RU2655623C2 - Method for environmental monitoring of temporarily abandoned mining districts - Google Patents

Abstract

FIELD: ecology.

SUBSTANCE: invention relates to ecology, namely to the assessment of the state of conserved areas of mineral development and their impact on the environment. For this, simultaneously with the monitoring of the conserved section of rock formation, a background monitoring of its natural analogue, which has not experienced any anthropogenic impact, but located in the same natural conditions, is carried out. Obtained monitoring results are compared and a conclusion about the degree of change of the conserved area is made, and after comparing the results of the monitoring with the MPC, the final assessment of the state of the temporarily abandoned site is made, taking into account the environmental norms of the region.

EFFECT: invention provides an increase in the accuracy of the assessment of the impact of environmental monitoring facilities on the components of the natural environment.

1 cl, 4 tbl, 1 ex

Description

The invention relates to the field of environmental monitoring, in particular to environmental monitoring of mining mining, and can be used in the development and implementation of measures to protect the environment.

The well-known "Method of environmental monitoring of hazardous production facilities" according to the patent of the Russian Federation No. 2413220 dated 10.26.2009, including sampling of components of the natural environment (atmospheric air, surface and groundwater, bottom sediments, soil and snow cover), analysis of samples, processing of analysis data, as well as comparing the monitoring data obtained during the operation of the facility with the results of background monitoring of the territory conducted before the facility began to function. Designed to assess the state of the environment and compare with established environmental quality standards in the form of maximum permissible concentrations (MPC). This method makes it possible to carry out monitoring work at points (areas) of the most probable presence of pollutants, determined by the results of an assessment of the environmental impact of the facility when calculating the dispersion of pollutants in the air based on measurements of their concentrations at emission sources, taking into account statistical meteorological data. The sampling area based on the results of modeling the dispersion of pollutants is determined by the established minimum concentration. The observation network is based on the maximum density of points near the object and their decrease towards the boundaries of the zone of its potential influence.

However, this method is based on monitoring work on points with a high content of pollutants, and exclusion from the observation grid of points with a minimum content detected in the previous observation period. The main emphasis is on average statistical meteorological data. The use of this method is possible only in the territory where the technical and information tools are sufficiently developed that allow the collection, transmission and comparative analysis of the data obtained. The main drawback is the orientation of the work on secondary processes and phenomena in the form of anomalous changes in individual components of the environment without taking into account the integral effects of the technosphere on nature. The use of this method is limited by the fact that it is based on the Roshydromet observation system. It is known that at present the network of observations is not sufficient in all places, which affects the completeness and quality of the data, and as a result, it is not always possible to get the desired picture. The disadvantage is the receipt of information on the environmental situation and the provision of predicting the pollution of only atmospheric air in the industrial region. Thus, the known monitoring method is not accurate enough from the point of view of assessing the state of the natural environment at mothballed mining sites.

 A known method of environmental monitoring of chemical weapons destruction facilities (patent RU2303780 C2 of 05/10/2007), including sampling of surface, ground and underground waters, snow cover, bottom sediments, soils, analysis of samples and data processing, recording the results in an analytical database, the results of the analysis data processing assess the environmental situation in the area of the facility for the storage and destruction of chemical weapons, in the sanitary protection zone, in the zone of protective measures, additionally conduct atmospheric sampling in air and monitoring of the animal and plant world in the area of the chemical weapons destruction facility, in the sanitary protection zone, in the protective measures zone, all samples are compared in accordance with the standards for maximum permissible concentrations (MPC) of each specific substance, when MPC is exceeded in the air water analysis, when exceeding the MPC in water, an analysis is carried out in the soil, when exceeding the MPC in the soil, an analysis is made of the animal and plant world in the area of the chemical weapons destruction facility, in the sanitary protection zone, in the protection zone As a result of comparing the obtained data, the analysis procedures are tightened, namely, the analysis deadlines are established, which are established in accordance with regulatory or, if the problem is solved before the construction of chemical weapons destruction facilities begins, background monitoring of the territory is carried out before construction of the chemical weapons destruction facility begins, intended for the construction of the facility, including sampling of surface, ground and groundwater, snow cover, bottom build-up of soil, soil, as well as additionally conduct sampling of atmospheric air and monitor the animal and plant world in the construction zone of the chemical weapons destruction facility, in the sanitary protection zone, in the protective measures zone, and then compare the results of the data obtained during the background monitoring with data obtained in the process of destruction of chemical weapons. Comparison of all samples is carried out in accordance with the standards for maximum permissible concentrations (MPC) of each specific substance, when exceeding the MPC in air, a water analysis is carried out, when exceeding the MPC in water, an analysis is carried out in the soil, when exceeding the MPC in the soil, the animal and plant world as a result of the comparison of the data obtained, they tighten the rules for carrying out analyzes, namely, reduce the time for analysis, lennye in accordance with the regulations, the processing of sample analysis data includes comparing the received data with the background monitoring data.

The disadvantage of this method is that environmental monitoring of chemical weapons destruction facilities in the first case compares all samples in accordance with the standards for maximum permissible concentrations (MPC) of each specific substance, but does not take into account the values of background monitoring, in the second case, conduct background monitoring territory (before the construction of the chemical weapons destruction facility), and then they compare the data obtained during the background monitoring with the data obtained in the process of tozheniya chemical weapons and with the norms for the maximum allowable concentration (MAC) of each individual substance. At the same time, the use of background monitoring data obtained before the construction of the facility does not allow an assessment of the components of the environment (soil, soil, snow, vegetation, animals) in conjunction with the constantly changing environmental conditions. The disadvantage of this method is that when conducting environmental monitoring do not take into account environmental standards (environmental standards of the region), identified and published in the open press, which reduces the accuracy of the assessment and determination of the tendency to restore the natural environment.

The prior art method of mountain environmental monitoring (Temporary provision on mountain environmental monitoring, Gosgortekhnadzor of Russia, 05.16.1997), which defines the goals, objectives and functions of mountain environmental monitoring, and also establishes the procedure for its implementation when using subsoil (prototype) . Mining and environmental monitoring includes observation, assessment, forecasting the harmful effects of mining on the environment and preparation of recommendations to prevent this impact, taking into account mineral resources and their use, as well as assessing the use of natural resources and the state of industrial safety in mining operations. Mining and environmental monitoring is carried out within the boundaries of the mining allotment, as well as the land provided for mining (land allotment), as well as outside them in the zone of harmful effects of mining. In accordance with paragraph 1.5. The basis of mining and environmental monitoring is the monitoring by users of mineral resources of the use of mineral resources, the state of the geological environment, mine workings, land, water bodies, and also clause 1.6. states that “The system of mining and environmental monitoring is part of the system of state monitoring of the geological environment, which is part of the Unified State System of Environmental Monitoring. The mountain environmental monitoring system interacts with the Russian emergency system, land monitoring system, the Unified information system of subsoil use in Russia and others. ” According to paragraph 2.2. The main tasks of mining and environmental monitoring are: assessment of the state of the environment and the use of mineral resources in mining operations; environmental forecast, including changes caused by industrial accidents and disasters; development of recommendations for the prevention of industrial accidents and disasters, the prevention or reduction of the harmful effects of mining on the environment, the rational use of mineral resources and the protection of mineral resources; ensuring the reliability of accounting for the movement of mineral reserves and losses during their extraction and primary processing. The solution of the tasks is achieved by organizing a system of remote and ground-based observations that provide high-quality and reliable information in the required volumes, analysis of this information and adoption of appropriate decisions based on the results of the analysis. In accordance with clause 2.3. The objects of mining and environmental monitoring are man-made objects (mining, dumps of overburden and host rocks, tailings, sedimentation tanks and accumulators of drainage and other industrial water, transport communications, etc.) formed during mining, transportation, processing of mineral resources, use of mineral resources in non-mining purposes and reclamation of disturbed lands, etc.

The disadvantage of this method is that mining and environmental monitoring is based on the general provisions for conducting monitoring studies, is carried out within the boundaries of the mining allotment, as well as the land plot, during the liquidation (conservation) of a mining enterprise and is carried out until the hydrogeological conditions and processes of displacement are stabilized the rock mass disturbed by mining operations does not spell out the criteria by which sections (polygons) of observations are selected, research parameters, not There are background monitoring values (a natural analogue), outside the zone of the harmful effects of mining, but located in the same natural conditions. The disadvantage of this method is that it is not intended to use key areas (polygons) for monitoring the state of soil, snow cover, species composition, pollution of the flora and fauna, biological objects (flora and fauna), including rare and endangered species that can be identified in conserved rock sections do not take into account environmental standards (environmental standards of the region) identified and published in an open furnace which reduces the accuracy of the assessment and determination of the tendency for restoration of the natural environment.

 The technical result is to increase the accuracy of assessing the impact of environmental monitoring on the components of the environment, by monitoring the conformity of the state of the components of the environment to the maximum permissible regulatory loads, taking into account the background values (natural analogue) and environmental standards of the region.

The technical result is ensured due to the fact that in the method of environmental monitoring in conserved rock sections, including monitoring of the conserved rock section and assessing the state of the conserved section in comparison with the maximum permissible concentrations (MPC), background monitoring of the natural analogue is carried out simultaneously with monitoring of the conserved section, not experienced anthropogenic impact, but in the same natural conditions, monitoring results obtained They inform and make a conclusion about the degree of change of the conserved area, and after comparing the monitoring results with the MPC, the final assessment of the state of the conserved area is made taking into account the environmental standards of the region.

The proposed method of environmental monitoring is carried out in two areas - in the conserved, when the pollution process has already occurred (stage of conservation) and in the background area (F), outside, which is a natural analogue of the conserved, according to the components of the environment (soil, soil, snow, vegetation, animals) in the relationship, which allows us to make an assessment taking into account constantly changing environmental conditions, which led to an increase in the accuracy of the assessment and determination of the tendency for restoration of the natural environment dy. If the results exceed the background, MPC and environmental standards of the region, a negative impact zone is projected taking into account weather conditions and the amount of pollutant emissions.

Environmental monitoring makes it possible to characterize the current state and influence of conserved mine workings on changes in the land fund and its quality indicators; changes in the species composition, density of growth and population of species of fauna and flora; soil and soil transformation. The degree of environmental pollution is carried out on the study of soils, soil and soil strata, snow cover, the study of vegetation and animals.

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 natural environment and predict changes in its condition in the future. Allows to put into operation the conserved area after some time of conservation. In addition, the proposed method allows to reduce the amount of research performed during monitoring, which significantly reduces the cost of its implementation.

The method is as follows. First, the background site is selected (a natural analogue of the conserved mining site) (F), while the network of monitoring observations (points), the dates on the background site (F) and the conserved mining site are selected. Monitoring is carried out simultaneously on a natural analogue (F) and on a conserved area of rocks. Assessment of the state of the environment in conserved rock sections is carried out taking into account the data of the natural analogue, MPC and environmental standards of the region. Constant points of monitoring observations are laid and determined at the beginning of the work, their location and frequency depends on the area of the object. The network of monitoring observations includes representative points located on the territory of the conserved plots and background plots (F). When creating a system for observing the state of the environment, the main attention is paid to:

a) analysis of the results of research of territories on environmental components; b) analysis of data on the sources and extent of anthropogenic impact on the environment, anthropogenic sources of environmental pollution;

            c) determining the optimal (necessary and sufficient) indicators of the monitoring system.

The functioning of the observational network provides a comprehensive assessment of the pollution of environmental components and their operational use.

As objects of environmental monitoring for constant monitoring, the components of the environment (soil cover, snow cover, vegetation, wildlife) are selected.

The time of observation (sampling) is set at the initial stage of monitoring, based on a comprehensive assessment of pollution of the soil and soil strata and use, natural and artificial changes in the state of the environment. The frequency of sampling twice a year is summer (soils and techno-soil and geobotanical monitoring) and the winter period - snow surveys (February - March) and determination of the number, density and species composition of mammals using the winter route method ( ZMU).

Monitoring of land resources includes an assessment of the effect of conserved mine workings on the state and change of the land fund and its quality indicators. On the territory adjacent to the conserved mine workings, observation posts are established for the possible transformation of the soil and soil stratum and the degree of its pollution. Soil monitoring is combined with monitoring of the animal and plant world.

The concentrations of pollutants in the selected samples (soil, vegetation) are determined by the method of quantitative chemical analysis, the analysis and calculation of the coefficients allows us to say about the migration ability of the elements common in the conditions of the conserved area, their ability to concentrate in soil and vegetation and carried outside the monitoring area . In soil sections, sampling is carried out depending on the degree of anthropogenic load in the soil at depths (0-10, 10-20, 20-3-, 30-40, 40-50 cm), and on the formed soils according to typical horizons . Plant samples are taken on an area of 250 cm ² in triplicate, with species analysis.

The biological activity and toxicity of soils are evaluated by bioassay and bioindication. The combination of bioindication methods and chemical-analytical studies in soil samples can increase the information and reliability of monitoring data. Biological studies are conducted on the basis of a set of bioassays and bioindicators, analysis of samples using certified methods makes it possible to assess the quality of the environment with the identification of the prerequisites for the emergence of conditions for the emergence of self-healing processes of the natural environment in a conserved area.

The system of environmental monitoring of soil conditions is based on landscape-geochemical differentiation and the most probable paths of surface and soil (subsoil) migration of pollutants in accordance with the requirements of GOST 17.4.3.01-83, 17.4.4.02-84, 17.4.3.02.-85 , RD 07-291-99 and “Temporary provision on mountain environmental monitoring”, which is known from the prior art, where the general provisions of the goals, objectives, objects and functions of mountain environmental monitoring are formulated, but they do not provide the possibility of obtaining a reliable assessment in zdeystviya object on the environment and forecasting changes its state in the future in accordance with the maximum permissible load and environmental standards in the region.

The purpose of environmental monitoring is to assess the condition of industrial soils in the coal mine zone; control over restoration of soil fertility; pollution control, both in the coal mine zone and in the background areas, in the environment. The structure is subject to mandatory control, physical properties - particle size distribution, bulk mass, humidity, etc., chemical properties - pH, humus, nitrogen, CO ₂ carbonates, readily soluble salts, physicochemical properties - exchange bases, exchange cations - Na ⁺ , Al ³⁺ , H ⁺ , heavy metals, soil biological activity, toxicity. The parameters are selected taking into account the processes occurring in naturally overgrowing dumps, in the cultivated areas and in the conservation areas of the brown coal deposit; when soil is contaminated with heavy metals characteristic of a given territory.

The snow cover records the actual amount of pollutant deposition in the cold and long season of the year, to fix the full spectrum of pollutants, an integral sample is taken to the entire depth of its occurrence. The data obtained by the method of snow surveying are indicative, since the snow cover, being a depositing medium, has an integrated reflection of the surface concentration of atmospheric impurities. After transportation of snow water samples in laboratory conditions in them according to GOST 17.1.3.07-82; GOST 17.1.5.05-85; The list of fishery standards, 1993; SanPiNu 4630-88. The general requirements for the protection of surface waters from pollution [GOST 17.1.3.13-86] carried out chemical-analytical work to determine the composition and quality of snow water according to standardized methods.

Monitoring of the state of the vegetation cover is carried out on the observational reference network. The main task is the long-term monitoring of the state of the vegetation cover, from the pioneer state to the equifinal (final) state, the identification of the reaction of the vegetation cover, and, above all, rare species to anthropogenic impact, the determination of protected species in the adjacent strip of natural objects. The constant trial area within itself should be as uniform as possible in terms of the terrain, the nature of the soil, the steepness and exposure of the slope, the level of groundwater, the nature of the underlying rocks. When conducting monitoring studies of plants, special attention is paid to the morphological characteristics of the leaves, the peculiarities of pigmentation on the trunk, leaves, flowers, and the identification of various anomalies.

The system of environmental monitoring of the state of the animal world is based on the estimation of the number of animal populations, including those included in the Red Book of the Russian Federation, the Red Book of the Irkutsk Region in the territory of preserved mining sites, as well as the forecast of the status of populations of rare animal species and their habitats in the impact zone of preserved areas mining operations. The estimation of the number of animals, density and species composition, structural features, and features of biotopic confinement within the selected habitat types is carried out according to the results of route studies, which allows us to estimate the initial number of animals and their species diversity and to trace the nature and direction of changes, both in species and numerical direction.

 At the same time, the same work is carried out on a pre-selected background site, which is located outside the conserved area, i.e. outside the zone of its influence on environmental indicators at the stage of monitoring work.

The proposed monitoring method is presented below in tabular form, as an example of the method:

- monitoring of the soil stratum includes the definition of controlled parameters.

Table 1

Stage of work Types of work in progress Number of samples Periodicity Types of analyzes
Field
Ecological and geochemical examination of the territory. On pledged sites
(key and background)
soil and rock samples are taken.
Depends on the number of reference points and their location.
Once a year
Determination of soil moisture, pH. Analytical Performing physical and chemical analyzes of rocks and soils.
Once a year Determination of content: humus, carbonates, water-soluble salts, (exchange bases Ca, Mg, Na, Al, H); heavy metals (Cu, Ca, Mg, Ba, Cr, Sr, Ni, Co, V, Ti, Fe, Mn, Pb). Cameral Generalization of the received material. Preparation of a final report. - - -

- monitoring of snow cover includes the determination of controlled parameters in snow water.

table 2

Stage of work Types of work in progress Number of samples Periodicity Types of analyzes
Field
Conducting snow surveys at the laid sites (key and background); snow sampling is performed.
Depends on the number of reference points.

Once a year
- Analytical Performing physical and chemical analyzes of snow water. Preparation of a final report. Once a year Solids, pH, suspended solids, HCO ₃ ^- , Cl ^- , SO ₄ ^2- , heavy metals (Cu Zn, Ca, Mg, Cr, Ba, Ni, Pb, Cd).

- monitoring of vegetation includes the definition of controlled parameters.

Table 3

Stage of work Types of work in progress Number of samples Periodicity Types of analyzes
Field
 Bookmark and description of geobotanical sites on key and background sites. Depends on the number of reference points
Once a year
- Cameral Analysis and assessment of the species composition, the density of growth of species in conserved areas; assessment of the abundance and number of protected species in the zone of influence of the section; drawing up a map-diagram of the spatial distribution and changes in the vegetation cover. Preparation of a final report. - - -

- monitoring of the study of the animal world includes the definition of controlled parameters. Work is carried out 2 times a year (during snow surveying - ZMU and in the summer).

Table 4

Stage of work Types of work in progress Number of samples Periodicity Types of analyzes
Field
Bookmark and description of wildlife monitoring points at representative sites (key and background areas). Depends on the number of reference points 2 times per year - Cameral Analysis and assessment of the number, density and species composition of mammals in conserved areas; habitat areas of rare and protected species. Preparation of a final report. - - -

The proposed monitoring method was tested in three mothballed areas “Production section Razrez Azeisky Branch Tulunugol LLC VostokSibUgol company” work was carried out in this area for 5 years, which allowed to identify the following trends:

- restoration of the fertile soil layer;

- active restoration of vegetation;

- An increase in the distribution areas of living animals (entry from natural areas to conserved areas).

Forms for the presentation of monitoring results (tables, graphics):

- materials obtained in the field are processed: in the field - selection, labeling;

- in the laboratory (analytical) - preparation and conduct of chemical-physical analysis;

- cameral - analysis, evaluation and generalization of the material obtained.

Before using analytical data, digital material is processed and displayed graphically in order to more clearly present the revealed patterns. The data are tabulated and, based on their analysis, the features of the controlled components are revealed: soil cover (soil-soil stratum), snow cover, flora and fauna. The results of the spatial distribution and changes in the vegetation cover are presented in the form of tables, graphs and cartographic schemes.

Example

At the beginning of monitoring work, a network of observations is created in the conserved area, at the same time background monitoring is carried out on the natural analogue of the conserved area (F) with the laying of the observation network, on the natural analogue and the conserved area, environmental samples are taken, samples are analyzed and the results obtained are compared, MPC and environmental regulations of the region (ENR).

For example, at point 1 of the conserved area in the soil at a depth of 0-10 cm, the content of nickel (Ni) is 26 mg / kg (A ₁ ), the soils of the natural analogue (F) contain 20 mg / kg, and the MPC of soils is 4 mg / kg, the ENR of the soils of the Baikal geoecological region is 44.7 mg / kg. Thus, we compose an analytical series:

4 <(20 <26) <44.7

The soils of the conserved area at the beginning of monitoring work contain nickel in excess of the MPC value and indicators of the natural analogue (F), which is the result of anthropogenic impact on the soils during hydrocarbon production, but they do not exceed the ENR of the soils of the Baikal geoecological region where monitoring.

2. The next year, during monitoring, at point 1, soil and soil studies are carried out, simultaneously with soil studies in a natural analogue, a comparison is made with the data obtained in the previous year of monitoring observations, in a natural analogue (Ф ₁ ) - 20 mg / kg, in soil-soil - 26 mg / kg, comparisons are made with the maximum permissible concentration of soils - 4 mg / kg, the ENR of the soils of the Baikal geoecological region - 44.7 mg / kg, in the natural analogue (Ф _n ) the soils contain - 20 mg / kg. , in the soil, the result is 70 mg / kg (A ₂ ).

4 <20 <26 <70 44.7

According to the results of monitoring studies, the concentration of nickel in the natural analogue of the soil has not changed, an increase in the content of the element is revealed only in the conditions of the conserved area, which shows pollution of the conserved area with nickel over the past period, therefore, it is necessary to determine the causes of contamination of the area of the conserved area.

3. According to well-known methods of monitoring observations, the accuracy of determining the content of pollutants in natural environments is quite high, but using them to characterize the pollution of the conserved area it is impossible to identify the true level of pollution, and when using this method, the accuracy in determining the true pollution of natural environments of conserved areas increases more than 50%.

Claims (1)

The method of environmental monitoring in conserved rock areas, including monitoring of the conserved rock section and assessment of the state of the conserved section in comparison with the maximum permissible concentrations (MPC), characterized in that simultaneously with monitoring the conserved area, background monitoring of a natural analogue that has not experienced anthropogenic impact is carried out, but located in the same natural conditions, the monitoring results are compared and conclude about the degree of changes in the conserved area, and after comparing the monitoring results with the MPC, the final assessment of the state of the conserved area is made taking into account the environmental standards of the region.