SU507808A1 - Device for monitoring parameters of combustion processes - Google Patents

Description

one

The invention relates to means for monitoring the parameters of a combustion process by measuring temperature with optical pyrometers.

The known devices for measuring and controlling temperature ensure the measurement of only instantaneous or average temperatures.

In a number of cases, for example, dl. control: nor by the technological process during the formation of a feedback signal in real time scales: it becomes necessary to determine the current value of the number of flame luminosities exceeding a given one; level

The purpose of the invention is to provide an automatic determination of the current value of the number of exaggerations of flame brightness at a given level over a selected sliding time interval with simultaneous high-frequency fluctuations of brightness at a pressure.

This goal is achieved by the fact that the output of a brightness meter through a converter of the current value of flame brightness into a frequency-modulated pulse signal

connected to the main input of the first sequential register; the outputs of the co-op bits through; The first summation-multiply | YESH converter and the threshold element are connected to the main input of the second sequential register. The outputs of the bits of the latter are connected via a second summing-multiplying converter with an indicator of the current value of the number of flame intensities of a given level. To the shift inputs of the first serial register directly, and the second serial register through the frequency divider is connected to the generator pushing (pulses.

The drawing presents the proposed device.

It contains a luminance meter 1, a frequency converter 2, the first serial register 3, formed by | bits 4, assembled from elements with; two stable STATES, the first sum; peace-multiplying converter 5, the first frequency generator 6 in voltage, 7 forward pulse generator ,

the threshold element 8, the second sequential register 9, surrounded by the bits Yu, also with the help of elements with two stable states, the second summing multiplier converter 11, the second

frequency to voltage converter 12, frequency divider 13, indicator 14 of the current value of the number of flame luminosities exceeding a given level.

The flame brightness meter is connected to the input of frequency converter 2, the output of which is connected to the main input of the first sequential shift register 3, formed by bits 4 using. elements with two stable states. The outputs of the bits of the first serial register 3 are connected to the input of the first summing-multiplying converter 5, the power bus of which is connected via the frequency converter 6 to the output of the advancing pulses generator 7, where the shift inputs of the first, serial register 3 are connected directly.

The output of the first summation of the 610-multiply converter 5 is connected to the input of the threshold element 8, the output of which is connected to the main input of the second sequential shift register 9, formed by bits 1O, also collected from the elements with two stable states.

The outputs of the bits of the second serial register 9 are connected to the input of the second summing-multiplying converter 11, the power bus of which is connected via the second frequency converter 12 to voltage together with the shift inputs of the second serial register 9 to the output of the frequency divider 13, whose input is connected to the generator output 7 promotion pulses.

The output of the second summing-multiplying converter 11 is connected to the TeKyuiero indicator of the value of the amount of flame intensity exceeding a given level.

The device works as follows

The signal from the output of the luminance meter 1 flame voltage is fed to the input of the transducer 2, at the output of which we obtain a frequency-modulated pulse signal corresponding to the current value of the flame brightness. The resulting pulse sequence is fed to the main input of the first sequential register 3. Each pulse of the sequence converts to the excited state the first bit (element with two stable states) of the specified register, and the pulses of the sequence to the shift input of the register from the output generator 7 of the advancing pulses, sequentially transfer the state of the excitation from to the discharge along the register 3

The nominal value of the part (lty of the pulse signal fed to the shift input of register 3 must be higher than the maximum value of the frequency of the signal fed to the main input, register.

Information about the number of register bits in the excited state (which corresponds to the number of low-frequency fluctuations of flame intensity on a sliding interval of a given length) is output in parallel from all outputs of bits 4 using the first summing-multiplying converter; analog signal from which is input to the threshold element 8, which has a threshold of 1J (,

When the input voltage exceeds the threshold element of the threshold value Up, the output will give pulses, the number of which corresponds to the number of flame intensities of a given level, the corresponding threshold threshold threshold element.

For the purpose of continuous automatic determination of the current value of the amount of flame brightness exceeding a given level at a selected sliding time interval while simultaneously suppressing high-frequency brightness fluctuations, a pulse signal from the output of the threshold element is fed to the main input of the second sequential register 9.

In this case, similarly to the above described, each pulse arriving at the main input of the sequential register 9 transfers the first bit of the specified register to the excited state, and the sequence pulses fed to the shift input of the register from the output of the frequency divider 13 sequentially transfer the state of the excitation from bit to bit along register 9.

As in the first serial register, the nominal value of the frequency of the pulse signal fed to the shift input of the second serial register must be higher than the maximum frequency of the signal fed to its main input.

The number of excited bits in the second sequential register at any time corresponds to the number of pulses coming from the output of the threshold element for a certain period of time, which, in turn,

five

corresponds to the number of exceeding the brightness of the flame at the level indicated, corresponding to the triggering of the threshold element, on the selected sliding time interval,

Information on the number of bits of the second register that are in the excited state is displayed in parallel with all the outputs of bit 1O. with the help of the second summing-multiplying converter 12, the analog output signal of which corresponds to the current value of the number of flame excesses of a given level in a sliding interval of a given length.

At the same time, the indicator 14 will mark the current value of the number of exceeding the brightness of the flame of a given level.

with f o r ula invention

A device for monitoring the parameters of the combustion process, comprising a meter P: Flame bones connected to the converter input of the current value of the flame intensity into a frequency modulated pulse signal, successive registers,

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I sum up the ce-ul knife of the pre-sig- nificant generator of the generator impulse r, n-r | tel part, the threshold element and ippik. of the current value of the parameters of the broadcasting airspace pr.rS}, about tl and h and ysheu 9 with sm, NTO, with the aim of automating the determination of the 1-st current value of the quantity of the previous | flame intensity of a given level over a selected sliding time interval while simultaneously suppressing high frequency fluctuations of brightness, the output of a brightness meter through a converter of a current flame brightness value into a frequency modulated pulse signal is connected to the main input-first serial register, the bit outputs of which are over the first summing-multiplying the converter and the threshold element are half the key to the main input of the second post-successive 1-register, the outputs of which are beyond the second sum, 1 ive1ce-multiply ripeo6i5a: v :) the driver is connected to the indnkator-zm of the current value of the amount of flame intensity exceeding a given level, and to the shift inputs of the first sequence-sequence: yy-yy-istrp directly, and the second after-variable; ; M.t.Klyuchen generator promoting imiulg.sotk