SU641494A1 - Magnetic tape tensioning device - Google Patents

Description

I

The invention relates to the field of magnetic recording, in particular, to devices for magnetic tape.

Tensioning devices for magnetic tapes are known in which tension is created by braking with slipping in the feeding unit 1.

The disadvantage of such devices is the oscillation of the tension of the magnetic tape, which leads to fluctuations in its speed and, consequently, to distortion of recording and reproduction.

The limes also include devices for tensioning the magnetic tape, comprising a housing, two pairs of rotors, and a switching unit cooperating with them, consisting of nodes mounted on the axles (2).

The disadvantage of these devices is the inadequacy of the tension of the magnetic tape.

The purpose of the invention is to ensure the constant tension of the magnetic tape.

The goal is achieved by the fact that in the device for tensioning the magnetic tape, the first node is made in a double-sided gear sleeve, and the second is in the form of a gear wheel and two gear sleeves, the first of which interacts with the gear wheel through a detachable coupling, and the second with the first through the overrunning clutch, while the gear wheel interacts with a double-sided gear sleeve and both nodes interact with two pairs of rotors.

FIG. 1 image of a device for tensioning a magnetic tape with an electric motor AND its path of drawing; in fig. 2 - a device for tensioning a magnetic tape, a slit.

In case I, rotors 2 and 3 are mounted on axis 4 and rotors 5 and 6 are mounted on axis 7. Axes 4 and 7 rotate in bearings 8 and 9, respectively. The rotors 2 and 3 freely rotate through the covers 10.

on axis 4, and rotors 5 and 6 and base 7 - through covers 11. The rotors are made of magical soft material and covered inside with copper or other material that acts as short locking coils for currents induced by EMF. On the outside

the rotor has toothed gears through which it connects to a switching unit consisting of a double-sided gear sleeve 12, a gear wheel 13 that is engaged with a larger

gear bushing 12, first gear bushing 4 with detachable coupling 15. second sponge bushing with overrunning coupling 17 and liner 18. Both assemblies rotate freely on axles 19 and 20. Bushings 21 serve for sampling backlashes. 1, the spring 22 serves as the dh connector of the detachable coupling when the direction of rotation of the gear sleeve 14 is changed.

The rotor 6 is connected by a gearing with a small gear of a double-sided gear sleeve 52, which is engaged with the gear wheel 13. Through a detachable sleeve 15, the gear wheel 13 is connected to the first gear sleeve 14, which is in constant engagement with the rotor 3. Tension with an electric motor 23 is necessary on axles 4 and 7 to place overrunning clutches 24 and 25 so that when the motor rotates clockwise, the rotation through belt 25 is transferred to the rotor 2, and counter-clockwise to the rotor 5. Through the axes 4 and 7, the passages 27 and 28 rotate to the feeding unit 29 with the coil 30 and the receiving unit 31 with the coil 32. With the magnetic tape loaded into the path with the magnetic heads 33 and the drive unit 34 and 35, the tension device operates as follows in a way.

Coil 30 has a full roll of magnetic tape, and on coil 32 it is missing.

When the tape recorder is turned on, the electric motor 23 has to rotate counterclockwise, so that Kak has a minimum coil radius of 32, then the rotor 5 makes the maximum number of revolutions to ensure that the carrier is underneath. The rotor 2 makes the minimum number of revolutions under the action of the drive unit 34 and 35, since the radius of the carrier on it is maximum. The rotor 5, rotating with a large number of revolutions, carries with its magnetic field the rotor b, at which the maximum torque will be induced. Since the rotor 6 is connected via gear joints and detachable coupling to the rotor 3, the latter rotates clockwise at maximum speed, inducing the maximum torque on the rotor 2, creating the necessary tension on the carrier in the path. At the moment when the radii of the magnetic tape at the feed and receiving nodes 29 and 31 become equal, the slip of the rotors in magnetic fields will be equal, and therefore the torques of the rotors 3 and 6 will be equal, since they are directed to opposite sides then take a fixed position.

As soon as the magnetic tape on the receiving unit 31 becomes more than on the feeding unit 29, the speed of the rotor 2 will become greater than the speed of the rotor 5. The rotating moment of the rotor 3 will become greater than the rotational moment of the rotor b, and the rotor 3 will begin to rotate counterclockwise, which will lead to a change the direction of rotation of the gear bushing 14 under the action of the spring 22. The gear bushing 14 will be connected to the gear 13 and will engage through the overrunning clutch 17 with the second gear bushing 16.

After this commutation, the rotors 3 n 6 have a consonant rotation, i.e. counter clockwise, and since the rotor torque 6 is greater than the rotor torque 3, the induced power on the rotor shaft 5 will continuously increase with increasing radius of the magnetic tape. The power on the shaft of the rotor 2 decreases in proportion to the decrease in the radius of the tape on the feeding unit 29.

When changing the direction of the rotating motor 23 clockwise, the switching will occur between the gears, the device will take its original position and repeat the work cycle.

Claims (2)

1. USSR author's certificate number 355653, cl. About And At 15/18, 1972. 2. US patent number 3809336, cl. 242-202, 1974. Zf 3t J2