SU1167482A1 - Gas analyser - Google Patents

Abstract

A GAS ANALYZER, consisting of an optically coupled radiation source, a spherical mirror, a two-frequency modulator, a working and reference cell, a focusing system and a radiation receiver, electrically connected to an electronic recording system containing a preamplifier, a synchronous detector and a recorder different by the fact that, in order to increase the measurement accuracy and reliability of operation, due to the exclusion of mechanical components from the electron-recording part, and from the optical path - the mechanical shutter, The electron-recording part additionally contains synchronous filters, amplifiers, a second synchronous detector, transmittance meters for the amplifiers of the working and reference channels, comparing and subtracting devices, with the output of the preamplifier connected to the synchronous inputs of the working and reference channels, the outputs of which through the amplifiers are connected to the inputs the corresponding synchronous detectors of the working and reference channels, and the outputs of the synchronous detectors are connected to the inputs of a comparison ( The output of which is connected to the control input of the working channel amplifier, the inputs and outputs of the working and reference channels amplifiers are connected respectively to the inputs of the transmittance meters of the working and reference channels amplifiers, and their outputs to the inputs of the detracting device whose output is connected to the recorder.

Description

The invention relates to analytical instrumentation and can be used to control the emission of industrial enterprises and vehicles into the atmosphere, as well as to control technological processes associated with the emission of gases.

The purpose of the invention is to increase the accuracy of measurements and the reliability of the gas analyzer due to the exclusion from the electronic recording part of the mechanical components, and from the optical path - mechanical damper.

The drawing shows a structural diagram of a gas analyzer.

The gas analyzer contains a radiation source 1, a spherical mirror 2, a dual-frequency modulator 3, a working 4 and a reference 5 cuvette, a focusing system 6, a radiation receiver 7, a preliminary amplifier 8, synchronous filters 9 and 10 of the working and reference channels, respectively, amplifiers 11 and 12 of the working and reference channels, respectively, meter 13 of the gain of the amplifier 11 and meter 14 of the gain of the amplifier 12, synchronous detectors 15 and 16 of the working and reference channels, respectively, the comparator 17, the subtractor 18 and recorder 19.

The gas analyzer operates as follows.

The radiation from the radiation source 1, located at the focus of the spherical mirror 2, is divided into two parallel light fluxes, modulated by a two-frequency modulator 3, passes through the working 4 and reference 5 cells, and is focused by the focusing system 6 on the receiving area of the radiation receiver 7.

The radiation receiver 7 converts the light flux supplied to its receiving area into an electric signal, which is the sum of two signals of different frequencies, which, after amplification in the pre-amplifier 8, is fed to the inputs of synchronous filters 9 and 10, which are synchronously and in phase with the modulation frequencies of the light fluxes, passed through working 4 and supporting 5 ditches. Electrical signals from the output of synchronous filters' 9 and 10, whose amplitudes are proportional

7482 2 are typical of radiation intensities,? passed through the working 4 and reference 5 cells, are fed to the inputs of amplifiers 11 and 12 of the working and reference channels and, after amplification, are fed to the inputs of synchronous detectors 15 and 16. From the output of synchronous detectors 15 and 16, constant voltages whose levels are proportional to the intensity of the radiation transmitted through the working 4 and reference 5 cuvettes, respectively, they go to the inputs of the comparative device 17. In the absence of the test gas in the working cuvette 4, the intensities of radiation passing through the working 4 and horn 5 cuvettes are equal, and if ffitsientov transmission amplifiers 11 and 12 working and reference channels has constant voltage output from the synchronous detectors 15 and GB applied to the inputs of comparator 17 are also equal. At the same time, at the output of the comparison device

17, the error signal is zero, and the gain of the amplifier 11 of the working channel is not changed. Thus at the output of the meters 13 and 14 there are equal in level voltage applied to the - inputs of the subtracting device 18, and its output voltage is zero, which is recorded by the recorder 19.

When the test gas appears in the working cell, the intensity of the radiation passing through it becomes lower than the intensity of the radiation passing through the reference 5 cell, which leads to a decrease in the ⁴⁰ level of constant voltage at the output of the synchronous detector 15 of the working channel. At the same time, a mismatch signal appears at the output of the comparator 17, increasing the transmission coefficient of the working channel amplifier 11 so that the DC voltage levels at the output of the comparator 17 become equal. The increase in the gain of the amplifier 11 leads to an increase in the signal level at the output of the meter 13, which causes the appearance at the output of the subtractor 18 of an electric signal proportional to the concentration of the test gas in the working cell 4, the value of which is recorded by the recorder 19.

Claims (1)

GAS ANALYZER, consisting of an optically coupled radiation source, a spherical mirror, a two-frequency working and supporting biting system of a modulator, a cuvette, * a foyer of a radiation receiver electrically connected to an electron-recording system containing a pre-amplifier, a synchronous detector and a registrar, characterized in that, in order to improve the accuracy of measurements and reliability due to the exclusion from the electronic recording part of the mechanical components, and from the optical path - mechanical damper, electronic the onon-recording part additionally contains synchronous filters, amplifiers, a second synchronous detector, transmittance coefficients of the amplifiers of the working and reference channels, comparing and subtracting devices, and the output of the preliminary amplifier is connected to the inputs of the synchronous filters of the working and reference channels, the outputs of which through the amplifiers are connected to the inputs corresponding synchronous detectors of the working and reference channels, and the outputs of synchronous detectors are connected to the inputs of the comparison device, the output of which th is connected to a control input of the working amplifier, the inputs and outputs of amplifiers working and reference channels respectively connected to the inputs of gauges coefficients transmission amplifiers working and reference channels, and their outputs to the inputs of a subtractor whose output is connected to the logger. ZSHW'TiS · '’ -ABOUT 1 11 (