RU2413220C1 - Method for environmental monitoring of hazardous production facilities - Google Patents

Abstract

FIELD: ecology.

SUBSTANCE: method includes sampling of natural environment components, analysis of samples, processing of analysis data, performed by results of processing of analysis data, assessment of environmental condition in zone of anthropogenic effect of object, background monitoring of object territory executed before start of construction and intended to assess condition of natural environment prior to object functioning, comparison of monitoring data, produced in process of object functioning, with results of background monitoring, and also with established norms of quality of natural environment in the form of maximum permissible concentrations (MPC), besides, monitoring in process of object functioning is carried out in points (areas) of sampling with maximum possible presence of contaminating substances (CS) in object of monitoring - soil, snow cover, water and bottom deposits, at the same time density of sampling system points is determined by specified probability of CS detection in zone of potential effect of object, is maximum near the object and reduces in direction to borders of its potential effect, and frequency of sampling and analysis of samples in each point of sampling is proportionate to quantity of detected changes of CS concentrations.

EFFECT: improved validity and simplified monitoring.

3 cl, 1 dwg

Description

The invention relates to the field of environmental protection and is intended for use at hazardous production facilities (hereinafter referred to as facilities), including facilities for the destruction of chemical weapons (hereinafter referred to as CCW facilities) and for assessing the impact of these facilities on the environmental situation in the areas of their location (technogenic impact) .

Environmental monitoring carried out at the CWD facilities on the territory of the Russian Federation is aimed at ensuring environmental safety of the process of destruction of chemical weapons in accordance with the federal target program "Destruction of stockpiles of chemical weapons in the Russian Federation", section "Development and implementation of the state system of measures for environmental protection and environmental safety during storage and destruction of chemical weapons, demilitarization or destruction of facilities for their production. " Environmental monitoring is necessary due to the fact that the destruction of chemical weapons is associated with a certain risk of chemical poisonous substances or their derivatives entering the environment (hereinafter - OS).

A known method of radioecological monitoring of the tritium content in the OS of an industrial enterprise (RF patent No. 2223517 from 2002.01.24). In the method, sampling of surface and underground waters, snow cover, soils in the strict regime zone (in the enterprise zone), the sanitary protection zone and the observation zone are carried out. Then, control samples of soil and water are sampled from areas located outside the zone of influence of this enterprise and not subject to tritium contamination from other enterprises, sample preparation, analysis of samples for tritium content and processing of analysis data are carried out, and then the results of data obtained on the territory of the enterprise are compared , with the results of the analysis of control samples from sites located outside the zone of its influence and not subject to tritium contamination from other enterprises. If areas with a high tritium content in surface, ground and underground waters and snow cover are found in the territory of an industrial enterprise, the specific activity of tritium is compared with the level of intervention and their membership in liquid radioactive waste is determined. If areas with a high content of tritium in soil determines its belonging to solid radioactive waste.

The disadvantage of this method is that the analysis is not carried out on all components of the natural environment (hereinafter - PS), therefore it does not allow to obtain reliable information about the effect of emissions on the state of PS as a whole.

There is a method of environmental monitoring of CWD facilities (RF Patent No. 2005133758 dated 2007.05.10), including sampling of the components of substation: surface and groundwater, soil, snow cover, bottom sediments, atmospheric air, analysis of samples, data processing, recording the results in the analytical database assessment of the environmental situation in the zone of storage and destruction of chemical weapons, in the sanitary protection zone (hereinafter - SPZ), in the zone of protective measures (hereinafter - ZZM), carried out prior to construction and the CWD facility, background monitoring of the territory, designed to assess the state of the substation prior to the operation of the facility, comparing the monitoring data obtained during the operation of the facility with the results of background monitoring, as well as with established quality standards for substations (maximum permissible concentrations - MPC), and when exceeding MAC in the air conduct water analysis, when exceeding the MAC in water, analyze the soil, when exceeding the MAC in the soil, analyze the flora and fauna, in case of emergency and I take appropriate action.

This method makes it possible to obtain information about the situation in the areas of destruction of chemical weapons by sampling all components of the substation and comparing the data with background monitoring data. However, this method does not take into account the conditions (patterns) of the distribution of pollutants in the PS, which with a high degree of probability can lead to the case of sampling in places where there is no pollution, which significantly reduces the reliability of the information received and affects the accuracy of the assessment of the environmental situation in the area monitoring.

The objective of the present invention is to increase the reliability of the information obtained by monitoring a hazardous production facility or OS in the area of its technogenic impact by determining, according to the results of modeling, the impact of the facility on the components of the substrates of areas (territories) in which pollutants in the components of the substrates are most likely to be present, which will allow for a more reliable assessment of the operational situation in the area where the hazardous production facility is located (including the CWD facility).

The problem is solved as follows. In the method of environmental monitoring of hazardous production facilities (including CCW facilities), including sampling of PS components (surface and groundwater, soil, snow cover, bottom sediments, atmospheric air), analysis of samples, data processing, recording the results in analytical database, data processing and environmental assessment in the area of technogenic impact of the facility (for the CCW facility - in the industrial zone, SPZ and ZZM), background monitoring is carried out prior to the construction of the facility, designed to assess the condition of the substation before of the functioning of the facility, a comparison of the monitoring data obtained during the operation of the facility with the results of background monitoring, as well as with the established quality standards of the substation, the pollution of the territory of the hazardous production facility and its impact zone (sampling, etc.) is monitored as much as possible the likely presence of pollutants in the components of the subsurface (soil, snow, surface and groundwater, bottom sediments, etc.), determined by the results of the assessment of the impact of the object on the environment, for example, the calculation and the dispersion of pollutants in atmospheric air based on measurements of their concentrations at emission sources or on the industrial site of an object within its SPZ (for example, at the border), taking into account statistical meteorological data averaged over a certain period (monitoring period) (wind direction and speed). The sampling areas based on the results of modeling the dispersion of pollutants are determined by the established minimum concentration of pollutants (for example, at the level of 0.1 from MPC).

The density of points of the sampling system is determined by the given probability P _{N of} detection of pollutants in the zone of potential influence of the object is maximum near the object and decreases towards the boundaries of the zone of its potential influence.

The sampling frequency at each sampling point is calculated as actual statistical information on the results of the sample analysis is accumulated for each i-th point. First, by the formula

where L _i , N _{n, i} and M _{n, i} are, respectively, the number of pollutants controlled at a point, the total number of detection of pollutants in samples and the total number of samples taken is determined by the relative frequency A _{i of the} presence of substances in it, and then by the formulas:

where C ₂ , C ₁ , C ₀ , C and k are coefficients depending on P _N , the probability p _i (P _N ) of the presence of pollutants at the point and the periodicity T _{n, i} (P _N ) of the next sampling in it are calculated. Moreover, if the previous and current values of pollutant concentrations at the point are different, then the numerator in expression (1) increases by one. The frequency of the presence of pollutants at the point remains equal to unity, and the sampling frequency is equal to 1 month. This means that the information efficiency of the point in the overall efficiency of the sampling system corresponds to the given. If the previous and current concentrations of any pollutant are equal to each other or some pollutant is not detected at the point, then the numerator in expression (1) does not change. The overall probability of the presence of pollutants at the point will decrease, while the sampling frequency in it will increase, which corresponds to a decrease in the information efficiency of the point. In this regard, even if, according to the results of processing regular statistics of meteorological parameters, the point again falls into the monitoring area, sampling will not be carried out in it, and the calculated frequency value will decrease by 1, and will decrease in the same way until it becomes equal one.

Points not included in the next sampling session can be replaced by points at which pollutants were detected in previous monitoring sessions and had the highest concentrations in them according to the results of quantitative chemical analysis. The final choice is made taking into account those decisions that are made or will be made based on the processing of current monitoring data. If it turns out that the sampling frequency at all newly defined points will be more than 1, and no substances were detected at any point in the previous session, this may serve as the basis for deciding that sampling in the next monitoring session is not required.

The concentrations of pollutants in the selected samples are determined by the methods of quantitative chemical analysis and toxicity of the samples is estimated using bioassay and bioindication methods.

The combination of methods of chemical analytical research and biomonitoring (bit testing, bioindication) can improve the reliability and information content of monitoring data. Biological studies are carried out on the basis of a set of universal bioassays and bioindicators (selected representative biological objects, usually the simplest microorganisms, microalgae and bacteria), and if ecotoxicity (toxicity of selected samples) is detected, a detailed quantitative chemical analysis is performed to identify pollutants. The analysis of selected samples using certified methods at bioobjects makes it possible to assess the quality of the environment, since only chemical-analytical studies based on sanitary-hygienic criteria do not fully evaluate the effect of pollutants and especially their low concentrations on the biotic component of PS. The latter is especially relevant for monitoring highly toxic toxic substances and their transformation products into PS, scientific data on the effect of which on the biotic component of PS components (for example, on soil microorganisms) are extremely limited.

Sampling of atmospheric air is carried out by the method of flare measurements, taking into account the mode of emission of the object into the atmosphere at points located along the directive direction of the wind during the sampling period. For example, sampling points can be located on circles centered at the location of the source of pollutant emissions (hazardous production facility, CCA facility) with radii of 1, 2, 3, 5 and 10 km, circles are divided into twenty-four sectors, sampling is carried out according to direction from the EAS facility. Samples are also taken in the sector located on the windward side of the object, at least at one point within the SPZ. Sampling of soil and snow cover is carried out in places where pollutant concentrations have been detected according to atmospheric air pollution monitoring data (for example, at a level of 0.5 MPC or more), pollutant concentrations in the samples are determined by quantitative chemical analysis methods and toxicity of the samples is estimated using bioassay methods and bioindication.

The combination of measurements with the model definition of the observation zone and sampling sessions can significantly reduce the amount of analytical work carried out while increasing the reliability of the results of studying the state of the OS. The regulation (order, program) for monitoring is based on a combination of a model analytical approach with measurements of chemical and physical characteristics of pollutant sources on the territory (industrial site) of the facility and subsequent chemical, analytical and biological studies of the levels of pollution of the components of the substation in the facility and in the area of its technological impact . When monitoring PS components in the zone of influence of an object, the monitoring procedure provides for the preliminary determination of the observation zone based on the results of measurements at pollutant sources (or, in the case of emissions analysis) on the territory of the object within the SPZ or at its border, followed by calculation of the dispersion of pollutants and determining the most probable detection zones of pollutants scattered in the OS.

The objects of monitoring are:

on the territory of a hazardous production facility - sources of pollutants (their compliance with established environmental standards) and pollutants in the components of the environment:

- discharges of pollutants in the OS, storm drains;

- groundwater pollution at observation wells;

- general industrial waste in the environment (including waste disposal facilities);

- emissions of pollutants in the environment;

- environmental equipment and treatment systems;

- components of the environment (atmospheric air, soil cover, snow cover).

in the area of technogenic influence of the object - pollutants in the components of the PS:

- atmospheric air;

- soil cover;

- snow cover;

- natural waters (surface and ground);

- bottom sediments (silt sediments).

The structure of the monitoring system includes:

- a laboratory (laboratories) for conducting analytical studies of the compliance of pollutant sources with established environmental standards (monitoring of pollutant sources) and monitoring of PS components in the zone of influence of an object;

- laboratory (s) for biomonitoring and biotesting for quantitative assessment of the toxicity of PS components, as well as waste generated during the operation of the facility;

- mobile test laboratories designed for sampling and, if necessary, operational monitoring of substation components in the zone of influence of the object. If the samples show signs of the presence of controlled pollutants, these samples should be transferred for further analysis to the analytical laboratory;

- an information-analytical system designed to display and analyze information, research and forecast the processes of accumulation and distribution of pollutants in the components of substation, assess the reliability of monitoring results;

- auxiliary systems and monitoring tools (portable and stationary weather stations, information channels and communication tools).

The test laboratory is designed to conduct regular sampling and operational monitoring of substation components. The presence of the test laboratory allows the implementation of a modern two-level monitoring system, in which the primary eco-analytical control is carried out according to the minimum number of characteristic group features (markers), followed by detailed analysis of the sample in conditions of a stationary analytical laboratory equipped with high-precision equipment. This monitoring scheme allows you to significantly improve the performance and efficiency of monitoring. If there are any signs of contaminants in the samples (for example, identification of pollutant markers), these samples should be transferred for further analysis to the analytical laboratory.

The frequency of sampling at emission sources is established at the initial stage of monitoring (based on statistical and background studies). The minimum required periodicity of sampling and measurements is related to the concept of correlation (interconnection) of the results obtained in statistical processing. In the absence of excess of established standards (stable operation of the facility), the frequency of measurements increases or is established based on the requirements of regulatory documents (GOST, SanPiN, MPE, PNOOLR, VAT). The frequency of sampling and analysis in the zone of influence of the object is associated with the reliability of detection of pollutants; if there is a tendency for the absence of pollutants in certain monitoring zones (or at individual points in the sampling system), the frequency of sampling and analysis of samples at these points can be increased, which reduces the volume of studies while maintaining the reliability of the monitoring results.

Background monitoring results are used as the basis for assessing the impact of an object on the OS.

When monitoring the components of the substation in the zone of influence of the object (for the CWD object - in the SPZ and ZZM), the observation areas are preliminarily determined by the results of measurements at the sources of pollutants or on the territory of the object (within the SPZ). Then, the dispersion and propagation fields of pollutants in PS components in the zones of influence of the object are calculated and the results of calculations are used to construct pollutant dispersion maps in PS components, which determine the maximum probable detection zone for pollutants dispersed in the OS.

When organizing monitoring of a hazardous production facility, it is recommended to use a system of equally equidistant (with a constant step) points located on equidistant (from the facility) circles. The density of sampling points is maximum in the monitoring zone closest to the object and decreases in proportion to the distance from it. This provides a higher density of points in the region of the most probable pollution (formed, for example, due to precipitation from atmospheric air) and a correlation of model (calculated) patterns of pollutant dispersion with measured values of pollutant concentrations on the ground. The drawing shows, by way of example, the recommended sampling scheme, which is a circle with radii of 1, 2, 3, 5, and 10 km and a center at the location of the CWD object. The circles are divided into 24 sectors.

The proposed method includes the following monitoring scheme:

- preparation of initial data for calculating dispersion from the results of measurements at pollutant sources and statistical processing of monthly meteorological data;

- calculation of dispersion of pollutants in the atmosphere;

- determination of the monitoring area in the SPZ and ZZM, selection of the set of sampling points in accordance with the recommended scheme (see Fig. 1) and the results of statistical processing of data from previous monitoring sessions by calculating the probabilities of the presence of pollutants in them using formulas (1) and (2) ;

- the issuance of tasks for sampling in the SPZ and ZZM;

- conducting a sampling session in the components of the natural environment and analysis of selected samples;

- processing of analysis data, construction of dispersion fields and their comparison with calculated data;

- adjustment of the parameters of the calculation model and the sampling system, which are taken into account in the formation of subsequent tasks for monitoring in the area of technogenic influence of the object (for example, in the SPZ and ZZM of the CWD facility);

- the issuance of monitoring data in the form of maps of dispersion and spread of pollutants in the components of the PS with an indication of the levels (contours) of pollution and forecasts.

The proposed method of environmental monitoring in the area of technogenic impact of a hazardous production facility makes it possible to obtain a reliable assessment of the impact of the facility on the environment and predict changes in its state in the future, which reduces the risk of increasing pollution of the environment and environmental emergencies. In addition, the proposed method allows to reduce the amount of research performed during monitoring, which significantly reduces the cost of its implementation.

Literature

1. RF patent No. 2223517 / Russia /. The method of radioecological monitoring of tritium content in the environment of an industrial enterprise / 24.01.2002.

2. RF patent No. 2005133758 / Russia /. The method of environmental monitoring of chemical weapons destruction facilities / Alekseev V.A., Voronin B.N., Gabrichidze T.G., Nazarov V.D., Tolstykh A.V., Kapashin V.P., Fomin P.M. / May 10, 2007.

Claims (3)

1. A method for environmental monitoring of hazardous production facilities (hereinafter referred to as facilities), including chemical weapons destruction facilities (hereinafter referred to as CCW facilities), including sampling of components of the natural environment, analysis of samples, processing of analysis data, evaluation carried out based on the results of processing the analysis data environmental conditions in the area of technogenic impact of the facility, for CCW facilities - in the storage and destruction of chemical weapons, in the sanitary protection zone, in the area of protective measures, held before the construction of the facility that background monitoring of the territory, designed to assess the state of the environment before the operation of the facility, comparing the monitoring data obtained during the operation of the facility with the results of background monitoring, as well as with established environmental quality standards in the form of maximum permissible concentrations (MPC), characterized in that monitoring during the operation of the facility is carried out at points (areas) of sampling with the most probable presence of pollutants (pollutants) in the monitoring sites and - soil, snow, water and bottom sediments, while the density of the points of the sampling system is determined by the specified probability of detection of pollutants in the zone of potential influence of the object, is maximum near the object and decreases towards the boundaries of the zone of its potential influence, and the frequency of sampling and analysis in each sampling point is proportional to the number of detections of changes in pollutant concentrations. 2. The method according to claim 1, characterized in that the samples are taken at points located, for example, on circles with radii of 1, 2, 3, 5 and 10 km, twenty-four points on each circle centered at the location of the source of pollutant emissions of an object, the number of which is determined by the statistical processing of monthly data on wind directions and speeds and the calculation of dispersion of pollutants from the object, and when analyzing samples taken at sample points, their toxicity is preliminarily determined using biotesting methods several characteristic groups SG-selective biological indicator bioassays and in the presence of toxic pollutant concentration determined in samples of the methods of quantitative chemical analysis. 3. The method according to claim 2, characterized in that the samples for analysis are taken simultaneously in various components of the natural environment, such as soil, water and bottom sediments.

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