RU2016382C1 - Optronic measuring device - Google Patents

Abstract

FIELD: measurement technology. SUBSTANCE: device has a light flux modulator made in the form of rectangular diaphragm 4 one 5 of the faces of which is made of piezoelectric material, photoconverter 8 connected to the input of photocurrent amplifier 9. To photocurrent amplifier 9 with photoconverter 8 a negative feedback is applied with the aid of an automatic control unit composed of electric band-pass filter 10, low-pass filter with diode 11 and setting device 13 which are connected to the inputs of differential amplifier 13 the output of which is connected to protoconverter 8. The output of photocurrent amplifier 9 is connected to low-pass filter 14 connected to indicator 15. EFFECT: simplified construction.

Description

 The invention relates to instrumentation, in particular to devices for measuring the geometric parameters of parts, and can be used in mechanical engineering in the manufacture of large parts.

 Known optoelectronic measuring devices with scanning images of the edges of the product [1], which convert the position of the edges of the parts relative to the optical axis into a pulse-width signal, the duration of which is proportional to this position. Pulse-width conversion of the signal is used to exclude the influence of various amplitude factors on the measurement accuracy. These devices include an optical system, a scanning device, an electronic information processing unit with a photoconverter and a size deviation indicator. All these devices contain a complex mechanical design of the scanning unit, since the accuracy of the measurement depends on the accuracy of setting the scanning law.

 Of the known optical-electronic devices, the closest in technical essence is a device for measuring the angular coordinates of a point radiation source [2].

 This device contains a light flux chopper made in the form of two modulators with different modulation frequencies, a selective photocurrent amplifier with an automatic gain control unit tuned to the frequency of the first modulator, and a band-pass filter connected to the photocurrent amplifier and tuned to the frequency of the second modulator.

 The disadvantage of this device is the complexity of the mechanical structure, since the device contains two rotating modulators. In addition, modulators are sources of errors due to the extreme technological accuracy of their manufacture.

 This device cannot be used to measure the dimensions of parts without additional changes due to the measurement of the position of the boundary of the extended part, and not a point object.

 The aim of the invention is to simplify the design of the device.

 The goal is achieved by the fact that in an optical-electronic measuring device containing a light chopper, a photoconverter, a photocurrent amplifier with an automatic gain control unit and a bandpass filter included in its circuit, a low-pass filter included between the photocurrent amplifier and an indicator, the light chopper in the form of a U-shaped plate and mounted longitudinally on its inner side of the longitudinal plate, forming a rectangular diaphragm, and an alternating voltage source, longitudinal the plate is made of piezoelectric material and connected to an AC voltage source.

 This difference makes it possible to significantly simplify the design of the measuring device and its dimensions, since it completely lacks mechanical rotating elements with electric drives. The exclusion of mechanical rotating parts also increases the reliability of the measuring device, since these elements are sources of failure.

 Figure 1 shows a diagram of a device; figure 2 is a section aa in figure 1; figure 3 is a diagram explaining the operation of the device.

The device consists of a light source 2 intended to illuminate the measured part 1, which increases the contrast of the image. In the image plane of the lens 3, a rectangular diaphragm is installed, consisting of a U-shaped plate 4 and a longitudinal movable plate 5, which is made of a piezoelectric material and connected to an AC voltage source 6. A rectangular aperture with elements 4, 5 and an AC voltage source 6 constitute a light chopper flow. A condenser 7 is installed behind the diaphragm, which collects the light flux to the photoconverter 8, which is in turn connected through a load resistor R _n to the photocurrent amplifier 9. The photocurrent amplifier 9 is a DC amplifier and its bandwidth is limited by the frequency of the voltage source 6. A unit is connected to the photocurrent amplifier 9 automatic gain control (AGC), consisting of an electric band-pass filter 10 tuned to the frequency of the voltage source 6, a low-pass filter 11 with diode V and a driver 12, which oedineny to the inputs of the differential amplifier 13, which in addition to enhancing the function also performs the function of the comparison element. The output of the differential amplifier 13 is connected to the photoconverter 8. The output of the photocurrent amplifier 9 is connected to a low-pass filter 14, which, in turn, is connected to the indicator 15.

When the measuring device is operating using the oscillatory motion of the piezoelectric plate 5, the light flux coming from the measured surface of the part 1 is modulated. The energy source of the oscillations is the voltage source 6. The modulated light flux Φ (t) (diagram 16 in FIG. 3) contains a constant Ф _о and the variable components f _m . The constant component of the light flux is determined by the position of the tangent to the measured surface, i.e. the deviation of the part size from the nominal one, and the magnitude of the variable component is constant and is set by the oscillation amplitude of the plate 5 using a voltage source 6. Then, the modulated light flux through the condenser 7 is fed to a photoconverter 8, where it is converted into electric current, which is then converted to a resistor R _n into the voltage is amplified by the photocurrent amplifier 9. The voltage from the output of the photocurrent amplifier 9 is supplied to a low-pass filter 14, which emits a constant component of the signal, is proportional hydrochloric deviation from the nominal size. Then the signal from the output of the low-pass filter 14 is fed to the indicator 15, which registers the deviation of the part size. To exclude the influence of changes in the illuminance of the surface of the part on the measurement result, as well as changes in various parameters of the measuring device (sensitivity of the photoconverter, gain of the photocurrent amplifier, etc.), an automatic gain control unit (AGC) is introduced. When the illumination of the part changes, the amplitude of the variable component of the signal also changes, which is extracted using a band-pass filter 10, which is then converted to direct voltage using a low-pass filter 11, which, in turn, is fed to the inverting input of the differential amplifier 13. To the second non-inverting input the amplifier 13 receives a signal from the setter 12. The change in the illumination of the part is converted into a constant voltage supplied to the inverting input of the amplifier 13, which amplifies this change The voltage and output voltage of the amplifier 13 changes the supply voltage of the photoconverter 8, and, accordingly, its sensitivity so that the variable component of the signal at the output of the amplifier of the photocurrent 9 remains constant. At the same time, by changing the sensitivity of the photoconverter 8, the influence of illumination on the constant component of the signal at the output of the low-pass filter 14, and therefore on the measurement result recorded by the indicator 15, is compensated. The change in the parameters of the measuring device is also compensated.

 When an optical-electronic measuring device is introduced to determine the geometric parameters of large-sized parts of chemical and oil equipment, the productivity of their manufacture on roll bending machines is increased, since the reliability of the device increases, and therefore, the time for repair and adjustment of the measuring device is reduced. In addition, in comparison with the base object, the cost of the measuring device itself decreases and with an increase in their number at the enterprise, the amount of savings can be a significant article of the overall economic effect of implementation.

Claims (1)

 OPTICAL-ELECTRONIC MEASURING DEVICE, comprising a light chopper, a photoconverter, a photocurrent amplifier with an automatic gain control unit and a bandpass filter included in its circuit, a low-pass filter included between the photocurrent amplifier and an indicator, characterized in that, in order to simplify the design, the luminous flux interrupter is made in the form of a U-shaped plate and movably mounted on its inner side of the longitudinal plate, forming a rectangular diaphragm, and the source is variable voltage, the longitudinal plate is made of piezoelectric material and connected to an AC voltage source.

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