DE3003551A1 - Drive mechanism for tape recorder - has DC motor coupled via two gears to wind and rewind capstans holding tape spools - Google Patents

Abstract

The drive mechanism has two spool capstans, one of which is driven via gearing by an electromotor. The electromotor (17) can be coupled via a toothed-wheel gear (19,23-27,31,33) to the capstan (13) that winds up the tape in order to drive the tape. The electromotor is a dc motor with a permanently magnetic stator and a no-iron rotor shaped like a bell that overhangs the permanent magnet of the stator. The gear has plastic cogs. For fast rewind, the motor drives the rewind capstan via a second gear. A cog (23) is located at one end of the pivoted arm and comes into contact either with the one gear or the other according to the position of the arm.

Description

Tape drive

The invention relates to a tape drive with two mandrels for Winding or unwinding a magnetic tape, at least one of which has a Transmission can be coupled with an electric motor.

In conventional tape drives, the electric motor drives one a flywheel connected to the capstan to which the MagnetSantena ef or Wiedyabe is pressed. The winding mandrels are operated via slip clutches and a speed-reducing Transmission either from the same electric motor or from additional electric motors driven. Conventional tape drives are therefore relatively expensive and thus expensive. With the slip clutches and usually as a friction roller gear or Belt drive trained gear of the winding mandrel drive is Wear parts that are often only replaced after dismantling the drive can. After all, the high weight of the flywheel is important in many applications undesirable.

In the case of tape drives, which are satisfactory, but not If the synchronization requirements are too high, attempts have already been made to use the magnetic tape when recording or playing back, not via a capstan, but via the winding one To drive the winding mandrel, which then, however, depends on the winding diameter changing belt speed was accepted. With these tape drives but were sufficient synchronization properties only with the use of a flywheel and a mechanically decoupling belt or friction gear between the electric motor and to reach the winding mandrel.

The object of the invention is to provide as small, light and as possible at the same time structurally simple and thus inexpensive tape drive of high reliability indicate which synchronization properties are sufficient for use in the voice frequency range Has.

This object is achieved according to the invention in that the bath On-electric motor to drive the magnetic tape took or playback via a gear transmission can be positively coupled with the winding mandrel which is wound up during playback and that the electric motor as a DC motor with a permanent magnet stand and a ironless rotor is designed with helical winding. Such a thing, also for tape cassettes A suitable tape drive is particularly suitable for use in telephone answering machines and dictation machines. The electric motor drives the magnetic tape when it is Do not hear or play via a sound wave, but exclusively via the winding mandrel. In contrast to conventional tape drives however, the electric motor is positively connected to the winding mandrel via the gearbox, i.e. not mechanically decoupled from the winding mandrel. This means that there are no wearing parts more conventional Tape drives. Although gear transmission due to the alternating engagement of the Teeth per se tend to produce additional wow and flutter Surprisingly shown that when using a DC motor with permanent magnet stator and ironless rotor with skew winding, no flywheel is required. While conventional DC motors with an iron armature generate wow and flutter, if the rotor poles move past the stator poles, such wow and flutter occur does not occur in DC motors with ironless rotor with helical winding. Using such a DC motor does not require any mechanical decoupling between Motor and mandrel and also no flywheel, at least in the voice frequency range to achieve satisfactory synchronization properties.

The rotor of the DC motor can take the form of a permanent magnet stand overarching bell-runner -have in a cylindrical gap between the permanent magnet of the stator and a hollow cylindrical iron back yoke. Disc motors are also suitable, but it is also important here that the winding of the rotor is designed as a helical winding helical windings have the advantage that their turns are not exposed to an abrupt field change when the rotor rotates which would lead to wow and flutter. The turns of the skew winding can have a diamond shape, with the individual diamonds against each other in the circumferential direction are offset. However, the turns can also be used to produce a cylindrical one Winding body at an angle from one end face to the other end face of the winding body extend.

In order to keep the switching shocks of the gear transmission as small as possible, helical gears are preferred. Herringbone teeth are particularly suitable Bikes. The by passing errors of the Fluctuations in the synchronism of the gears occur can still be reduced by choosing a module that is as small as possible. The module of the gears should be less than or equal to 0.35.

Any residual / wow and flutter by electrical means To be able to regulate, the inertia of the drive elements of the tape drive should be be as small as possible.

The gears of the gear transmission therefore preferably consist of Plastic.

In order to use the electric motor for both the To be able to use or playback as well as for fast rewind is expedient provided that the electric motor to drive the magnetic tape during fast reverse Via a second gear drive, form-locking with the one that winds up during the return Winding mandrel can be coupled and that pivotable on one about the axis of rotation of the electric motor Arm is rotatable with a gear wheel constantly meshing with an output pinion of the electric motor is mounted, which alternates with a depending on the pivot position of the arm to be brought into engagement with a gear of the first or the second gear transmission coaxial pinion is firmly connected.

In the following, an embodiment of the invention will be based on Drawings are explained in more detail. 1 shows a schematic plan view to a cartridge drive; Fig. 2 is a plan view of the cartridge drive according to 1 with the cover plate removed in the playback mode; Fig. 3 is a plan view of the cassette drive according to Figure 1 in the rewind mode; 4 shows an axial section through a DC motor usable in the cassette drive of Figure 1; Fig. 5 a perspective illustration of the rotor of the direct current motor according to FIG. 4.

The cassette drive of FIG. 1 carries on a cover plate 1 to Adjustment of a tape cassette 3 relative to one attached to a base plate 5 Tape head 7 guide pins 9 or 11. The guide pins 9 are firmly attached to the cover plate 1 attached, the guide pins 11 are movable transversely to the guide pins 9 and are held resiliently biased.

Two winding mandrels 13 and 15 protruding beyond the cover plate 1 grip form-fitting in winding hubs, not shown, of the tape cassette 3 which the tape is wound or unwound depending on the direction of movement.

A single DC motor is used to drive the cartridge drive 17 (Fig. 2 and 3) provided, which alternately either in the recording or playback mode the winding mandrel 13 or in fast reverse the winding mandrel 15 drives Fig. 2 shows with the cover plate 1 removed, an output pinion 19 of the direct current motor 17, which constantly meshes with a gear 23 mounted on an arm 21. The arm 21 is coaxial to the pinion 19 pivotally mounted on the base plate 5, so that an equiaxed non-rotatably connected to the gear 23 pinion 25 optionally with a rotatable the base plate 5 mounted gear 27 or a coaxially rotatably fixed with the Winding shaft 15 connected gear 29 can be brought into engagement. Fig. 2 shows the pinion 25 meshes with the gear 27. The gear 27 is coaxial non-rotatably connected to a pinion 31, which is permanently rotatably fixed with a coaxial with the winding mandrel 13 connected gear 33 meshes.

The DC motor 17 drives the winding mandrel 13 via the out of the Wheels 19,23,25,27,31 and 33 existing gear drives with constant speed at. The belt speed changes depending on the current winding diameter on the pulling winding mandrel 13. So much for recording and playback is performed on the same cassette drive, the tape will be played back however, at every point with the tape speed used for recording emotional.

Fig. 3 shows the cartridge drive during the rewind operation.

The arm 21 is pivoted to the left, so that the pinion 25 with the Gear 29 meshes with the winding mandrel 15 in the opposite direction to the direction of rotation of the winding mandrel 13 drives. The reduction ratio of the one consisting of wheels 19, 23, 25 and 29 Gear drive is less than that of the gear drive effective in playback mode, so that the winding mandrel 15 threatens when fast reversing at a higher speed than the winding mandrel 13 in the recording and playback mode.

About wow and flutter due to the meshing of the gear trains to reduce, all gears are helically toothed and have a module of about 0.3. They exist, except for the pinion 19, to reduce the moment of inertia made of plastic.

FIGS. 4 and 5 show details of the direct current motor 17. A permanent magnet 35, which is radially magnetized to form the stator poles, is seated on a central extension 37 of an end flange 39, which is in a permanent magnet 35 coaxially enclosing cylindrical tube 41 is held.

The approach 37, the end flange 39 and the tube 41 form the iron return path of the permanent magnet 35. In the cylindrical annular gap between the permanent magnet 35 and the tube 41 engages a helical winding 43 of an ironless, in Fig. 5 closer rotor 45 shown. The helical winding 43 has from one end face to the other coils 47 running obliquely to the circumferential direction, which in layers with alternating Tilt are wound to the circumferential direction. The skewed winding 43 is held in a cantilevered manner on a flange 49, which is firmly attached to a pinion 19 carrying Output shaft 51 is seated. The output shaft 51 is on the one hand in a sintered bearing 53 of the end flange 39 and on the other hand in a sintered bearing 55 one on the pipe 41 mounted end flange 57. With 59 in Figure 4 is a commutator of the DC motor 17; # Terminal lugs are shown at 61.

Claims (7)

Claims tape drive with two mandrels for winding respectively. Unwinding a magnetic tape, at least one of which has a Transmission can be coupled to an electric motor, characterized in that the electric motor (17) for driving the magnetic tape during recording or playback via a gear drive (19,23-27,31,33) is positively coupled to the winding mandrel (13) and that the electric motor (17) is a direct current motor with a permanent magnet stand (35,39,41) and an ironless rotor (45) with a helical winding (43) is. 2 tape drive according to claim 1, characterized in that the DC motor (17) a permanent magnet (35) of the stator overlapping bell-shaped rotor (45). 3. tape drive according to claim 1, characterized in that the DC motor is designed as a disc motor. 4. tape drive according to claim 1, characterized in that the Gear transmission (19,23-27,31,33) has helical gears. 5. tape drive according to claim 1, characterized in that the Gear transmission (19,23-27,31,33) has gears with a module less than or equal to 0.35. 6. tape drive according to claim 1, characterized in that the Gear transmission (19,23-27,31,33) made of plastic gears. 7. tape drive according to claim 1, characterized in that the Electric motor (17) to drive the magnetic tape when fast reversing over a second gear drive (29) form-fit with the winding mandrel that winds up on return (15) can be coupled and that pivotable on one about the axis of rotation of the electric motor (17) Arm (21) with an output pinion (19) of the electric motor (17) constantly meshing Gear (23) is rotatably mounted, which with a depending on the pivot position of the arm (21) alternately with a gear (28 or 31) of the first or the second Gear transmission to be brought into engagement coaxial pinion (25) firmly connected is.