RU2077706C1 - Digital pyrometer of spectral ratio - Google Patents

Abstract

FIELD: high- temperature technological processes. SUBSTANCE: device has oscillator with photodetector, complex light filter, photo current amplifier with automatic control unit, which has peak detector, setter and differential amplifier, which is connected to control element of photo current amplifier. In addition device has Schmidt flip-flop, which is connected to amplifier, univibrator, which is connected to Schmidt flip-flop, subtraction unit, which output is connected to control input of commutator, which connects amplifier to serial circuit of signal generator, Schmidt flip-flop, and inverter, which is connected to control input of commutator through AND gate, which second input is connected to flip-flop. Commutator connects clock oscillator and pulse counter. EFFECT: increased functional capabilities. 2 dwg

Description

 The invention relates to instrumentation, in particular to devices for measuring the temperature of heated products, and can be used in the manufacture of rolled products, forgings and shells.

 Known optoelectronic systems for measuring the temperature of products with pulse-width modulation of the output signal [1] containing logarithmic converters.

These optoelectronic systems have the following disadvantages:
limited measurement accuracy due to the dependence of the parameters of the semiconductor elements of the logarithmic converters on external temperature conditions;
the complexity of tuning and calibration of such systems due to the inability to control the characteristics of nonlinear semiconductor elements.

 The closest in technical essence to the invention is an optical-electronic device for measuring the dimensions of heated products [2] containing a vibration scanner, two light filters, a photodetector with a photo-current amplifier, an automatic gain control unit (AGC), a Schmitt trigger, the input of which is connected to the output of the photo-current amplifier , a single-shot, connected to a Schmitt trigger, a generator of periodic signals of a special shape, a second Schmitt trigger, the input of which is connected to the outputs of two switches, and the output is connected to a control The main input of the third switch connecting the clock generator to the pulse counter.

 This measuring device has a low technical level, due to its functionality, namely the ability to measure only the relative value of the temperature correction, and with low accuracy. The main error in measuring the temperature difference is determined by the error in approximating the dependence of voltage on temperature, because the dependence is approximated by only one functional dependence - exponential.

 In this regard, the most important task is to create a new digital spectrometer pyrometer, which would measure with sufficient accuracy and present the result in digital form.

 The technical result of the claimed digital spectrometer pyrometer is to increase the measurement accuracy and ease of use of this measuring device, since the measurement result is displayed on a digital display.

 In addition, the presence of a digital output on the device allows it to be used as part of automated systems for controlling the production of products in a heated state.

 The specified technical result is achieved by the fact that a digital spectrometer pyrometer containing a vibration scanner, two light filters, a photodetector with a photocurrent amplifier, an automatic gain control unit (AGC), a Schmitt trigger, the input of which is connected to the output of the photocurrent amplifier, is a one-shot connected to a Schmitt trigger, a generator of periodic signals of a special form made in the form of a four-terminal with RC elements, a switch and a series-connected clock generator, the second commutator Ohr and pulse counter, equipped with a subtraction unit, the first input of which is connected to the output of the first Schmitt trigger, the second input is connected to the output of a single-shot, and the output is connected to the control input of the switch, connecting the output of the photocurrent amplifier with a signal generator of a special shape, the output of which, in turn , connected to the input of the second Schmitt trigger, and a two-input logic element And, the first input of which is connected to the output of the first Schmitt trigger, the second input is connected through the inverter to the output of the second Schmitt trigger , and the output of the element And is connected to the control input of the second switch.

 This difference makes it possible to increase the accuracy of temperature measurement, since the digital spectrometer pyrometer provides the ability to control the approximation of the dependence of the pulse duration on the product temperature, and to simplify the digital pyrometer scheme, since it lacks converters: functional and analog-to-digital.

 In addition, this difference makes it possible to increase the reliability of the pyrometer, since blocks with low reliability are excluded from its structure.

 The analysis of the prior art by the applicant, including a search by patents and scientific and technical sources of information and identification of sources containing information about analogues of the claimed solution, made it possible to establish that the applicant did not find an analogue characterized by features identical to all the essential features of the claimed invention. The definition from the list of identified analogues of the prototype as the closest solution for the totality of features made it possible to identify the set of essential distinguishing features in relation to the applicant's technical result in the claimed subject matter set forth in the claims.

 Therefore, the claimed invention meets the requirement of "novelty" under applicable law.

 To verify the conformity of the claimed invention to the requirement of the "inventive step", the applicant conducted an additional search for known solutions in order to identify features that match the distinctive features of the claimed invention, the results of which show that the claimed invention does not explicitly follow from the prior art.

 Therefore, the claimed invention meets the requirement of "inventive step".

 In FIG. 1 shows a block diagram of a pyrometer; figure 2 is a time-pulse diagram explaining the operation of the pyrometer.

 The pyrometer is a lens, in the image plane of which a composite filter 2 is installed, consisting of two filters with different passband and a dividing line perpendicular to the scanning direction. The spectral bandwidths of the filters are selected in such a way that when stabilizing the luminous flux passing through one filter, the luminous flux passing through the other filter does not exceed the luminous flux of the first filter in the entire temperature range of the heated product. A scanner is installed behind the composite filter 2, which is a vibrator 3, oscillating with a generator 4. A photodetector 5 is mounted on the free end of the vibrator 3, and a mask 6 is installed between the photodetector 5 and the filter 2, which covers the scanning area of the photodetector 5.

 To the amplifier 7 of the photocurrent connected to the photodetector 5, an automatic gain control unit (AGC) is connected, consisting of a peak detector 8, a setter 9, which are connected to the inputs of the differential amplifier 10, which, in addition to the amplification function, also performs the function of a comparison element. The output of the differential amplifier 10 is connected to a controlled element of the photocurrent amplifier 7. The first Schmitt trigger 11 is connected to the photocurrent amplifier 7, to which, in turn, a single-shot 12 of duration τ is connected. The output of the first Schmitt trigger is connected to the first input of the subtraction unit 13, and the output of the single-vibrator 12 is connected to the second input of the subtraction unit 12. The output of the subtraction unit 13 is connected to the control input of the first switch 14, connecting the output of the photocurrent amplifier 7 with a special form signal generator 15, which is quadrupole made on RC elements. A second Schmitt trigger 16 is connected to the output of the signal generator 15, the output of which is connected to the inverter 17. The output of the first Schmitt trigger 11 and the output of the inverter 17 are connected to the inputs of the two-input logic element 18, the output connected to the control input of the second switch 19 connecting the clock generator 20 with pulse counter 21.

 When the pyrometer is operating, the vibrator 3 with the photodetector 5 makes a reciprocating motion, transforming the spatial distribution of the brightness of the product into a temporary one. Since the filter 2 is composite and a mask 6 is installed behind it, the signal from the output of the photocurrent amplifier (diagram in figure 2) has a stepped shape.

 The filters are selected so that the voltage of the first stage in a given temperature range is less than the voltage of the second stage of the pulse. The voltage pulses from the amplifier of the photocurrent 7 are supplied to the peak detector 8 with a discharge time exceeding the scanning period. Thus, a constant voltage equal to the voltage of the second stage of the pulse is supplied from the peak detector to one input of the differential amplifier 10. At another input of the differential amplifier, a constant voltage is supplied from the master 9, with which the voltage of the peak detector is compared.

When the temperature of the product changes, the maximum voltage of the pulses arriving at the peak detector 8 changes, and the voltage deviation from the set value is amplified by a differential amplifier 10, which, in turn, changes the gain of the photocurrent amplifier 7 so that it is the maximum voltage or voltage of the second pulse stage U ₂ remains constant. The voltage of the first pulse stage U ₁ is determined by the temperature of the product. The signal from the amplifier of the photocurrent 7 is fed to the input of a Schmitt trigger 11 with a response threshold U _n1 , from the output of which rectangular pulses with a constant amplitude (diagram U _n , Fig. 2) trigger a single-shot 12 with a duration t. The signals from the output of the Schmitt trigger 11 and the output of the one-shot 12 are fed to the inputs of the subtraction unit 13, the output signal of which through the first switch 14 temporarily (t-τ) connects the four-terminal 15 made on RC elements to the photo current amplifier 7. At the output of the four-terminal network, a pulse is generated with a shifted and more gentle front edge (diagram U ₁₅ , figure 2), the shape of which is a transient process when exposed to a step function with voltage U ₁ .

The one-shot 12 eliminates the influence on the transition function of the shape of the front of the voltage pulse at the output of the photocurrent amplifier 7, because he "cuts off" with the help of the subtraction block 13 the front of the pulse. The signal from the output of the quadripole 15 is fed to the input of the second Schmitt trigger 16 with a response threshold U _n2 , the response time of which is determined by the shape of the transient process in the four-terminal network and the voltage value of the first pulse stage U ₁ , and therefore the product temperature. The signal from the output of the Schmitt trigger 16 is inverted by the inverter 17 and fed to one of the inputs of the logic element And 18, and to the other input the signal from the Schmitt trigger 11. At the output of the logic element And 18 a rectangular pulse is formed (diagram U ₁₈ in figure 2), the duration of which is determined by the difference in the time moments of the triggering of Schmitt triggers 11 and 16, and therefore the value of the temperature of the product. So, for example, when the temperature of the product decreases according to the Golitsyn-Vin law, the radiation maximum shifts to the right along the spectrum and, although with decreasing temperature, the radiation flux decreases due to the AGC block, which in this case increases the gain of the photocurrent amplifier, the voltage of the first stage increases. With a decrease in the voltage of the first stage, the pulse duration at the output of the AND 18 logic element also decreases, which is converted into a digital code, because the second switch 19 for the duration of the pulse duration connects to the pulse counter 21 a clock generator 20.

 The parameters of the filters, the duration of the pulse of a single vibrator, and the structure and parameters of the four-terminal are chosen so that the dependence of the duration of the pulse on the temperature of the product at the output of the logical element And is close to linear. The choice of the structure and parameters of the four-terminal network for a given transition function is based on the methods of synthesis of electrical circuits.

 The result of temperature measurement can be directly entered into the computer without analog-to-digital conversion.

 The use of this digital spectrometer pyrometer can improve the accuracy of measuring the temperature of products manufactured in a heated state, and therefore, improve the quality of products. In addition, the pyrometer has a simple and reliable design and structure, which allows it to be manufactured in a portable compact version, and this, in turn, expands the scope of its use.

Thus, the foregoing indicates that when using the claimed invention the following combination:
a digital spectrometer pyrometer embodying the claimed invention in its implementation, is intended for use in high temperature processes;
for the claimed invention in the form described in the claims, the possibility of its implementation in accordance with the description and the attached drawings is confirmed;
a digital pyrometer embodying the claimed invention in its implementation is capable of achieving the achievement of the technical result perceived by the applicant.

 Therefore, the claimed invention meets the requirement of "industrial applicability".

Claims (1)

1 A digital spectral-ratio pyrometer containing an optically coupled lens, two light filters and a photodetector, the photodetector mounted on a vibration scanner and connected to a photocurrent amplifier, which is connected to an automatic gain control unit including a first Schmitt trigger, the input of which is connected to the output of the photocurrent amplifier, a one-shot connected to a Schmitt trigger, a generator of periodic signals of a special form, made in the form of a four-strip with RC elements, the first switch and the next well-connected current pulse generator, a second switch and a pulse counter, characterized in that the pyrometer further comprises a subtraction unit, a second Schmitt trigger, an inverter and a two-input logic element And, the first input of the subtraction block connected to the output of the first Schmitt trigger, the second input connected to the output a single vibrator, and the output of the subtraction unit is connected to the control input of the first switch connecting the output of the photocurrent amplifier with a signal generator of a special form, the output of which is connected to the input th second Schmitt trigger, the first input of the two-input AND gate connected to the output of the first Schmitt trigger, the output of the second Schmitt trigger is connected via an inverter to the second input of the two-input AND gate, and the output of AND gate is connected to the control input of the second switch.

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