 results in the bearing of the control plate 15 at the ends of the curve path. The curve track further provides the self-locking stop of the lever 23, so that even if the tape heads are subject to varying force, the heads remain still. By moving the lever 23, the brake 24 is pressed against the retracting spindle and the projection of the lever 23 first releases the arm 14 by overcoming the spring force 25, and then the arm 13 of the brake 24. The plate 17 is locked in the clamped position as detailed below. The rotation of the control plate 15 also results in its pins approaching the left quick-arm 26 and the projection of the right quick-arm 27. That is, by actuating any of the high-speed pushbuttons, the control plate 15 pivots a certain angle back. As a result of this reversal, the heads mounted on the lever 23 are moved back, the unwinding brake 24 is raised, the rubber roller 7 moves away from the main shaft 1, and the coupling arm 21 stops the unwinding. In this way, it is possible to adjust irreversibly without releasing the blocked playback operation. In fact, the gap between the fork of the plate 17 and the control plate 15 allows the rotation to be reversed.

The overdrive to the right is started by pressing the arm 27 against the spring force 28. In this case the arm 29 is pivoted by the spring 22, 30 as far as it will go, the gear 10 is coupled to the quick-coupling spindle 11 with the reel spindle. 27 on the brake arm 14. Since the gears are not forced into each other but are pressed against each other by spring force, the engagement 1 is perfect in the event of contact of the faces. In the case that the fast-moving button 8 is pressed to the right without playback, the arm 27 is locked.

The counterclockwise movement can be controlled by pressing the transfer plate 31 against the force of the spring 32. In this case, the arm 26 is pivoted according to the curved path provided in the arm, so that the lever 33 engages the quick coupler gear 11 by the spring 30. The brake is released by preloading the arm 26 to move ^! m of the brake arm 13.

Pressing the bat overdrive to the left, ie without playing, will result in the transfer plate being blocked.

The stop plate 34 is connected to the base plate by hinges 37, 38, thereby providing a minimum frictional resistance of low force when moving and providing an easy start in the spring end position. The stop plate 34 is driven in the basic position by a compression spring 35. Instead of its stopper, the stop plate pin 36. The frame 27 and the overdrive plate are blocked by an oblique path formed in the nose plate 34. The stop tab of the plate 17 is formed on the hinge 38. The recording plate 39 is held in the gray base position by the spring 40. After pressing the button, the recording plate 39 is blocked by a nose-shaped projection on the stop plate 34. Length of nose-shaped projections on the stop plate 34 at joint 38 is unequal. Their playback and recording lengths are longer, so more blocking plate movement is required to block them. This ensures that when the play is blocked, the overdrive pins move in front of the nose-shaped projections. This means that they do not want to start and that they are not blocked by themselves. The spring 41 is held in its basic position by the stopplate 36. In the event that the stopper plate 34 is in order to block some operation in the forward position, the stopper plate 34 is moved slightly further by pressing the stopper 36 so that the blocking is canceled.

During the recording process, it must be ensured that the blocking is released when the overdrive stops are depressed. This is provided by a release plate 42 held on the left side in a deflected position by a compression spring 43. The release plate 42 is provided with a protrusion disposed adjacent the recording plate 39. By pressing the recording button ¹ , the recording plate 39 moves to said protrusion and moves the release plate 42 forward .

On the release plate 42, a U-shaped projection is provided at the pivot of the high-speed arms 27, 31 provided with an inclined path. ^Appearance! Since the projections are U-shaped, the high-speed dowel pins can move forward in the base of the release plate 42. When the recording plate 39 is pressed together with the play button or separately, the release plate 42 is moved forward and its slanted paths are brought to a position where the pivot pins of the high-speed plates are facing each other. By pressing any of the high-speed buttons, the jaw snaps into the inclined path and further moves the release plate 42. The left-hand side of the release plate 42 strikes the stop plate 34 and the shutters are released. By cutting off the tips of the protrusions of the stop plate 34 it is ensured that the previously pressed button is released and the newly pressed button is locked. As a result, the buttons lying between them may remain idle. According to what has been mentioned above, this possibility does not make it desirable in the case of a playback-overdrive combination.

Giant. 2 shows an exemplary embodiment of a torque limiting clutch.

To facilitate this construction, it should be noted that the adjustment of the spring force of the prior art mement limiting couplings could only be made in a few steps and that one end of the compression spring was constantly rubbing against the support surface.

A drive disk 45 is mounted idle on the shaft 44. A molded friction bush 49 is mounted on this disk. The shaft 44 is provided with a plunger in which a mounting washer 46 is mounted. In the drive disk 45, a spindle 47 is arranged movably in the axial direction of rotation. a second felt friction pad 48 is mounted in the swivel spindle 47. A spring disc 50 is movably mounted in the axial direction, pressed against the spring 52 by a threaded nut 51. The spring 52 presses the friction pads 48, 49 together. The pivot spindle 47, the spring 52 and the sprung disk 50, the nut 51 and the release plate 42 rotate at a uniform speed. The freewheel disk 53, pushed between the friction surfaces 48, 49, moves to provide some preset torque for the driven disk 54. The driven disk 54 rotates at a lower speed than the drive disk 45.

Giant. 3 shows a bottom view of the winding spindle. A U-shaped contact made of the same material is attached to the winding spindle 55. The feet 57, 58 of the U-shaped contact 56 are spaced apart from the plane of the winding spindle 55.

Giant. 4 shows the winding spindle 55 in section. The winding spindle 55 is rotatably mounted on the fixed shaft 63. A bearing 59 is firmly pressed in the upper portion of the winding spindle 55. A fixed 60 limiting backlash 60 is attached to the fixed shaft 63. The hexagonal drive spindle 61 rotates freely on the fixed shaft 63. A fixed cap 62 is attached to the ends of the fixed shaft 63 to limit axial play. ¹ to the upstream displacement of the winding spindle 55 and the hexagonal drive shaft 61 zabra207583 sive torsion spring 64, whose two ends are přijpeivněny к mandrel 55 а к šestiúhelnému drive shaft 61. The purpose of this device is that, to be on the hexagonal drive shaft 61 is transmitted from the winding spindle 55 constant mdment.

If, for example, the torque transmitted to the winding spindle 55 fluctuates, the torque spring 64 and the mass of the winding spindle 55 together form a mechanical filter to transmit the fluctuation moment of the gray hexagonal drive spindle 61 to a slight extent.

Giant. 5 shows the freewheel disk 53 of the take-up clutch shown in FIG. 2. The two faces of the freewheel disk 53 slip between the gripped friction surfaces 48, 49 in order to keep the slip friction coefficient constant. This effect is realized by the invention such that wild hemispherical protrusions of the same size as the size of the surface friction elements 48, 49 are in contact with them on both ends of the freewheel 53. These elements are felt fibers in the described embodiment. The team. It is practically achieved that a frictional force is generated when the elementary surface is contacted, the magnitude of which varies with time. The result of several thousand frictional forces, varying with time, provides a constant time-dependent force as a statistical average.

Giant. 6 shows a so-called rotary morse contact. The U-shaped contact 56 rotates and its foot 57 is in constant contact with the guide surface 65. This corresponds to the middle spring of the immersion contact. The shoe 58 connects the guide surface 65 to either the surface 67 or 66.

Giant. 7 shows a partial construction intended to induce a step connection between the gear wheels. The gear 68 is supported on the articulated arm 69. The articulated arm 89 can be pivoted about the pivot point 71 to a small extent 72 by the force of the tension spring 70. This movement can be prevented by the arm 77 held in the gray basic position by the spring 78. When the gear 68 is moved upward, the arm 77 moves against the spring force 78. In this case, the articulated arm 69 is not yet moving because of the stop plate 75. The stop plate 75 can pivot around the pivot point 73, but first, overcoming the force of the flat spring abutting the stop 74. When the arm 77 is pushed further up, it abuts the stop 76, overcoming the force of the flat spring abutting the surface of the stop 74, the stop plate 75 pivots and the articulated arm 69 can be rotated This design is desirable because it engages when the gear wheels are engaged in the case of slow handling unpleasant noise.

Giant. 8 illustrates structural elements that are in direct contact with the control rail.

The control plate 79 rotating on the shaft 80 can assume two stable polioles. As can be seen from the drawing, a first stable position is described. Both stable positions are secured by springs 81. The fork of the play arm 84 rotating around the shaft 83 encircles the pin 85 pressed into the control plate 79. Pressing the arm 84 in the direction of the arrow overcomes the spring force 86 thereby forcing the fork of the play arm 84 to the control plate 79 to be turned on by a pin ^85: pin 80 clockwise.

Once the control plate 79 reaches the neutral position (which occurs when the ends of the shafts 80, 83, 87 lie in a straight line), the spring force 81 moves the control plate 79 further clockwise and pushes it to the second stable position. Meanwhile, the pin 88 pressed into the control plate 79 allows the plate 90 carrying the roller rotating about the axis 89 to rotate counterclockwise. Likewise, the pin 91 pressed into the control plate allows the lever 93 to rotate the collision shafts 92 clockwise. When the control plate 79 is in the second stable position, the pin 96, embossed into the control plate 79, reaches a portion of the right quick-winding arm rotating around the shaft 97 and indicated by an arrow. At this time, by rotating the quick-winding ram 85 clockwise, the part of the quick-winding arm indicated by the arrow 87 is rotated by the arm 87 pressed into the control plate 87, counterclockwise to the plate 87. to not tip over to the first stable position. Similarly, rotated control plate 79 rotating rychlonavíjecího arm 98 of the right direction Porti clockwise arrow part rychlonavíjecího arm 98 of the right direction by a pin 96, a pressed d, the control board 79 the plate in the opposite ^one direction counterclockwise, which overcomes the force of the spring 82 so that the plate does not tilt to the first stable position.

Obir. 9 shows the operation of the limit switch.

The quick-winding arm 99 of the right-hand direction guided in the direction of the arrow 100 is pressed by the force of the spring 101 into its initial position. The stop plate 102 movable in the direction of the arrow 103 is pressed by the spring force 104 into the home position. When the fast-winding arm 99 is pushed forwardly against the force of the spring 101, the pin 105 mounted in the fast-winding arm 99 remains hanging у of the respective portion of the stop plate 102. FIG. 9 shows the so-called coupled position of the fast-winding arm 99 in the right direction, in which the operation of a switch not dependent on the drawing is similarly ensured.

The closure is released by a magnet 106, i.e. a clockwise rotation of the shaped lever 108 rotatably mounted on the shaft 107. The energy of the rotational movement is transmitted by the spring 109 to the arm 110 held in the basic position and also rotates around the shaft 107 The arm 110 is positioned against the pusher plate 102 and rotates the plate in the direction of the arrow 103. Thereafter, the quick-winding arm 99 returns to its home position by the action of the spring 101.

Claims (4)

A cassette recorder drive comprising a winding spindle in a carcass, at least one glacial axis and a pressure roller, characterized in that a flywheel (53) comprising an externally adjustable compression spring (52) is arranged between two friction surfaces (48, 49}, a U-shaped contact (56) is built into the winding spindle (55) and a spring (64) for transmitting the torque is provided between the winding spindle (55) and the hexagonal drive spindle (61) and further comprises a control plate (79) ), to which are connected the control plate of the right direction quick-winding arm (98) and the quick-closing arm (95) of the left direction, the pivoting lever (93) and the play arm (84), the control plate (79) being provided with two stabilizing springs (81). while the gear wheel (68) attached to the articulated arm (69) is adjustable. Drive according to claim 1, characterized in that the clutch flywheel (53) is provided with two hemispherical recesses arranged side by side on both gray faces. Drive according to claim 1, characterized in that the winding spindle (55) is rotatably mounted with the contact (56) and is made of a conductive material, in contact with a conductive surface (65) formed for switching by pressing and equipped with three outlets. 4. The drive according to claim 1, wherein one end of the torsion spring (64) is pressed against the winding spindle [55], the other end abutting the hexagonal driving spindle (61).