RU2044303C1 - Gas analyzer - Google Patents

Abstract

FIELD: instrumentation. SUBSTANCE: gas analyzer has source 1 of light radiation, capacitor 2, dish 3 for gas mixture, modulator 4 with light filters of working 5 (within region of maximum absorption of radiation by analyzed component of gas mixture) and reference 6 in absence of absorption) channels, focusing lens 7, radiation detector 8 with preamplifier installed in succession as well as first 9 and second 10 units for retrieval and storage, former 11 of synchronization pulses, sensor 12 of position of light filters, source 13 of reference voltage, former 14 of thermal compensation signal, adder 16, information processing unit 16 and indicator 17. EFFECT: enhanced operational efficiency and reliability. 1 dwg

Description

 The invention relates to optical instrumentation and can be used to create devices for analyzing the composition of substances using photodetectors with a temperature dependence of their sensitivity.

Known single-beam two-channel gas analyzer containing optically coupled radiation source, a modulator on which the filters of the working and reference channels are installed, a cuvette with the analyzed gas mixture and a radiation receiver, the output of which is connected to an electrical signal converter, at the input of which there is a recording device that displays the measurement results in concentration units [1]
A disadvantage of the known gas analyzer is the low stability of the readings when the ambient temperature changes in the case of using a semiconductor radiation detector.

Known single-beam multichannel gas analyzer containing optically coupled radiation source, a modulator on which are installed the filters of the working and reference channels, the volume with the analyte, a radiation receiver installed in a thermostat with a controlled power supply, an alternating signal amplifier and a multi-channel processing system connected in series with the radiation receiver information connected to the position sensor of the modulator, in which, in order to increase the temperature stability of the readings, stabilization of the temperature of the radiation receiver by the value of the signal of the reference channel [2]
A disadvantage of the known analyzer is that when using selective radiation detectors, for example, photoresistors based on lead selenide films, there are differences in the temperature dependence of the photosensitivity at different wavelengths, for example, at a wavelength of the reference channel 3.9 μm used in automobile exhaust gas analyzers engines, and at a wavelength of 4.6 μm, which coincides with the absorption band of carbon monoxide molecules, leading to a significant effect on the readings of changes in the ambient temperature kg Ambient.

 The aim of the invention is to increase the temperature stability of the readings of the gas analyzer by eliminating the influence on the readings of the differences in the course of the temperature dependences of the photosensitivity of the radiation detector at different wavelengths.

 This is achieved by the fact that in a gas analyzer containing a light radiation source, a condenser, a cuvette for the gas mixture, a modulator with a light filter passing the working wavelength at which the maximum absorption of light radiation by the analyzed component of the gas mixture is carried out, and a light filter, passing the reference wavelength at which the light radiation passes without absorption by the gas mixture, sequentially mounted on the same optical axis, focusing a lens and a radiation receiver with a preliminary amplifier, the output of which is connected to the information inputs of the amplifiers of the reference and working channels, the control inputs of which are connected to the output of the synchronization pulse shaper, the input of which is connected to the optical filter position sensor relative to the optical axis, the output of the reference channel amplifier is connected to the reference input of the block processing of information, the output of which is connected to an indicator of the concentration of the analyzed component of the gas mixture, a source of reference voltage is introduced thermocompensation signal generator and adder, wherein the output of the reference voltage source is connected to the reference input of the thermocompensation signal generator, whose information input is connected to the output of the reference channel amplifier, and the output to one of the adder inputs, the second input of which is connected to the output of the working channel amplifier, the output the adder is connected to the information input of the information processing unit.

 The drawing shows a gas analyzer with a thermal compensation device.

 The gas analyzer contains a light emission sensor 1, a condenser 2, sequentially mounted on the same optical axis, in the direction of radiation propagation to the cuvette 3 with a multicomponent gas mixture consisting, for example, of hydrocarbons, carbon monoxide and carbon dioxide and other gases. As a source of light radiation, an incandescent lamp, gas discharge lamp, LED or other source can be used. Further along the radiation, a modulator 4 is installed with the filters 5 and 6 fixed to it. The filter 6 transmits the reference wavelength at which the light radiation passes without absorption by the analyzed gas mixture, and the filter 5 passes the working wavelength at which the maximum absorption of the analyzed gas mixture occurs .

 In the described embodiment of the gas analyzer, the filters 5 and 6 are multilayer interference structures made by thermal evaporation in vacuum. A light filter transmits a wavelength of 3.9 μm, and a light filter a wavelength of 4.6 μm, which coincides with the absorption band of carbon monoxide molecules.

 The modulator 4 is a disk that is mounted rotatably (the drive is not shown) to ensure consistent installation of optical filters on the optical axis.

 The gas mixture is fed into the cell 3 from the source (not shown in the drawing), for example, due to natural diffusion or forced circulation.

 Further along the light radiation on the optical axis 1, a lens 7 is installed, focusing the light radiation on the receiving area of the radiation receiver 8 with a pre-amplifier. As a radiation detector, a photoresistor, a photodiode, a bolometer, a pyroelectric or other radiation detector with a built-in or structurally remote pre-amplifier can be used, from the output of which electrical signals are removed, with parameters allowing their further processing.

 In the proposed gas analyzer, a photodetector is used as a radiation receiver 8, which is a film sealed photoconistor based on lead selenide cooled by a thermoelectric refrigerator with an integrated preamplifier.

 The output of the radiation receiver 8 is connected to the information inputs of the first 9 and second 10 sampling-storage devices of the reference and working channels, the control inputs of which are connected to the output of the synchronization pulse shaper 11, the input of which is connected to the sensor 12 of the position of the filters 5 and 6 relative to the optical axis.

 The sensor 12 in the described embodiment is made in the form of an optocoupler pair consisting of an LED and a photodiode (not shown in the drawing), while in the modulator 4 a code track is made in the form of slots located on the periphery of the modulator disk.

 The output of the first reference channel sampling-storage device 9 is connected to the information input of the thermal compensation signal shaper 14, the reference input of which is connected to the output of the reference voltage source 13, and the output of the shaper 14 is connected to the first input of the adder 15, the second input of which is connected to the output of the second sampling device 10 storage of the working channel. The output of the adder 15 is connected to the information input 16 of the information processing unit, the reference input of which is connected to the output of the first sampling-storage device of the amplifier 9 of the reference channel, and the concentration indicator of the analyzed component calibrated in units of concentration is connected to the output of block 16.

 Shaper 11 synchronization pulses is based on logic elements and a pulse counter and synchronizes the operation of all nodes of the information processing circuit in the device.

 The reference voltage source 12 is a precision parametric voltage stabilizer based on a thermally compensated stabilizer, a thermocompensation signal generator 14 is a differential amplifier based on an integrated operational amplifier.

 The adder 15 is assembled according to the traditional adder circuit based on an operational amplifier.

 The information processing unit 16 is assembled based on elements of digital technology and contains a 12-bit analog-to-digital converter (ADC), a functional linearizer based on read-only memory (ROM), devices for outputting information to digital indicators and analog recording devices.

 The concentration indicator of the analyzed component of the gas mixture is a digital display assembled on the basis of LED, liquid crystal or other seven-segment or matrix indicators.

 The proposed gas analyzer operates as follows. A stream of light radiation from source 1 is formed into a parallel beam using a capacitor 2 and is directed along the optical axis to cell 3, through which the gas mixture is pumped and partially absorbed by the analyzed component at the corresponding operating wavelength.

 Modulation of radiation and the selection of the working and reference wavelengths is carried out using a modulator 4 for the sequential installation of filters 5 and 6 on the optical axis.

 Electrical pulse signals corresponding to the light fluxes at the reference and working wavelengths from the radiation receiver are fed to the inputs of the first and second sampling-storage devices 9 and 10 of the reference and working channels. At the same time, when the modulator 4 is rotated in accordance with the passage of its code path through the sensor installation zone 12, a sequence of pulses arrives from it, amplifying and acquiring a given form (amplitude and duration) in the former. The generated synchronization pulses arrive at the control inputs of the first and second sampling-storage devices of the reference and working channels.

 Based on these signals, at the moments of time corresponding to the flat portion of the apex of the pulse signals taken from the output of the radiation receiver, information about the amplitude of the reference and operating signals is recorded in the I – V characteristic of the corresponding channel. At the outputs of the sample-storage devices, constant voltages are set, the levels of which are proportional to the values of the light fluxes at the wavelengths of the reference and working channels.

 From the output of the sample-storage device 9, a constant voltage, the level of which is proportional to the magnitude of the signal amplitude in the reference channel, is fed to the information input of the thermal compensation signal generator 14, to the reference input of which the reference voltage is supplied from the output of the reference voltage source 13.

 The level of the reference voltage is selected so that at room temperature, for example, at a temperature corresponding to the middle of the operating temperature range, within which the gas analyzer is to be operated, the value of the thermal compensation signal at the output of the shaper was zero. A change in the ambient temperature will lead to a change in the photosensitivity of the radiation receiver, which will manifest itself in a change in the magnitude and amplitude of the signals of both the reference and the working channels. The voltage level at the input of the shaper 14 will change and a certain differential signal will appear at its output, the value of which is determined by the magnitude of the change in voltage at the input and the value of the gain of the differential amplifier, on the basis of which the shaper 14 is built. The value of the gain of the differential amplifier is determined when developing a gas analyzer by studying the temperature dependences of the photosensitivity of the radiation receiver at the wavelengths of the reference and working channels.

 In the proposed gas analyzer, the temperature dependences of the photosensitivity of the radiation receiver with a sufficient degree of accuracy could be represented as linear functions. The temperature range of the receiving platform is only a few degrees, since the radiation receiver is thermostatically controlled.

 In the general case, with a wider range of temperature variations in the receiving area of the radiation receiver, the temperature dependence of the photosensitivity of the radiation receiver can be a more complex function. Then, the shaper 14 of the thermal compensation signal is a functional converter assembled according to a more complex scheme.

 The signal of thermal compensation from the output of the shaper 14 is fed to the input of the adder 15, the input of which receives the signal of the working channel, which must be adjusted. From the output of the adder 15, the corrected working signal is fed to the measuring input of the information processing unit 16, at the reference input of which there is a constant voltage proportional to the amplitude of the signal at the output of the radiation receiver at the reference wavelength. In the block, the processing of measurement information is carried out, for example, according to the Lambert-Bouguer law, and a functional transformation is performed to linearize the output signal. From the output of block 16, information on the content of the analyzed component in the gas mixture is supplied with indicator 17, which displays the measurement results in concentration units.

 The invention is implemented in a prototype model of a carbon monoxide analyzer in a test gas mixture. The use of the proposed gas analyzer made it possible to create a portable stable reference gas analyzer with a relative measurement error not exceeding ± 2% in which the use of a serial photodetector based on a highly sensitive film moderately cooled lead selenide photoresistor with a working channel wavelength (for CO 4.6 μm) lies in the region of the long-wavelength edge of sensitivity.

Claims (1)

 A gas analyzer containing a light source, a condenser, a cuvette for a gas mixture, a modulator with a first filter for transmitting a reference wavelength and a second filter for transmitting a working wavelength, a focusing lens and a radiation receiver with a preamplifier, as well as a first one and the second sampling and storage units, a synchronization pulse generator, a filter position sensor, an information processing unit and an analyte gas concentration indicator a component, the output of the radiation receiver being connected to the inputs of the first and second sampling and storage units, the control inputs of which are connected to the output of the synchronization pulse shaper, the input of which is connected to the light filter position sensor, the output of the first sampling and storage unit is connected to the reference filter by the input of the information processing unit the output of which is connected to the concentration indicator of the analyzed gas component, characterized in that, in order to increase accuracy, a reference voltage source is introduced into it , a thermal compensation signal generator and an adder, wherein the output of the reference voltage source is connected to a reference input of the thermal compensation signal generator, the information input of which is connected to the output of the first sampling-storage unit, and the output is with the first input of the adder, the second input of which is connected to the output of the second sampling-storage unit , the output of the adder is connected to the information input of the information processing unit.