RU132548U1 - FIRE PHOTOMETER - Google Patents

Abstract

1. Flame photometer, including a burner with a device for injecting a solution of the test substance and an air and gas supply system, while the burner is connected in series with an optical system for transmitting the light flux by a dispersing element, a photodetector, a processing unit and recording the measurement results, characterized in that the dispersing element made in the form of an acousto-optic monochromator associated with a high-frequency driver, while the acousto-optic monochromator contains an acousto-optical cell with a zoelectric radiator enclosed between two crossed polarizers and made in the form of a ultrasonic-sensitive uniaxial crystal, and the high-frequency driver contains a frequency synthesizer and an ultrasound power amplifier, while the output of the processing unit and recording the measurement results is connected to the input of the high-frequency driver. 2. The flame photometer according to claim 1, characterized in that the acousto-optic monochromator contains from one to two acousto-optic cells. The flame photometer according to claim 1, characterized in that the spectral range of the acousto-optical monochromator is in the range from 0.380 to 0.850 μm. The flame photometer according to claim 1, characterized in that the transmission band of the radiation of the acousto-optic monochromator is not more than 0.25 nm at a wavelength of λ = 532 nm. The flame photometer according to claim 1, characterized in that the attenuation of the radiation of the acousto-optic monochromator outside the passband is not less than 10,000 times. The flame photometer according to claim 1, characterized in that the maximum number of points in the spectrum of an acousto-optic monochromator is

Description

The utility model relates to the field of applied optics and photometry for chemical analysis and determination of the concentration of various substances in solutions and can be used in water supply and wastewater treatment plants, as well as in laboratories of medical institutions, at nuclear power plants, in agriculture, in chemical, metallurgy and other sectors of the economy.

The known flame automatic photometer FPA-2, designed to measure the concentration of chemical elements in solutions by photometric flame measurements, into which the analyzed solution is sprayed [FPA-2, 1990, Zagorsk Optical-Mechanical Plant, TU 3-3.22-5-30 ]. The fiery photometer consists of a burner, a solution atomizer connected to an air and gas supply system (propane-butane). The burner is connected in series with an optical system for transmitting light flux, a dispersing element, a photodetector and a unit for processing and recording measurement results.

However, the known flame photometer is characterized by a limited number of measured elements, a sensitivity that does not meet the requirements for modern measuring instruments of this type, and the inability to scan the flame in a wide range of the spectrum.

The objective of the utility model is to develop the design of a flame photometer with improved technical and operational characteristics.

The technical result of the invention is to increase the accuracy of measurement and to enable measurement of the concentration of an unlimited number of elements in solution.

The task and the specified technical result are achieved by the fact that the flame photometer includes a burner equipped with a device for injecting a solution of the test substance and an air and gas supply system, while the burner is connected in series with an optical system for transmitting a light flux, a dispersing element, a photodetector and a processing and recording unit the results of measuring the concentration of substances in solution. According to a utility model, the dispersing element is made in the form of an acousto-optic monochromator associated with a high-frequency driver, while the acousto-optic monochromator contains an acousto-optic cell with an attached piezoelectric emitter, enclosed between two crossed polarizers and made in the form of a ultrasound-sensitive uniaxial crystal, while the high-frequency driver contains frequency synthesizer and ultrasonic power amplifier, and the output of the processing and recording unit The measurement results are connected to the input of the high-frequency driver.

In addition, an acousto-optic monochromator contains from one to two acousto-optic cells. As a uniaxial crystal of an acousto-optic cell, for example, a paratellurite crystal sensitive to ultrasonic influences can be used. The spectral range of an acousto-optic monochromator should be in the range of 0.380 to 0.850 μm. The passband of radiation of an acousto-optic monochromator should be no more than 0.25 nm at a wavelength of λ = 532 nm. The attenuation of the radiation of the acousto-optic monochromator outside the passband should be ensured by no less than 10,000 times, and the maximum number of points in the spectrum of the acousto-optic monochromator should be 2000 units.

The use of an acousto-optic monochromator associated with a high-frequency driver as a dispersing element makes it possible to increase the measurement accuracy and provide the possibility of measuring the concentration of unlimited

the number of elements in the solution, the emission lines of which are in the visible region of the spectrum, as well as reduce the mutual influence of chemical elements included in the composition of the test solution. Moreover, this embodiment of the dispersing element provides a spectral range when determining the concentration in the range of 0.380-0.850 μm, the radiation transmission band is not more than 0.25 nm at a wavelength of λ = 532 nm, the attenuation of radiation outside the transmission band is not less than 10,000 times, and also the maximum number of points in the spectrum is 2000 units.

In a flame photometer, the radiation filtering is provided by an acousto-optic cell enclosed between two polarizers and sensitive to ultrasonic influences. An ultrasound is generated by a piezoelectric emitter attached to an acousto-optic cell and periodically excited by a high-frequency acousto-optic monochromator driver. Propagating in a crystal, ultrasonic waves of adjustable frequency create periodic elastic stresses and, accordingly, mechanical deformations. The compression and rarefaction regions thus obtained, characterized by different densities and, as a consequence, refractive indices, form a phase diffraction grating. That component of the light beam incident on the acousto-optical cell, which has a wavelength that satisfies the Bragg diffraction condition, as a result of diffraction changes its direction of propagation and polarization. Only the diffracted component of the light beam with a polarization direction perpendicular to the direction of polarization of the light beam incident on the acousto-optic cell passes through the acousto-optic cell, which acts as a spectral filter.

The obtained diffraction grating emits radiation lying in a narrow spectral range from the broadband light flux, the interval of which is determined by the period of the grating.

Changing the frequency of the ultrasonic wave leads to a shift in the passband of the filter.

The frequency synthesizer of the high-frequency driver performs the function of frequency modulation of the ultrasonic wave. The high-frequency driver, in particular, the frequency or wavelength λ, as well as the required level of ultrasound output power, is controlled by a small-sized measuring and computing system. When setting the linear frequency modulation mode in the acousto-optic monochromator, linear tuning will be performed according to the wavelength λ.

In a flame photometer, narrow-band scanning is performed in that wavelength range, which includes the analytical radiation line of the chemical element under study. The process of measuring the concentration of several substances in a solution is carried out by narrow-band scanning in the range containing a group of emission lines.

The digitized signal from the photodetector located at the output of the acousto-optic monochromator allows reproducing the amplitude profile of the linear scanning of the optical signal along the wavelength. Since the analytical line of radiation of the chemical element under study also enters the boundaries of the scanning range, the envelope of the output signal received from the photodetector will display the convolution of the radiation line of the element under study with the image of a standard solution of this element. In the process of calibrating the inventive flame photometer using standard standard solutions of the analyzed chemical elements, copies of the model output signals for analytical emission lines of various chemical elements are recorded in the memory of a small measuring and computing system.

Schematic diagram of a fiery photometer is shown in the drawing.

The flame photometer contains a burner 1 in the form of a flame maintenance system associated with the injection system 2 of the test substance solution. The burner 1 is connected with an acousto-optic spectral system 3, which contains an optical system 4 for transmitting the light flux, an acousto-optic monochromator 5, which includes an acousto-optic cell 7 enclosed between the input 6 and output 9 polarizers with a piezoelectric ultrasonic emitter 8 attached to it. The ultrasound emitter 8 is connected to a high-frequency driver 10, comprising a frequency synthesizer 11 and an ultrasound power amplifier 12. The acousto-optic monochromator 5, in turn, is also connected in series with the photodetector 13 and the control unit 14 of the small measuring and computing system, which performs the functions of controlling the high-frequency driver 10 of the acousto-optic monochromator 5, as well as processing, transmission and display of measurement and related information.

The fiery photometer works as follows. The solution of the studied chemical element, passing through the injection system 2, is introduced into the flame of burner 1 in the form of an aerosol. Under the action of the thermal energy of the flame on the aerosol, the radiation of the spectral composition that is characteristic of this element is generated. Next, the light flux from the flame of the burner 1 with a radiation spectrum characteristic of the chemical element under study passes through an acousto-optical spectral system 3, at the input of which there is an optical system 4 for transmitting the light flux. In this case, the dispersing element of the system is an acousto-optic monochromator 5, controlled by a high-frequency driver 10, passes only the analytical emission line. The resulting radiation is received by the photodetector 13 and converted into an electrical signal, which is amplified and fed to the input of block 14 of a small measuring and computing system to determine the intensity of the analytical line and display it on the indicator in units of the concentration of the studied solution of a chemical element.

In the process of determining the concentration of substances using the proposed flame meter, the spectral line amplitudes and the concentration of the measured substances are determined by analyzing the data obtained by digitizing the output signal in the narrow-band scanning mode and comparing them with previously recorded spectral line images. For this, the operation of convolution of copies of the exemplary output signal A (λ) and the measured signal with a variable shift B (λ-γ) is used, as a result of which the function values are calculated:

,

,

Where:

λ is the wavelength;

γ is the variable wavelength shift;

A (λ) is the amplitude of the output signal of the sample;

Β (λ-γ) is the amplitude of the output signal of the measured substance,

which is a convolution of the model and measured signals.

In digital signal processing, the sum of the products of copies of the model and measured signals is calculated. If the reference signal Α (λ) is measured with a step of δ, and the measured signal B (λ) with a step of n * δ, then we can convolution with a step of n * δ, multiplying each point in the signal Β (λ) by the points of sample A ( λ) taken in increments of n * δ. This solution provides a significant effect, expressed in reducing the duration of the measurement process by changing the scanning step, a multiple of the measurement step of the reference signal.

At the same time, this solution does not require maintaining the exact correspondence of the scale of the specified wavelengths. The wavelength of the investigated radiation can vary with the temperature of the acousto-optic monochromator. However, such a change will not affect the results of measuring the concentration of the substance, since when processing the data, the position of the radiation maximum and, accordingly, the amplitude of the radiation line will be exactly found. The concentration of the test substance is directly proportional to the amplitude of the analytical emission line and is calculated taking into account the results obtained during calibration.

The result of the implementation of the claimed technical solution is the design of a flame photometer with a lower sensitivity threshold, reduced by 10-15 times, higher measurement accuracy, increased by 20%, the absence of restrictions on the chemical composition of the test solution, and reduced interaction of chemical elements included in the composition test solution, and a shorter measurement process, reduced by 20%.

The proposed technical solution is implemented in manufactured instruments using the flame photometry method. Their technical characteristics fully satisfy the functional requirements and purpose of the fiery photometer.

Claims (6)

1. Flame photometer, including a burner with a device for injecting a solution of the test substance and an air and gas supply system, while the burner is connected in series with an optical system for transmitting the light flux by a dispersing element, a photodetector, a processing unit and recording the measurement results, characterized in that the dispersing element made in the form of an acousto-optic monochromator associated with a high-frequency driver, while the acousto-optic monochromator contains an acousto-optical cell with a zoelectric radiator enclosed between two crossed polarizers and made in the form of a ultrasonic-sensitive uniaxial crystal, and the high-frequency driver contains a frequency synthesizer and an ultrasound power amplifier, while the output of the processing unit and recording the measurement results is connected to the input of the high-frequency driver. 2. The flame photometer according to claim 1, characterized in that the acousto-optic monochromator contains from one to two acousto-optic cells. 3. The flame photometer according to claim 1, characterized in that the spectral range of the acousto-optic monochromator is in the range from 0.380 to 0.850 μm. 4. The flame photometer according to claim 1, characterized in that the transmission band of the radiation of the acousto-optic monochromator is not more than 0.25 nm at a wavelength of λ = 532 nm. 5. The flame photometer according to claim 1, characterized in that the attenuation of the radiation of the acousto-optic monochromator outside the passband is not less than 10,000 times. 6. The flame photometer according to claim 1, characterized in that the maximum number of points in the spectrum of an acousto-optic monochromator is 2000 units.

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