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| Comparative analysis of different measurement principles of water turbidity |
| LI Hong1,2, BAO Yuhai1, HE Xiubin1 |
1. Institute of Mountain Hazards and Environment, Chinese Academy of Sciences, 610299, Chengdu, China;
2. University of Chinese Academy of Sciences, 100049, Beijing, China |
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Abstract [Background] Turbidity is one of the important indexes of water quality detection in rivers, lakes, and reservoirs. As a common instrument and equipment for water turbidity measurement, the turbidity meter has a wide variety of measurement methods. In the current water quality evaluation work, the applicable conditions and scope of the turbidity meter are often ignored, and the true turbidity of the water body cannot be obtained,This paper summarizes numerous literature, sorts out the advantages and disadvantages of various measurement methods of turbidity, and helps readers to choose turnitacturometer in an appropriate environment.[Methods] In the measurement method of turbidity, the calculation method, remote sensing inversion method, analogy method, turbidification method and photoelectric detection method are obtained. The calculation method calculates the turbidity through the sediment chlorophyll in the water, and the remote sensing inversion method is to reverse the turbidity by using the empirical model. The comparison method is to replace the turbidity. The photoelectric detection method is to obtain the turbidity by judging the light intensity absorbed or reflected by the liquid to be measured. When the turbidity value of the tested solution is >10 000, a desktop laboratory neopidometer can be used to determine the diluted tested liquid.[Results] From the selection of turbidimeter light source, the color, stability, luminescence intensity, measurement of particles and optical system of tungsten halogen lamp and infrared LED are analyzed. The comparison shows that infrared LED has wider applicability. Measurement methods are divided into indirect measurement and direct measurement, indirect method is divided into calculation method, remote sensing inversion method, analogy method. Direct measurement methods include:turbidimetric method, photoelectric detection method. The current commonly used method is photoelectric detection method in direct measurement. According to the optical path principle of photoelectric detection method, incident light can be divided into transmitted light, scattered light and transmitted scattered light, among which the scattered light can be divided into 90° scattering method, rear scattering method, front scattering method, surface scattering method, underwater scattering method, etc. Based on the principle of turbidity measurement, the upper limit of commercially available turbidity meters is 9 999 NTU. When the turbidity of water sample is greater than the upper limit, in order to meet the needs of emergency detection, the bench laboratory turbidity meter (measuring range 0~9 999 NTU) can be used for dilution determination of high turbidity water sample. For different application scenarios, laboratory, on-site online and portable have their own characteristics.[Conclusions] 1) For the turbidimeter's light source, infrared LED stability and optical system are more stable.2) The transmission formula, 90° scattering formula, back scattering formula and surface scattering formula are applicable to water bodies with turbidity >2 000, <2 000, 10~4 000 and <1 000 NTU The transmission scattering type sensitivity is high, but the measurement range is limited3) In different application scenarios, the accuracy of the field is second only to the laboratory; portable accuracy and measurement range are limited.In the present paper summarizes the applicability of turbidity meter in different measuring principles, points out the methods and instruments suitable for turbidity monitoring in different water bodies, and provides reference for water quality monitoring and evaluation.
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Received: 16 November 2022
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| [1] |
奚宏, 张志兰, 史东梅, 等. 三峡库区刘家沟小流域径流泥沙特征及趋势分析[J]. 中国水土保持科学, 2022, 20(4):1. XI Hong, ZHANG Zhilan, SHI Dongmei, et al. Runoff and sediment characteristics and trend analysis of Liujiagou small watershed in the Three Gorges Reservoir Area[J]. Science of Soil and Water Conservation, 2022, 20(4):1.
|
| [2] |
PETUS C, CHUST G, GOHIN F, et al. Estimating turbidity and total suspended matter in the Adour River plume (South Bay of Biscay) using MODIS 250-m imagery[J]. Continental Shelf Research, 2010, 30(5):379.
|
| [3] |
PANIGRAHI S, WIKNER J, PANIGRAHY R C, et al. Variability of nutrients and phytoplankton biomass in a shallow brackish water ecosystem (Chilika Lagoon, India)[J]. Limnology, 2009, 10(2):73.
|
| [4] |
王海军, 王洪铸, 潘保柱, 等. 长江亚热带浅水湖群藻类浊度与非藻类浊度的变异规律[J]. 水生生物学报, 2017, 41(2):414. WANG Haijun, WANG Hongzhu, PAN Baozhu, et al. Variations of algal and non-algal turbidity among the Yangtze subtropical shallow lakes[J]. Acta Hydrobiologica Sinica, 2017, 41(2):414.
|
| [5] |
MOREIRA V, LEBRON Y, DE PAULA E, et al. Recycled reverse osmosis membrane combined with pre-oxidation for improved arsenic removal from high turbidity waters and retrofit of conventional drinking water treatment process[J]. Journal of Cleaner Production, 2021, 312:127859.
|
| [6] |
BRAGA A, FILION Y. Initial stages of particulate iron oxide attachment on drinking water PVC pipes characterized by turbidity data and brightfield microscopy from a full-scale laboratory[J]. Environmental Science:Water Research & Technology, The Royal Society of Chemistry, 2022, 8(6):1195.
|
| [7] |
何嘉莉, 袁耀芬, 周沛良, 等. 自来水厂混凝剂自动精准投加系统建设与运行[J]. 中国给水排水, 2021, 37(18):139. HE Jiali, YUAN Yaofen, ZHOU Peiliang, et al.Construction and operation of automatic and accurate coagulant dosing system in waterworks[J]. China Water & Wastewater, 2021, 37(18):139.
|
| [8] |
CABALLERO I, NAVARRO G. Application of extended full resolution MERIS imagery to assist coastal management of the area adjacent to the Guadalquivir estuary[J]. Progress in Oceanography, 2018, 165:215.
|
| [9] |
XU Xiuquan, FAN Haoming, CHEN Xiaoyu, et al. Estimating low eroded sediment concentrations by turbidity and spectral characteristics based on a laboratory experiment[J].Environmental Monitoring and Assessment 2020, 192(2):1.
|
| [10] |
LAWLER D M, PETTS G E, FOSTER I D L, et al. Turbidity dynamics during spring storm events in an urban headwater river system:the Upper Tame, West Midlands, UK[J]. The Science of the Total Environment, 2006, 360(1):109.
|
| [11] |
MOHD KHAIRI M T, IBRAHIM S, MD YUNUS M A, et al. A review on the design and development of turbidimeter[J]. Sensor Review, 2015, 35(1):98.
|
| [12] |
左辉. 浊度的检测原理及方法[J]. 中国计量, 2012(4):86. ZUO Hui. Turbidity detection principle and method[J]. China Metrology, 2012(4):86.
|
| [13] |
黄旭. 水质分析中的浊度检测探析[J]. 全面腐蚀控制, 2022, 36(1):95. HUANG Xu. Discussion on turbidity detection in water quality analysis[J]. Total Corrosion Control, 2022, 36(1):95.
|
| [14] |
管轶华, 项志强, 郜晚蕾, 等. 一种在线式超低量程浊度高精度测量传感器研制[J]. 无线通信技术, 2022, 31(1):30. GUAN Yihua, XIANG Zhiqiang, GAO Wanlei, et al.Development of an online ultra-low range high-precision turbidity measurement sensor[J]. Wireless Communication Technology, 2022, 31(1):30.
|
| [15] |
KITCHENER B G, WAINWRIGHT J, PARSONS A J. A review of the principles of turbidity measurement[J]. Progress in Physical Geography:Earth and Environment, SAGE Publications Ltd, 2017, 41(5):620.
|
| [16] |
ZHOU Qu, WANG Jianru, TIAN Liqiao, et al. Remotely sensed water turbidity dynamics and its potential driving factors in Wuhan, an urbanizing city of China[J]. Journal of Hydrology, 2021, 593:125893.
|
| [17] |
王志丹. 光学浊度传感器的设计与实现[D]. 南京:南京信息工程大学, 2016:9. WANG Zhidan. Design and Realization of optical turbidity sensor[D]. Nanjing:Nanjing University of Information Science & Technology, 2016:9.
|
| [18] |
兰羽, 张顺星. 一种直射式光电浊度计的设计[J]. 国外电子测量技术, 2013, 32(1):53. LAN Yu, ZHANG Shunxing. Design of a direct-injection photoelectric nephelometer[J]. Foreign Electronic Measurement Technology, 2013, 32(1):53.
|
| [19] |
TRIARDIANTO E, MANSYUR M. Utilization of laser turbidimeter to measure the concentration of starch suspension as a model for measurement of sperm turbidity[J]. KESANS:International Journal of Health and Science, 2022, 1(11):934.
|
| [20] |
SAMPEDRO Ó, SALGUEIRO J R. Turbidimeter and RGB sensor for remote measurements in an aquatic medium[J]. Measurement, 2015, 68:128.
|
| [21] |
水质-浊度的测定浊度计法:HJ 1072-2019[S]. 北京:中国环境出版集团出版,2020:1. Water quality-determination of turbidity turbidimeter method:HJ 1072-2019[S]. Beijing:Published by China Environmental Publishing Group,2020:1.
|
| [22] |
BRIGHT C E, MAGER S M. A national-scale study of spatial variability in the relationship between turbidity and suspended sediment concentration and sediment properties[J]. River Research and Applications, 2020, 36(8):1449.
|
| [23] |
周正, 万茜婷, 龙超. 基于MODIS数据的悬浮物遥感反演研究[J]. 人民长江, 2014, 45(18):95. ZHOU Zheng, WAN Qianting,LONG Chao. Study on remote sensing retrieval of suspended sediment concentration based on MODIS data[J]. Yangtze River, 2014, 45(18):95.
|
| [24] |
许鹏, 杜萍, 申茜, 等. 基于GF-1 WFV影像的浑河悬浮物浓度和浊度遥感反演研究[J]. 沈阳师范大学学报(自然科学版), 2017, 35(2):180 XU Peng, DU Ping, SHEN Qian, et al.Research on remote sensing inversion mode of suspended matter density and turbidity based on GF-1 WFV image data in Hunhe rive[J]. Journal of Shenyang Normal University (Natural Science Edition), 2017, 35(2):180.
|
| [25] |
王震, 乔璐璐, 王云飞. 东中国海表层悬浮体浓度卫星遥感反演研究进展[J]. 沉积学报, 2016, 34(2):292. WANG Zhen, QIAO Lulu, WANG Yunfei. Progress on retrieval models of suspended sediment concentration from satellite images in the Eastern Chinaseas[J]. Acea Sedimentologica Sinica, 2016, 34(2):292.
|
| [26] |
陈聪, 陆庆. 浊度计法测定水中浊度的适用性研究及建议[J]. 化工设计通讯, 2021, 47(3):61. CHEN Cong,Lu Qing. Research and suggestion on the applicability of turbidity meter method to measure turbidity in water[J]. Chemical Engineering Design Communications, 2021, 47(3):61.
|
| [27] |
刘建华, 李平, 张成成, 等. 浊度计法测定工业废水中的悬浮物[J]. 绿色科技, 2015(11):181. LIU Jianhua, LI Ping, ZHANG Chengcheng, et al.Determination of suspended solids in industrial waste water by turbidimetric method[J]. Journal of Green Science and Technology, 2015(11):181.
|
| [28] |
张旭云, 孙宇颖, 邓君萍. 浊度计法测定水样浊度的探讨[J]. 山西建筑, 2010, 36(21):176. ZHANG Xuyun, SUN Yuying, DENG Junping. Discussion on water sample turbidity measurement with turbidimeter method[J]. Shanxi Architecture, 2010, 36(21):176.
|
| [29] |
张文祥, 杨世伦. OBS浊度标定与悬沙浓度误差分析[J]. 海洋技术, 2008, 27(4):5. ZHANG Wenxiang, YANG Shilun. Turbidity calibration of OBS and errors analysis of suspended sediment concentration[J]. Marine Technology, 2008, 27(4):5.
|
| [30] |
张恺, 张玉钧, 殷高方, 等. 综合散射法与透射法测量水浊度的研究[J]. 大气与环境光学学报, 2011, 6(2):100. ZHANG Kai, ZHANG Yujun, YIN Gaofang, et al. Measurement of water turbidity combined with scattering and transmission method[J]. Journal of Atmospheric and Environmental Optics, 2011, 6(2):100.
|
| [31] |
勾晶晶, 李健. 浊度计在悬移质泥沙测验中的误差分析[J]. 长江技术经济, 2020(5):43. GOU Jingjing, LI Jian. Erroranalysis of turbidimeter in suspended sediment test[J]. Technology and Economy of Changjiang, 2020(5):43.
|
| [32] |
JASTRAM J D, ZIPPER C E, ZELAZNY L W, et al. Increasing precision of turbidity-based suspended sediment concentration and load estimates[J]. Journal of Environmental Quality, 2010, 39(4):1306.
|
| [33] |
康亚, 龚丽萍. 浊度测量原理的探讨[J]. 电子测试, 2013(8):245. KANG Ya, GONG Liping. The study of turbidity measurement[J]. Electronic Test, 2013(8):245.
|
| [34] |
BRIGHT C E, MAGER S M, HORTON S L. Predicting suspended sediment concentration from nephelometric turbidity in organic-rich waters[J]. River Research and Applications, 2018, 34(7):640.
|
| [35] |
蔡岳. 散射式红外浊度计[D]. 武汉:华中科技大学,2013:12. CAI Yue. Measurement of water turbidity combined with scattering and transmission meathod[D]. Wuhan:HuaZhong University of Science and Technology, 2013:12.
|
|
|
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