SU562859A1 - Device for controlling a tape recorder of a magnetic recording apparatus - Google Patents

Description

The invention relates to instrumentation and can be used to damage the tape mechanism (LPL) in those magnetic recording apparatus, where the intertwining of the magnetic tape is carried out using piezo-transducers.

In the overwhelming majority of tape mechanisms, the movement of the magnetic tape is carried out with the help of a drive shaft driven by an electric motor. At the same time, the drive shaft itself can be either a continuation of the rotor of the electric motor or associated with it as a passic, as well as friction gear 1. Here, the control of the tape drive mechanism is only taken up by changing the voltage supplied to the electric motor. Therefore, the control accuracy in this case is not high enough.

When using a control circuit made only on key elements, the reliability of operation of the device as a whole decreases, since the failure of at least one element virtually eliminates the operation of the whole circuit 2.

The closest to the present invention is a device for controlling a tape-driving mechanism of a magnetic recording apparatus (AMZ), comprising a piezo transducer coupled to a hub, an actuator element interacting with them, such as a drive shaft, a generator and a speed sensor of magnetic tape 3. But this device It has a sufficiently high temperature and temporal stability of operation, which affects the uniformity of the speed of the magnetic tape.

The purpose of the invention is to increase the temperature and time stability of the operation of the device, which affects the uniformity of the movement of the magnetic tape.

For this, the proposed device is equipped with a feedback unit connected in series, a voltage amplifier, a detector, an automatic gain control unit and a power amplifier connected between the output and the input of a piezo-converter, an automatic frequency control unit connected between the second output of the voltage amplifier and the generator input, output which is connected with the second input of the automatic gain control unit, as well as the frequency discriminator connected between the output of the speed sensor magnetic tape and the third input of the automatic gain control unit.

In drawing P1, the structure of the proposed device is shown.

The device consists of two parts: a mechanic / and an electric 2. A piezotransducer 4 is connected to the input of the concentrator 3, and to the output of the concentrator there is an element of the actuator 5 connected to the sensor 6 of the speed of the magnetic tape (not shown). Output 7 of the piezoelectric & spreading device through feedback unit 8, voltage amplifier 9 and unit, automatic frequency adjustment / O are connected to generator P. Amplifier 9 through output 12 and detector 13 are connected to automatic gain control unit 14. To this same unit through the exit. 15 connected generator //. The automatic gain control unit (AGC) through the power amplifier 16 is connected to the input of the piezoelectric transducer 4, and the speed sensor 6 via the frequency dial | riminator 17 - to the IS input of the AGC unit.

When the generator is operating, the signal through the AGC unit and the power amplifier comes to a piezoelectric transducer, which converts the incoming electric oscillations into mecharic ones. The latter, having entered the concentrator, are amplified in it and begin to interact with the drive element, for example, the LPM drive shaft (shown in the drawing). When any conditions affecting the uniformity of the rotational speed of the drive element are changed, an electrical circuit is included in the work, which includes a feedback unit, an automatic frequency control unit, an AGC unit, a detector and a discriminator. That is, when the gain is varied, the AGC block comes into operation, and when the pulse frequency is changed from the generator, the frequency auto tuning block. All other elements of the electrical part of the device are designed either to amplify the signals or to detect them.

In comparison with the prototype, the proposed device has a somewhat more complicated scheme. But it should be borne in mind that the operation stability of the drive's eleteite increases several times, which is directly related to the improvement of the quality of the recorded and reproduced information. Besides

Moreover, since the transmission to the drive is from a piezotransducer, rather than from a traditional electric motor, there is a fairly high energy efficiency (for example, an average DCS type electric motor consumes 400-500 mA. A piezotransducer can consume 4-15 mA). The weight of the entire scheme described is several times less than the weight of only one electric motor.

Claims (3)

1. US patent ° 3862729, cl. 242-206, publ. 1975. 2. Japan patent ° 47448, cl. 102E31, publ. 1974. 3. Author's certificate .N9 429458, cl. G 11 B 15/20, 1972.