RU2161321C2 - Process of control over effluent of polluting substances from sources polluting city atmosphere - Google Patents

Abstract

FIELD: meteorology. SUBSTANCE: process is intended for use in complex of atmospheric surveillance measures for timely detection of sources polluting atmosphere which have current effluent of harmful substances unauthorized by norms. Software of system of atmospheric monitoring of city includes algorithm of solution of inverse problem of diffusion of polluting substances in air basin of city. Given algorithm ensures detection of locations of sources polluting atmosphere whose level of effluent of harmful substances exceeds level authorized by norm. Results of detection are used to conduct urgent test of these sources polluting atmosphere right at points of their locations. EFFECT: timely detection of sources polluting city atmosphere with level of effluent of harmful substances exceeding authorized norm thanks to expansion of functional and operational capabilities of system monitoring pollution of atmosphere. 1 cl

Description

 The invention relates to meteorology and can be used in a system of atmospheric protection measures for the rapid identification of sources of atmospheric pollution (IZA) with the current regulatory and unauthorized level of emissions (grams / sec) of harmful substances (EXPLOSIVES).

 The most important area of atmospheric protection activity is the state control of IZA in order to obtain objective information on explosive emissions into the atmosphere by industrial enterprises and transport, assess compliance of actual emission values with established standards, and, if there is a discrepancy, make decisions on the necessary amount of organizational and technical atmospheric protection measures to ensure this conformity.

 At present, the legislatively established standards for the level of explosive emissions in the atmosphere are the level of maximum permissible emissions (MPE) of explosives (grams / sec) into the atmosphere, determined by the levels of maximum permissible concentrations of explosives in the city atmosphere.

 When forming recommendations on the regulation of explosive emissions by industrial enterprises, current measurements of the state of atmospheric air pollution are carried out using a network of fixed and mobile route control points. The structure and configuration of the location on the terrain of the network of control points is determined by the area of use of the observation data and the range of tasks to be solved within the framework of atmospheric protection measures (see, for example, V.I. Krasov et al., "Optimization of the spatial structure of the observation network when monitoring pollution of the city’s atmosphere; in Proceedings of the MGO named after A.I. Voyeykov "Methods and means of monitoring air pollution and industrial emissions", L., Gidrometeoizdat, 1987, p. 13-14).

 The planning of the spatial structure of the air pollution control network is currently based on a few regulatory documents that give recommendations on the number of control points, but the location of points on the ground is not determined (see, for example, “Guidelines for the control of air pollution” RD 52.04.186- 89, M., Hydrometeoizdat, 1991, p. 11-13).

 There is a method of forming a monitoring network for monitoring atmospheric pollution in the city, carried out by a network of stationary and route control points, which are located in densely populated areas with adverse environmental conditions, subject to regulatory restrictions by various city services: architectural, fire, sanitary, etc. (see, for example, patent N 2102782 dated 02/08/94. "A method for forming an observation network for monitoring atmospheric pollution in the city." Authors - V. S. Zemskov, V. I. Kiselev, V. P. Kolodiy, S. M. Efendiev, Applicant - State Rocket Center "Design Bureau named after Academician V.P. Makeev").

 The effectiveness of the control of urban air pollution using the known method is confirmed by the results of its operation in the city of Chelyabinsk (see, for example, V.I. Kiselev, A.V. Mochalina "Assessment of the carbon monoxide concentration field in the air basin of the city of Chelyabinsk based on the results of experimental operation of an automated system environmental monitoring ", Ufa, 1995, Conference proceedings on the ecology of industrial cities).

 Evaluation of the explosive emissions of various IZA according to observations at a network of air pollution control points, a comparison of the obtained estimates of the explosive IZA emissions with normatively authorized values and a decision is not made on the compliance of the values of the estimates of IZA emissions with standard values in the known method.

 It is known that identifying and determining the location on the IZA area with a normatively unauthorized level of explosive emissions into the atmosphere is one of the main tasks of state control of IZA.

 The closest in technical essence to the claimed method and selected as a prototype is a method for controlling sources of explosive emissions of industrial enterprises of the city, including an inventory of sources of explosive emissions, deployment and operation of an environmental monitoring system in the city, including an automated system for monitoring the state of atmospheric pollution, carrying out current measurements of the level of air pollution in the city, taking into account restrictions on the functioning of regulations specified by regulatory documents, as well as periodic (with a predetermined frequency) planned monitoring of explosive emissions directly from the IZA at their location at the enterprises, (see "All-Union Normative Document. Guidelines for Monitoring Sources of Atmospheric Pollution. OND-90. Part 1, St. Petersburg, 1992, pp. 35-40).

 In the known method, the planned control of explosive emissions at the location of the IZA at the city enterprises is carried out no more than once every six months. The low frequency of routine monitoring of explosive emissions at the location of the IZA does not provide for the prompt detection of IZA with a normatively unauthorized level of explosive emissions, and the data on measurements of air pollution of the explosives, as a rule, are not associated with the level of emissions of specific IZA. This is the disadvantage of the prototype method.

 The present invention solves the problem of the rapid detection of IZA with a normatively unauthorized level of explosive emissions, during and according to the results of the current measurement of urban air pollution, by expanding the functional and operational capabilities of the air pollution monitoring system by including an algorithm for solving the inverse problem in its mathematical software dispersion, ensuring the identification of IZA with a regulatory and unauthorized level of explosive emissions, to identify which carry out ext enny (unscheduled) BB control these emissions IZA parameters according to their location on the ground.

The problem is solved by the fact that the proposed:
A method for controlling the IZA emissions of a city, including an inventory of sources of city air pollution, the deployment and operation of an atmosphere monitoring system in the city, including an automated system for monitoring the state of atmospheric pollution (AFM), which carries out ongoing measurements of the level of air pollution in the city in points, number and the places of functioning of which in the city are regulated by normative documents and the planned control with a normatively specified frequency you of IZA explosives at their location on the territory of the city, characterized in that the atmospheric monitoring system is introduced into the working part of the software and mathematical support (MIP) and, in the process of functioning of the atmospheric monitoring system, an algorithm is used for the relationship between the mass emission of harmful IZA substances and the level the concentration of this explosive in control points under current weather conditions (air temperature, wind speed and direction), according to the calculation results, all IZAs are ranked by the level of decrease in their contribution and the level of explosive surface concentration at each point of control of atmospheric pollution, including those from the main pollutants, those from which the total contribution is not less than 80% of the total calculated pollution at each of the points of control of atmospheric pollution, are computed calculated for different values of mass emissions of the main ones explosive concentration values with measured values, for a minimum quality criterion, for example, for a minimum of the sum of the standard deviations of the calculated from the measured concentration values BB, at all points define the control values for the mass emissions of the main AIA, including set location IZA which exceed the maximum level of mass ejection sanctioned by an amount not less than 10% and measurement is carried out extra weight these emissions BB IZA according to their location. The presence of distinctive features, compared with the prototype, confirms the novelty of the claimed method.

 The proposed method for controlling explosive emissions by sources of urban atmospheric pollution, carried out according to monitoring of atmospheric pollution, primarily in residential areas with a high population density and a high degree of atmospheric pollution, allows in the process of its implementation to quickly identify the location of IZA with a normatively unauthorized level of explosive emissions in the atmosphere of an industrial city without (additional) attraction of flare measurements and without continuous measurement of emission parameters in ex IZA.

To clarify the technical essence of the proposed invention, an algorithm for identifying IZA that exceeded the normatively established maximum allowable emission of explosives into the atmosphere of a city developed at the State Missile Center "Design Bureau named after Academician V. P. Makeev" is considered. The algorithm operates on the basis of solving the inverse problem of estimating the emission of explosives from IZA in the conditions of various cities of the Urals (Chelyabinsk, Zlatoust, Kyshtym, Pervouralsk). These cities, as objects of monitoring, have the following characteristics:
- the number of IZA - 9800 - 600 pipes;
- sources are located in large groups of 5-10 pieces at a distance of 5-10 to 50 meters, which makes it difficult to identify the impact of each of them on the amount of explosive emissions in the whole city;
- the geometric dimensions of the pipes are characterized by a wide variety - from low, up to 10 m high, to high, up to 150 m high;
- mass emission from various sources is characterized by extremely great diversity: from a few grams / second to 1500 grams / second from one pipe;
- due to the compact arrangement of groups of sources, in almost any direction of the wind, the superposition of torches occurs;
- as control points where regular measurements are taken, both existing stationary and automatic air pollution control posts (Chelyabinsk) are used, the spatial structure of which is from 12 (Chelyabinsk) to 3 (Kyshtym) control points developed in accordance with the methodology of the "Method of forming a network of observations for monitoring atmospheric pollution of the city" application for invention N 94004144/28 (004300) from 02/08/94. IPC G 01 W 1/00 and is implemented or is being introduced in these cities.

где C_i ^изм, C_i ^ф, C_i ^р - измеренное, фоновое, расчетное значения приземной концентрации конкретного загрязняющего вещества, соответственно на i - м АПК, мг/м³; Ci^р - расчетное значение определяется при текущих значениях метеорологических метеопараметров и заданных значениях массовых выбросов ИЗА;
- варьируют величиной массового выброса ВВ из каждого ИЗА, минимизируя функционал J, например, методом поиска глобального экстремума;
- принимают за оценки (m_i ^ф) истинных значений массовых выбросов ВВ основных ИЗА значения массовых выбросов основных ИЗА, при которых достигается минимум функционала J;
- оценки массовых выбросов ИЗА, полученные выше, сравнивают со значениями m_i ^ПДВ для каждого из ИЗА по следующему решающему правилу: если m_i ^ф ≥ m_i ^ПДВ(1+ α), где α = 0,1, то ИЗА относится к источникам, превысившим нормативно-санкционированный уровень выбросов ВВ в атмосферу;
- повторяют указанную последовательность действий по каждому ВВ;
- осуществляют внеплановый (экстренный) контроль ИЗА с нормативно-несанкционированным уровнем выбросов ВВ в атмосферу;
- по результатам внепланового контроля ИЗА осуществляют необходимый комплекс атмосфероохранных мероприятий, направленных на понижение уровня выброса ВВ в атмосферу у выявленных ИЗА.In the process of implementing the proposed method for controlling emissions of pollutants from the city’s IHA, the following sequence of actions is performed:
- at control points and weather stations, respectively, current values of the concentration of explosives in the atmosphere, meteorological parameters (ambient temperature, wind speed and direction, etc.) are measured;
- at current values of meteorological parameters, the surface concentration of the controlled pollutant from each IZA is calculated at each control point, according to the explosive dispersion model given in the Methodology for Calculating the Concentrations of Atmospheric Air of Hazardous Substances Contained in Emissions of Enterprises (OND-86, Goskomhydromet, Leningrad, 1987, pp. 4-13, formulas (2.1.) - (2.31 g)), or according to other models (see, for example, NL Byzova "Scattering of impurities in the atmospheric boundary layer", Moscow, Gidrometeoizdat, 1974, p. 192.);
- determine the estimated total concentration of the controlled pollutant from all the IZA and the percentage contribution of each IZA to the calculated total concentration at each IZA in the calculated total concentration at each control point;
- All ISAs are ranked by their contribution to the level of surface concentration of explosives at each point of air pollution control, including those from the main pollutants that are ISA, whose total contribution is at least 80% of the total calculated pollution at any of the points of air pollution control;
- include the total contribution from non-basic IZA to background pollution - C _f ;
- determine the value of the functional J

where C _i ^ism , C _i ^f , C _i ^p is the measured, background, calculated value of the surface concentration of a particular pollutant, respectively, on the i-th APC, mg / m ³ ; Ci ^p - the calculated value is determined at the current values of meteorological meteorological parameters and given values of mass emissions of IZA;
- they vary with the mass emission of explosives from each IZA, minimizing the functional J, for example, by searching for a global extremum;
- take the estimates (m _i ^f ) of the true values of the mass emissions of explosives of the main ISA values of the mass emissions of the main ISA, at which the minimum of the functional J is achieved;
- estimates of the mass emissions of IZA obtained above are compared with the values of m _i ^MPE for each of the IZA according to the following decisive rule: if m _i ^f ≥ m _i ^PDV (1+ α), where α = 0.1, then IZA refers to the sources exceeding the normatively-authorized level of explosive emissions into the atmosphere;
- repeat the specified sequence of actions for each explosive;
- carry out unscheduled (emergency) control of IZA with a regulatory and unauthorized level of explosive emissions into the atmosphere;
- according to the results of unscheduled control of the IZA, they carry out the necessary set of atmospheric protection measures aimed at lowering the level of explosive emissions into the atmosphere of the identified IZA.

 An assessment of the accuracy of the proposed algorithm based on numerical machine modeling of the process of atmospheric pollution and the operation of the algorithm itself to identify IZA with a normatively unauthorized level of explosive emissions showed that the reliability of the algorithm is ~ 80%, i.e. in 80% of cases, IAS were reliably determined by the algorithm as exceeding the MPE.

 The proposed method for controlling emissions of polluting substances by sources of pollution of the city’s atmosphere compared to the known prototype method provides, first of all, the speed of identifying the location of IZA with a normatively unauthorized level of explosive emissions into the city’s atmosphere with a high degree of reliability of identifying these sources.

Claims (2)

 1. A method of controlling emissions of harmful substances (BB) by sources of pollution of the city’s atmosphere, including an inventory of sources of pollution of the city’s atmosphere, the deployment and operation of a monitoring system on the territory of the city, including an automated monitoring system (AFM) of the state of pollution of the atmosphere, which carries out ongoing level measurements air pollution in the city in points, the number and places of functioning of which in the city are regulated by regulatory documents, and planned monitoring at a predetermined frequency of harmful substances (BB) emissions by sources of atmospheric pollution (IAS) at their location in the city, characterized in that they also introduce atmospheric monitoring systems into the working mathematical and software support (PMO) the process of functioning of the atmospheric monitoring system involves an algorithm for the relationship between the mass emission of explosive materials from the IZA and the concentration level of this explosive in control points under current weather conditions, according to the results of calculations All ISAs are measured according to their contribution to the level of surface concentration of explosives at each point of control of atmospheric pollution, including those that are the main pollutants, whose total contribution is not less than 80% of the total calculated pollution at each point of control of atmospheric pollution; different values of mass emissions of the main ISA values of the concentration of explosives at control points with measured values at the same points for a minimum quality criterion, for example, a minimum amount of mean square deviations of the calculated from the measured values of the concentration of explosives, in all control points determine the values of mass emissions for all the main IZA, among which establish the location of the IZA, exceeding the level of the maximum authorized mass emission by at least 10% and carry out emergency measurements of the mass emissions of the explosives of these IZA at their location.  2. A method of controlling emissions of harmful substances by sources of city air pollution according to claim 1, characterized in that the composition of the variable parameters, which minimize the quality criterion, include wind speed and direction.