WO2019090554A1 - Method for monitoring the quality of water at water source - Google Patents
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Abstract
A method for monitoring the quality of water at a water source, comprising the following steps: step 1: determining a target water source, and constructing a water flow model by using remote sensing data from an observation satellite; step 2: evaluating various water quality elements of the water source according to an ecosystem stability degree, an ecosystem loss degree, and a risk degree of a risk source of the water source; step 3: performing overall safety level evaluation on the quality of water at the water source according to the water flow model on the basis of a fuzzy mathematical method; step 4: presetting a water quality migration distribution model of the water source according to the local meteorological environment and geological conditions; and step 5: establishing an early warning mechanism and an emergency mechanism by using the water quality migration distribution model of the water source. In this way, a wide range of surface water sources can be quickly and conveniently monitored and evaluated; furthermore, obtained monitoring results have the advantages of both spatiality and dynamics, thereby facilitating management of the water sources and prediction of pollution status.
Description
本发明属于水质安全技术领域,特别是涉及一种水源地水质监测方法。The invention belongs to the technical field of water quality safety, and in particular relates to a water quality monitoring method for water source.
随着我国经济社会快速发展、人口持续增长和城镇化率逐步提高,水源地面临的环境压力显著增大,水质总体呈下降趋势,甚至部分水源因水质下降,不得不更换取水口位置,或是关闭水源地。目前,流域水环境的健康发展受到前所有为的挑战。With the rapid development of China's economy and society, the continuous population growth and the gradual increase of urbanization rate, the environmental pressure on the water source area has increased significantly, the water quality has generally declined, and even some water sources have to change the water intake position due to the water quality decline, or Turn off the water source. At present, the healthy development of the water environment in the basin is challenged by all of the former.
现有的区域生态监测方法中主要针对城市、流域等而设计的,缺乏面向地表水源集水区生态监测方法的指标体系和相关指数模型;对于流域监测方法中,由于缺乏多时相定量的空间数据支持,很难探明复杂流域下垫面作用过程的复杂性,以致大多数监测指标由于缺乏过程‐机理分析,停留在定性分析上,缺乏可靠性。The existing regional ecological monitoring methods are mainly designed for cities, river basins, etc., lacking the index system and related index model for surface water source watershed ecological monitoring methods; for the basin monitoring method, due to the lack of multi-temporal quantitative spatial data Support, it is difficult to find out the complexity of the process of underlying surface in complex watersheds, so that most monitoring indicators are stuck in qualitative analysis due to lack of process-mechanism analysis and lack of reliability.
发明内容Summary of the invention
本发明主要解决的技术问题是提供一种水源地水质监测方法,保证能够快速、方便的实现大范围的地表水源地的监测评价,得到的监测结果也具有空间性和动态性的优点,便于水源地的管理和对污染情况的预判。The technical problem mainly solved by the invention is to provide a water quality monitoring method for a water source, which ensures rapid and convenient realization of monitoring and evaluation of a wide range of surface water sources, and the obtained monitoring results also have the advantages of space and dynamics, and are convenient for water sources. Land management and pre-judgment of pollution.
为解决上述技术问题,本发明采用的一个技术方案是:提供一种水源地水质监测方法,包括以下步骤:In order to solve the above technical problem, a technical solution adopted by the present invention is to provide a water quality monitoring method for a water source, comprising the following steps:
步骤一:确认目标水源地,利用观测卫星的遥感数据,构建水流模型;Step 1: Confirm the target water source and use the remote sensing data of the observation satellite to construct a water flow model;
步骤二:根据水源地的生态系统稳定度、生态系统损失度和风险源危险度对各项水源地水质要素进行评估;Step 2: Evaluate the water quality elements of each water source according to the ecosystem stability, ecosystem loss and risk source risk of the water source;
步骤三:根据水流模型基于模糊数学方法对水源地的水质进行整体的安全等级评估;Step 3: According to the water flow model, based on the fuzzy mathematical method, the overall safety level assessment of the water quality of the water source is performed;
步骤四:根据当地的气象环境和地质条件预设水源地水质迁移分布模型;Step 4: Predict the water quality migration distribution model of the water source according to the local meteorological environment and geological conditions;
步骤五:利用水源地水质迁移分布模型建立预警机制和应急机制。
Step 5: Establish an early warning mechanism and an emergency mechanism by using the water source migration distribution model of the water source.
进一步地说,所述步骤二中的所述生态系统稳定度包括地质土壤要素、地貌植被要素、生态群体结构、生态恢复能力要素和人为因素。Further, the ecosystem stability in the second step includes geological soil elements, geomorphic vegetation elements, ecological group structure, ecological restoration capacity elements and human factors.
进一步地说,所述步骤二中的所述风险源危险度包括土壤沙化要素、水土流失要素、污染源排放要素、自然灾害要素和干旱缺水要素。Further, the risk source risk in the second step includes soil desertification elements, soil erosion factors, pollution source emission factors, natural disaster elements, and drought and water shortage elements.
进一步地说,在所述步骤二中的所述生态系统损失度包括饮用水损失度要素和水利设施要素。Further, the degree of ecosystem loss in the second step includes a drinking water loss factor and a water conservancy factor.
进一步地说,所述人为因素包括过度垦殖土地要素、过度放牧要素和过度采药要素。Further, the human factors include excessively cultivated land elements, overgrazing elements, and over-harvesting elements.
进一步地说,在所述步骤一的利用观测卫星的遥感数据之前,要对观测卫星的遥感数据进行辐射定标、几何纠正和纠正预处理,从而得到地表反射的遥感图像。Further, before the remote sensing data of the observation satellite is used in the first step, the remote sensing data of the observation satellite is subjected to radiometric calibration, geometric correction and correction preprocessing, thereby obtaining a remote sensing image of the surface reflection.
进一步地说,所述饮用水损失度要素的检测通过地面统计数据,结合供水能力评价模型,计算水体的可供水量以及需求水量的比例,确认水源地当前的人口的需求量,计算水源地当前的供水能力,评估水源地当前饮用水的安全等级。Further, the detection of the drinking water loss factor is calculated by using ground statistics, combined with the water supply capacity evaluation model, calculating the water supply amount and the proportion of the required water volume, confirming the current population demand of the water source, and calculating the current water source current. The water supply capacity to assess the current level of safety of drinking water in the water source.
本发明的有益效果至少具有以下几点:The beneficial effects of the present invention have at least the following points:
一、本发明利用观测卫星的遥感数据,从而进一步优化构建水流模型,保证能够快速、方便的实现大范围的地表水源地的监测评价;1. The present invention utilizes remote sensing data of observation satellites to further optimize the construction of the water flow model to ensure rapid and convenient implementation of monitoring and evaluation of a wide range of surface water sources;
二、本发明根据水源地的生态系统稳定度、生态系统损失度和风险源危险度对各项水源地水质要素进行评估考虑各指标,可以得到水源的总体安全等级,过程机理明确,结合水质迁移分布模型,得到的监测结果也具有空间性和动态性的优点;2. The invention evaluates the water quality elements of various water sources according to the ecosystem stability, ecosystem loss and risk source risk of the water source. Considering the indicators, the overall safety level of the water source can be obtained, and the process mechanism is clear, combined with water quality migration. The distribution model, the obtained monitoring results also have the advantages of spatial and dynamic;
三、本发明根据气象环境和地质条件预设水源地水质迁移分布模型,提高水源地水质安全预警的主动性,便于水源地的管理和对污染情况的预判。3. According to the meteorological environment and geological conditions, the present invention predetermines the water source migration distribution model of the water source, improves the initiative of the water source safety warning, and facilitates the management of the water source and the pre-judgment of the pollution situation.
下面对本发明的较佳实施例进行详细阐述,以使本发明的优点和特征能更易于被本领域技术人员理解,从而对本发明的保护范围做出更为清楚明确
的界定。The preferred embodiments of the present invention are described in detail below to make the advantages and features of the present invention more readily understood by those skilled in the art, so that the scope of the present invention is more clearly defined.
Definition.
实施例:一种水源地水质监测方法,本发明包括以下步骤:Embodiment: A method for monitoring water quality in a water source, the present invention includes the following steps:
步骤一:确认目标水源地,利用观测卫星的遥感数据,构建水流模型;Step 1: Confirm the target water source and use the remote sensing data of the observation satellite to construct a water flow model;
步骤二:根据水源地的生态系统稳定度、生态系统损失度和风险源危险度对各项水源地水质要素进行评估;Step 2: Evaluate the water quality elements of each water source according to the ecosystem stability, ecosystem loss and risk source risk of the water source;
步骤三:根据水流模型基于模糊数学方法对水源地的水质进行整体的安全等级评估;Step 3: According to the water flow model, based on the fuzzy mathematical method, the overall safety level assessment of the water quality of the water source is performed;
步骤四:根据当地的气象环境和地质条件预设水源地水质迁移分布模型;Step 4: Predict the water quality migration distribution model of the water source according to the local meteorological environment and geological conditions;
步骤五:利用水源地水质迁移分布模型建立预警机制和应急机制。Step 5: Establish an early warning mechanism and an emergency mechanism by using the water source migration distribution model of the water source.
所述步骤二中的所述生态系统稳定度包括地质土壤要素、地貌植被要素、生态群体结构、生态恢复能力要素和人为因素。The ecosystem stability in the second step includes geological soil elements, geomorphological vegetation elements, ecological group structure, ecological restoration capacity elements and human factors.
所述步骤二中的所述风险源危险度包括土壤沙化要素、水土流失要素、污染源排放要素、自然灾害要素和干旱缺水要素。The risk source risk in the second step includes soil desertification elements, soil erosion factors, pollution source emission factors, natural disaster elements, and drought and water shortage elements.
在所述步骤二中的所述生态系统损失度包括饮用水损失度要素和水利设施要素。The degree of ecosystem loss in the second step includes drinking water loss factors and water conservancy facilities.
所述人为因素包括过度垦殖土地要素、过度放牧要素和过度采药要素。The human factors include excessively cultivated land elements, overgrazing elements, and over-harvesting elements.
在所述步骤一的利用观测卫星的遥感数据之前,要对观测卫星的遥感数据进行辐射定标、几何纠正和纠正预处理,从而得到地表反射的遥感图像。Before using the remote sensing data of the observation satellite in the first step, the remote sensing data of the observation satellite is subjected to radiometric calibration, geometric correction and correction preprocessing, thereby obtaining a remote sensing image of the surface reflection.
所述饮用水损失度要素的检测通过地面统计数据,结合供水能力评价模型,计算水体的可供水量以及需求水量的比例,确认水源地当前的人口的需求量,计算水源地当前的供水能力,评估水源地当前饮用水的安全等级。The detection of the drinking water loss factor is calculated by using ground statistical data, combined with the water supply capacity evaluation model, calculating the water supply amount and the proportion of the required water volume, confirming the current population demand of the water source, and calculating the current water supply capacity of the water source. Assess the current level of safety of drinking water in the water source.
本发明的工作原理如下:本发明利用观测卫星的遥感数据,从而进一步优化构建水流模型,保证能够快速、方便的实现大范围的地表水源地的监测评价;The working principle of the invention is as follows: the invention utilizes the remote sensing data of the observation satellite to further optimize the construction of the water flow model, and ensures that the monitoring and evaluation of a wide range of surface water sources can be realized quickly and conveniently;
根据水源地的生态系统稳定度、生态系统损失度和风险源危险度对各项水源地水质要素进行评估考虑各指标,可以得到水源的总体安全等级,过程机理明确,结合水质迁移分布模型,得到的监测结果也具有空间性和动态性的优点;
According to the ecosystem stability, ecosystem loss and risk source risk of the water source, the water quality elements of each water source are evaluated. Considering the indicators, the overall safety level of the water source can be obtained, and the process mechanism is clear. The monitoring results also have the advantages of space and dynamics;
根据气象环境和地质条件预设水源地水质迁移分布模型,提高水源地水质安全预警的主动性,便于水源地的管理和对污染情况的预判。According to the meteorological environment and geological conditions, the water source migration distribution model of the water source is preset, and the initiative of the water source safety warning is improved, which facilitates the management of the water source and the pre-judgment of the pollution situation.
以上所述仅为本发明的实施例,并非因此限制本发明的专利范围,凡是利用本发明说明书所作的等效结构变换,或直接或间接运用在其他相关的技术领域,均同理包括在本发明的专利保护范围内。
The above is only the embodiment of the present invention, and thus does not limit the scope of the patent of the present invention. Any equivalent structural transformation made by the specification of the present invention, or directly or indirectly applied to other related technical fields, is equally included in the present invention. Within the scope of patent protection of the invention.
Claims (7)
- 一种水源地水质监测方法,其特征在于:包括以下步骤:A water source monitoring method for water source, characterized in that the method comprises the following steps:步骤一:确认目标水源地,利用观测卫星的遥感数据,构建水流模型;Step 1: Confirm the target water source and use the remote sensing data of the observation satellite to construct a water flow model;步骤二:根据水源地的生态系统稳定度、生态系统损失度和风险源危险度对各项水源地水质要素进行评估;Step 2: Evaluate the water quality elements of each water source according to the ecosystem stability, ecosystem loss and risk source risk of the water source;步骤三:根据水流模型基于模糊数学方法对水源地的水质进行整体的安全等级评估;Step 3: According to the water flow model, based on the fuzzy mathematical method, the overall safety level assessment of the water quality of the water source is performed;步骤四:根据当地的气象环境和地质条件预设水源地水质迁移分布模型;Step 4: Predict the water quality migration distribution model of the water source according to the local meteorological environment and geological conditions;步骤五:利用水源地水质迁移分布模型建立预警机制和应急机制。Step 5: Establish an early warning mechanism and an emergency mechanism by using the water source migration distribution model of the water source.
- 根据权利要求1所述的一种水源地水质监测方法,其特征在于:所述步骤二中的所述生态系统稳定度包括地质土壤要素、地貌植被要素、生态群体结构、生态恢复能力要素和人为因素。The method for monitoring water quality in a water source according to claim 1, wherein the ecosystem stability in the second step comprises geological soil elements, geomorphic vegetation elements, ecological group structure, ecological restoration capability elements, and artificial factors. factor.
- 根据权利要求1所述的一种水源地水质监测方法,其特征在于:所述步骤二中的所述风险源危险度包括土壤沙化要素、水土流失要素、污染源排放要素、自然灾害要素和干旱缺水要素。The method for monitoring water quality in a water source according to claim 1, wherein the risk source risk in the second step comprises soil desertification elements, soil erosion factors, pollution source emission factors, natural disaster elements, and drought deficiency. Water element.
- 根据权利要求1所述的一种水源地水质监测方法,其特征在于:在所述步骤二中的所述生态系统损失度包括饮用水损失度要素和水利设施要素。The water quality monitoring method for a water source according to claim 1, wherein the ecosystem loss degree in the second step comprises a drinking water loss factor and a water conservancy facility element.
- 根据权利要求2所述的水源地水质监测方法,其特征在于:所述人为因素包括过度垦殖土地要素、过度放牧要素和过度采药要素。The water source water quality monitoring method according to claim 2, wherein the human factors include excessively cultivated land elements, overgrazing elements, and over-harvest elements.
- 根据权利要求1所述的一种水源地水质监测方法,其特征在于:在所述步骤一的利用观测卫星的遥感数据之前,要对观测卫星的遥感数据进行辐射定标、几何纠正和纠正预处理,从而得到地表反射的遥感图像。The method for monitoring water quality of a water source according to claim 1, characterized in that before the remote sensing data of the observation satellite is used in the first step, the radiometric calibration, geometric correction and correction of the remote sensing data of the observation satellite are performed. Processing to obtain a remote sensing image of the surface reflection.
- 根据权利要求4所述的一种水源地水质监测方法,其特征在于:所述饮用水损失度要素的检测通过地面统计数据,结合供水能力评价模型,计算水体的可供水量以及需求水量的比例,确认水源地当前的人口的需求量,计算水源地当前的供水能力,评估水源地当前饮用水的安全等级。 The water quality monitoring method for a water source according to claim 4, wherein the detection of the drinking water loss factor is calculated by using ground statistics and a water supply capacity evaluation model to calculate the water supply amount and the proportion of the required water volume. To confirm the current population demand of the water source, calculate the current water supply capacity of the water source, and assess the current level of safety of the drinking water source.
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CN110930042A (en) * | 2019-11-29 | 2020-03-27 | 西京学院 | Ocean water quality data online analysis and evaluation method based on DS evidence theory |
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