SU645086A1 - Carrier tape speed measuring device - Google Patents

Description

The invention relates to the field of instrumentation and can be used to measure the speed of tape objects, in particular magnetic tape media. A device for measuring the speed of a magnetic carrier is known. It is based on recording and reading a sinusoidal signal of a fixed frequency. However, this device cannot be used when magnetic recording is already on the media. It is also known a device for measuring the speed of a tape carrier 2, comprising two light sources, two photodetectors, a driver and a time interval meter. The drawback of the device is a decrease in the measurement accuracy at the angular displacement of the photosensor relative to the direction of movement of the tape and at a relative change in the brightness of the light sources and the sensitivity of the photo detectors. The purpose of the invention is to increase the accuracy of the velocity measurement. This goal is achieved by the fact that the device is equipped with a differential amplifier with an indicator connected to its output, a switch whose inputs are connected to photodetectors, and the outputs are connected to the input of a time interval generator and the inputs of a differential amplifier and a light source intensity regulator. FIG. Figure 1 shows the structural scheme of the device for measuring the speed of a tape carrier; in fig. 2 shows the photo sensor in a position relative to the tape carrier. A moving tape carrier 1 with optical marks 2 applied to it is located between a pair of spaced apart sources of light 3, which are connected via a regulator 4 of the intensity of light sources to a power source, and two photodetectors 5. The light sources and photodetectors form a photosensor 6. Switch 7 connects the outputs of the photodetectors 5 with the inputs of the differential amplifier 8, the output of which is connected to the indicator 9, or with the input of the imaging device 10, which is connected to the meter 11 time intervals. A device for measuring the speed of a tape carrier operates as follows. Initially, in the “Installation” mode, the photo sensor 6 is installed relative to the tape carrier 1. For this, if there is no tape carrier 1 in the groove of the photo sensor 6, when the photodetectors 5 are fully illuminated, the intensity

3

the illumination is set by the controller 4 of the intensity of illumination of the sources of light 3 so that the signals from the photo-receivers, which in this mode are connected by a switch of 7 modes to the inputs of the differential amplifier 8, are equal. When the signals are equal, indicator 9 gives a zero reading.

Next, the photo sensor is mounted on the monitored device so that the tape carrier 1 covers the part of the photosensitive surface of the photodetectors. (Schematically, the position of the photo sensor 6 relative to the carrier 1 is shown in Fig. 2). After that, the inclination of the photosensor 6 is changed relative to the longitudinal edge of the tape 1 so that the signals from the photodetectors 5 become equal, which is indicated by the zero reading of the indicator 9.

With the same signals, the illuminated surfaces of the photodetectors 5 are equal, which indicates that the plane in which the optical axes of the photodetectors are located is parallel to the speed of the carrier. Do not change the slope, the photo sensor 6 is moved so that the tape carrier

I completely blocked the photosensitive surfaces of the receivers 5.

In the Measurement mode, the tape carrier 1 with optical labels 2, the distance between which is greater than the distance between the photodetectors 5, interacts with the optical pair of light sources 3 - the photodetector 5. In this mode, the outputs of the photodetectors are through the cross: 10, which generates square wave pulses and starts the meter

I1 time intervals.

four

Upon further movement, the tape carrier with optical labels interacts with the second optical pair of the light source 3 - the photodetector 5, as a result of which the second pulse formed by the imaging unit 10 stops the meter with 11 time intervals.

The proposed device provides high accuracy of measurements due to the fact that the signals of both photodetectors are aligned, which reduces the error in determining the time interval between the signals from the output of photodetectors. In addition, the oyo allows you to accurately and quickly set the photo sensor relative to the tape media without the use of special alignment devices.

Claims (2)

1. Author's certificate of the USSR No. 243843, cl. G 01B 7/04, 1967. 2. The author's certificate of the USSR № 533976, cl. G 01 P 3/36, 1976.