RU148307U1 - DEVICE FOR DETERMINING ORGANIC CARBON IN WATER - Google Patents

Abstract

1. A device for determining organic carbon in water, comprising a carrier gas supply unit and a hydrometer located on the gas main, an ascarite cartridge, a photochemical unit in which two mercury-quartz lamps are installed with a photochemical cell placed between them, at the output of which there is a return a refrigerator to which a cartridge with an anhydron and a measuring unit with an analyzer located in it are connected in series, characterized in that in the measuring unit we use a controlled A computer-controlled Fourier-transform IR spectrometer, in the working area of which there is a gas cuvette connected to the atmosphere and hermetically connected to the detector and the spectrometer lens, to which a purge unit is connected, including a micro-compressor, a cartridge with a desiccant and a cartridge with ascarite, sequentially located on the additional gas line and the spectrometer interferometer is filled with nitrogen. 2. The device according to claim 1, characterized in that the carrier gas supply unit installed at the inlet of the gas main contains a peristaltic pump and a pressure stabilizer. 3. The device according to claim 1, characterized in that on the gas line between the hydrometer and the cartridge with ascarite an additional cartridge with a desiccant is installed.

Description

The utility model relates to the field of ecology and analytical chemistry, in particular to devices for determining organic carbon in environmental objects and is intended to control the quality of drinking and natural water, as well as to assess the degree of pollution of wastewater.

A device is known for determining the total organic matter content in water, including a series of inert gas supply unit, a unit for supplying oxygen to the gas stream, made in the form of a solid electrolyte metering cell with a stabilized power source, a unit for supplying a liquid sample, a chamber for introducing and burning a liquid sample with a hole for introducing a liquid sample into a cuvette located in a coaxial furnace, a measuring solid electrolyte cell with oxygen-ion conductivity, refurbished in a coaxial furnace, a control unit, stabilization and measurement of the flow rate of the gas mixture, an electronic control unit and a unit for recording the results of determination (RF Patent No. 2053507, MKP G01N 27/417, published 01/27/1996).

A disadvantage of the known device is the design complexity due to the presence in the furnace of a measuring solid electrolyte cell and insufficient accuracy of the analysis.

A device for determining the total organic carbon in water, containing a feeding device for a water sample, a heating vessel (furnace), a source of transporting gas, a detector at the outlet of the heating vessel and a flow line connecting the inlet of the heating vessel to a source of transporting gas to which the device is connected a sample of water, while one or more gas cylinders with calibration gas of various concentrations are integrated into the flow line of the transporting gas (RF Patent No. 2347221, MCP G01N 33/18, published January 27, 2008).

A disadvantage of the known device is the complexity of the hardware, due to the need to use cylinders with calibration gas.

A device for the photochemical determination of inorganic and organic carbon is known, which consists of a cuvette with a coaxially located radiation source (mercury-quartz lamp), a needle-pierced sample inlet, ending with a guide pipe that is connected to the inlet of the carrier gas. The cuvette is connected through a reflux condenser to a measuring cell and a recording device. The guide pipe has a length less than the length of the needle of the syringe dispenser and is installed with a gap relative to the bottom of the cuvette (Copyright certificate No. 1170322, MKI G01N 21/11, published July 30, 1985).

The disadvantage is the high background noise created by the accumulation of carbon dioxide in the confined space of the device, which limits the sensitivity of the measurements, impairs the reproducibility of the results. In addition, when the device is operated with a closed gas flow, glass parts, in particular, a photochemical cell, often break, which is unsafe and requires mass production of them from expensive optical quartz.

The closest set of features adopted for the prototype is a device for determining organic carbon in water with a continuous gas stream passing through the analyzer. The device comprises a carrier gas supply unit with a microcompressor located on it at the gas line outlet and a hydrometer located on the gas line, an ascarite cartridge, a glass filter to remove mechanical particles, a photochemical unit in which two mercury-quartz lamps are installed with a photochemical cell for a water sample with a sensitizer, which was used as a mixture of equal volumes of a 1 molar solution of sulfuric acid and a 3% solution of mercury chloride. At the output of the photochemical cell, a reflux condenser is installed, to which a cartridge with an anhydron (Mg (ClO ₄ ) ₂ ) and a measuring unit are connected in series. The measuring unit consists of an optical-acoustic analyzer, recorder and integrator connected in series by signal cables (Martynova N.N., Lozovik P.A., Glinsky AM Determination of organic carbon in natural waters using a continuous gas flow system // Organic matter and biogenic elements in the waters of Karelia (Petrozavodsk, 1985, p. 191-203).

The disadvantage of the prototype is a narrow range of measurements of the concentration of organic carbon, due to the inability to measure high concentrations of carbon dioxide by an optical-acoustic analyzer and insufficient measurement accuracy. In addition, the service life of the optical acoustic analyzer in the device is quite small and is limited to a period of 1-3 years, which is caused by the influx of residual water vapor from the photochemical cell and subsequent corrosion of the optical components, which cannot be replaced.

The task to which the utility model is directed is the development of an automated, easy-to-manufacture device that makes it possible to effectively use it to determine the content of organic carbon in natural, drinking, and wastewater.

The technical result of the utility model is to expand the measurement range of the concentration of organic carbon, increase the accuracy of the analysis and increase the service life of the device.

This goal is achieved by the fact that in the known device for determining organic carbon in water, comprising a carrier gas supply unit and a hydrometer located on the gas main, an ascarite cartridge, a photochemical unit in which two mercury-quartz lamps with a photochemical cell located between them are installed at the output of which a reflux condenser is installed, to which a cartridge with an anhydron and a measuring unit with an analyzer located in it are connected in series, according to a utility model, in the measuring the unit used as an analyzer is a computer-controlled dispersion IR-Fourier spectrometer, in the working area of which there is a gas cuvette connected to the atmosphere and hermetically connected to the detector and lens, to which a purge unit is connected, including a microcompressor, a cartridge with a desiccant and a cartridge with ascarite, in series located on an additional gas line, and the spectrometer interferometer is filled with nitrogen. In addition, the carrier gas supply unit, installed at the inlet of the gas main, contains a pressure-sensitive pump and a stabilizer. On the gas line between the hydrometer and the cartridge with ascarite, a cartridge with a dehumidifier is additionally installed.

In FIG. presents a block diagram of a device for determining organic carbon in water.

A device for determining organic carbon in water contains a carrier gas supply unit 1, which includes a fixed-pressure pump 2 and a pressure stabilizer 3, as well as a hydrometer 5 located on the gas line 4, a cartridge with a desiccant 6, a cartridge with ascarite 7, a photochemical block 8, in which two mercury-quartz lamps 9 are installed with a photochemical cell located between them 10. At the output of the photochemical cell, a reflux condenser 11 is installed, to which a cartridge with anhydron 12 and a measuring unit 13 are connected in series. The analyzer is located in the unit 13, which is a computer-controlled dispersion IR-Fourier spectrometer 14, which has a gas cuvette 15 in communication with the atmosphere and hermetically connected to the detector 16 and lens 17, to the detector and a purge unit 18, including a microcompressor 19, a cartridge with a desiccant 20, and a cartridge with ascarite 21, sequentially located on the additional gas line 22, is connected to the lens of the spectrometer 14, interferometer 23 of the spectrometer 14 fill not nitrogen. The device operates as follows.

Preparation of the device for operation is carried out before each series of measurements by first turning on the IR-Fourier spectrometer 14, the static pump 2 and the microcompressor 19 to displace atmospheric moisture and carbon dioxide from the lens 17 and the detector 16 of the spectrometer 14 and the gas line 4.

The preparation of the photochemical cell is carried out before each measurement and consists in the fact that 0.3 g of crystalline ammonium persulfate, 0.75 ml of a 1 molar solution of H ₃ PO ₄ and 15 ml of an aqueous sample are placed in the photochemical cell 10. The photochemical cell 10 with the reflux condenser 11 is assembled and installed in the photochemical block 8.

The fixed-pressure pump 2 delivers a carrier gas, which is atmospheric air, to the gas line 4 through a pressure stabilizer 3, which smooths out fluctuations in the carrier gas flow at the pump outlet. Next, the carrier gas enters the preparation system, consisting of a cartridge-desiccant (CaCl ₂ ) 6 and a cartridge with ascari-7, where it is cleaned of water vapor and carbon dioxide, respectively. The carrier gas stream passing through the photochemical cell 10, in which a water sample with an oxidizing agent, ammonium persulfate, is placed, must remain constant throughout the entire measurement process. Its flow rate is controlled using a hydrometer 5, by the pressure drop of the carrier gas when passing through a calibrated tube. The purge of the water sample continues until the signal recorded by the measuring unit 13 stops changing, which will correspond to the moment of inorganic carbon exit from the water sample. Next, using the measuring unit 13, the background value is recorded, which corresponds to the residual carbon dioxide content in the carrier gas.

The next step is the inclusion of UV lamps 9 in the photochemical unit 8, with the help of which the decomposition of organic matter in a water sample is carried out with the release of carbon dioxide. Carbon dioxide released during the decomposition of organic matter enters the reflux condenser 11, where water vapor is separated from the main carrier gas stream. Condensed water flows back to the photochemical cell 10, and carbon dioxide is carried away by the carrier gas stream and passes through the gas line 4 to the anhydron cartridge (Mg (ClO ₄ ) ₂ ) 12, where it is dehydrated and then the gas cell 15 of the measuring unit 13 is supplied. block 13 is the registration of the absorption coefficient of infrared radiation of carbon dioxide in the gas cuvette 15, relative to the background value measured previously. Measurements are taken at regular intervals. The absorption coefficient is integrated over the measurement time and is a characteristic that is directly proportional to the volume of carbon dioxide released during the decomposition of organic matter.

The concentration of organic carbon in the water sample is determined by calculation according to the calibration graph, which reflects the dependence of the integral absorption coefficient on the concentration of organic carbon in pre-prepared standard samples with a priori known concentration. To construct a calibration curve, standard samples are loaded into the photochemical cell 10 instead of a water sample.

Tests of the device were carried out on water samples from 4 different types of lakes of Karelia, taken in different seasons of the year. A total of 76 water samples were analyzed. In the analysis, two successive determinations of _Corg for each of them were carried out, which allowed us to carry out statistical processing of the results and estimate the measurement error. As a result, it was determined that in the studied samples the concentration of _Corg was in the range from 5.5 to 21.0 mgS / L, and the standard deviation in this range was 0.13 mgS / L. In addition, experiments were conducted with standard solutions of citric acid with a concentration of from 0.05 to 100 mgS / L, which showed that the detection limit is 0.1 mgS / L, and at a concentration of 10 mgS / L, the device detector does not roll over. Calibration was carried out on the basis of citric acid standards corresponding to the following concentrations of _Corg : 2, 4, 6, 8, 10, 15, 20, 25 mgS / L. In this case, two measurements were carried out for each of the concentrations. The correlation coefficient was equal to R ² = 0.9991. The table shows the characteristics of the proposed device and prototype.

Table. Indicator Prototype Proposed solution Range of measurements, mgS / l 0.1-20 0.1-100 Measurement error (standard deviation), mgS / l 0.18 0.13 Service life, years 1-3 10

From the table it follows that the use of the proposed device in comparison with the prototype allows you to expand the measurement range of the concentration of organic carbon, increase the accuracy of the analysis, as evidenced by a decrease in measurement error, and also increase the service life of the device through the use of interchangeable optical components in a gas cell.

Claims (3)

1. A device for determining organic carbon in water, comprising a carrier gas supply unit and a hydrometer located on the gas main, an ascarite cartridge, a photochemical unit in which two mercury-quartz lamps are installed with a photochemical cell placed between them, at the output of which there is a return a refrigerator to which a cartridge with an anhydron and a measuring unit with an analyzer located in it are connected in series, characterized in that in the measuring unit we use a controlled a computer-controlled Fourier-transform IR spectrometer, in the working area of which there is a gas cuvette connected to the atmosphere and hermetically connected to the detector and the lens of the spectrometer, to which a purge unit is connected, including a microcompressor, a cartridge with a desiccant and a cartridge with ascarite, sequentially located on the additional gas line and the spectrometer interferometer is filled with nitrogen. 2. The device according to claim 1, characterized in that the carrier gas supply unit installed at the inlet of the gas main contains a peristaltic pump and a pressure stabilizer. 3. The device according to p. 1, characterized in that on the gas line between the hydrometer and the cartridge with ascarite an additional cartridge with a desiccant is installed.

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