SU605077A1 - Device for measuring lateral deformation of moving band - Google Patents

Description

the electrostatic carrier tape 5, on which the control signal 6 is recorded as a latent electrostatic image of two straight lines located at a distance L. The sawtooth voltage generator 7 is connected to the deflection systems of the CRT 1 and CRT 2, the source of which is connected to the cathodes of which of a constant voltage 8. Grounding, respectively, through resistors 9 and 10, counter electrodes 3 and 4 are connected via terminating amplifiers 11 and 12 to the input of a trigger 13, one output of which is connected to one of the inputs of a key device 14 and to i One of the driver 15. A high-frequency square pulse generator 16 is connected to another input of the key 14. The key output is connected to the indicator 18 via a pulse counter 17, and the output of the driver 15 is connected to the O input (zero setting) of the pulse counter 17. The driver 15, the pulse counter 17 and indicator 18 form a digital display unit.

The device works as follows.

The recorded control signal 6 is read from the moving tape of the carrier 5 by feeding the deflection of the CRT system 1 and CRT 2 from the sawtooth voltage generator 7, and the cathodes of these tubes - a signal from the constant voltage source 8. The CRT 1 and CRT 2 are set that the centers of their screens are located at distance A.

Thus, the electron beams of the CRT 1 and the CRT 2 are synchronously scanned over the surface of the moving carrier tape 5.

When an electron beam hits the electrodes of a metal-fiber screen of CRT 1 and CRT 2, located opposite the uncharged portions of the carrier 5, an air break through the weft between the screen of the tubes and the carrier 5, which is approximately 20 µm, occurs. Charge is transferred to carrier 5, which flows in the form of current through carrier circuit 5 — a counter electrode – resistor – housing. Resistors 9 and 10 (see Fig. 2a) produce a voltage drop with an emphasis t / i. When an electron beam hits the electrodes of the CRT 1 and CRT 2 metal screen located opposite the pilot signal sections (the control signal is a latent electrostatic image of two straight lines), an air gap between the CRT 1 and CRT 2 screens and the carrier 5 is broken and transferred charge, the value of which depends on the potential difference between the tube screen electrode and the portion of the control signal. This charge flows in the form of a current along the same circuit. On resistors 9 and 10, the voltage drops to f / g (see Fig. 2a).

With simultaneous scanning of CRT 1 and CRT 2 rays on the surface of the carrier 5 in the absence of transverse deformation of the carrier 5, the rays intersect the control signals simultaneously. Amplifiers-limiters 11 and 12 on the leading edge of the control signal form pulses (Fig. 2a and b). FIG. 3 shows the impulse with a line. These pulses simultaneously arrive at the separate inputs of the trigger 13, which does not work in this case.

In the case of the presence of transverse deformation of the carrier, the limiting amplifiers 11 and 12 form pulses whose leading edges are spaced apart in time (see Fig. 2a and b). The first pulse triggers the trigger 13, and the second sets it to its original position. In this case, a pulse is formed at the output of the trigger 13, the duration of which is directly proportional to the amount of lateral deformation of the moving carrier. This pulse opens the key 14 for the duration of its duration, through which the high-frequency rectangular pulses from the generator 16 arrive at the pulse counter 17. The magnitude of the deformation is digitally recorded using an indicator 18. The pulse counter is reset to zero by the signal coming from the former 15 and forming on the falling edge of the pulse with the trigger 13.

Installing the centers of the CRT 1 and CRT 2 screens at a distance equal to the distance between the pilot lines, and synchronous scanning of the rays of these tubes completely affect the lateral oscillations of the carrier 5 and allow the transverse deformations of the information carrier to be measured with high accuracy in a dynamic one.

Claims (2)

1. Author's certificate of the USSR No. 368469, G 01B 7/00, 1971. 2. USSR author's certificate number 346744, G 01B 9/00, 1972. (prototype).