|
|
|
|
|
|
| MC Simulation of Detection Conditions for EDXRF Analysis of Cd
Element in Wastewater Solution |
| LIAO Xian-li1, 2, LAI Wan-chang1*, MA Shu-hao3, TANG Lin2 |
1. College of Nuclear Technology and Automation Engineering, Chengdu University of Technology, Chengdu 610059, China
2. School of Electronic Information and Electrical Engineering, Chengdu University, Chengdu 610106, China
3. Institute of Minimg Engineering, Bgrimm Technology Group, Beijing 102600, China
|
|
|
|
|
Abstract Industrial wastewater discharge is an important factor causing heavy metal element Cd pollution in water systems. Improper discharge may cause serious environmental pollution. Long-term consumption of crops or aquatic organisms in Cd-contaminated environments will cause various diseases and cause serious harm to the body. Therefore, timely detection of the heavy metal element Cd content is very important for treating and discharging industrial wastewater.Compared with traditional detection methods, energy-dispersive X-ray fluorescence (EDXRF) analysis has the advantages of fast speed, no damage to samples, simple operation, and small instrument size. It is more suitable for application in industrial wastewater treatment sites to detect heavy metal elements in industrial wastewater rapidly. Detection provides a basis for the treatment of industrial wastewater. This article conducts research on factors affecting the on-site rapid detection of Cd element content in industrial wastewater using the EDXRF method. The detection object is untreated flowing industrial wastewater. In order not to affect the process flow, the wastewater sample will flow through a section of the processingpipeline, and the EDXRF detection device will be installed. Outside the processing pipeline, this paper deduces the mathematical model of X-ray fluorescence analysis when the pipeline is square and the X-ray source and detector are vertically located on two adjacent planes of the square pipeline. The simulation analyzes different pipeline geometric parameters and “source-sample” - Explore the influence of the geometric position of the element to be measured on the characteristic X-ray irradiation rate of Cd, verify the accuracy of the theoretical analysis through Monte Carlo method simulation, and obtain the optimal excitation-detection device and its optimized parameters for the square pipe sample.This article conducts MATLAB simulation research based on the established mathematical model. The industrial wastewater solution is set to have a Cd element concentration of 100 000 μg·mL-1, the medium is an HNO3 solution with a concentration of 1.09 mol·L-1, and the incident light ray energy is set to 40 keV, which is brought into parameter calculation, the effects of pipe wall material, pipe wall thickness, detector height, and horizontal distance of the X-ray source on the changing trend of the characteristic X-ray intensity of the element Cd in the standard sample were obtained. At the same time, a Monte Carlo model was established to simulate and study the source outlet ofthe sample. The simulation study was conducted to investigate the influence of the horizontal distance from the source outlet to the sample side, collimator diameter, “source-sample” distance, “sample-detector” distance, detector height, pipe wall thickness, and pipe wall material on the net peak area and peak-to-background ratio of the Cd characteristic peak in the sample. It is found that the pipe wall thickness should be as thin as possible under allowable process conditions, and the commonly used pipe material is better to be polypropylene acid ester plastic. The “sample-detector” distance is 1 mm. The “source-sample” distance and detector height should be as small as possible under objective conditions, such as the device's geometric size and the device's fixing conditions. When the horizontal distance from the source outlet to the sample size is 2.8 mm and the collimator diameter is 2 mm, the peak-to-background ratio and net peak area of the Cd characteristic peak will reach an optimal value.
|
|
Received: 2023-12-12
Accepted: 2024-07-01
|
|
|
|
Corresponding Authors:
LAI Wan-chang
E-mail: Lwchang@cdut.edu.cn
|
|
[1] Tholkappian M, Ravisankar R, Chandrasekaran A, et al. Toxicology Reports, 2018, 5: 173.
[2] ZHANG Qian, ZENG Jing, PENG Qiong(张 倩, 曾 静, 彭 琼). China Metal Bulletin(中国金属通报), 2022,(2): 144.
[3] Dal'nova O A, Bebeshko G I, Es'kina V V, et al. Inorganic Materials, 2018, 54(14): 1397.
[4] QIN Xing-xiu(秦兴秀). Chinese Journal of Analysis Laboratory(分析试验室), 2021, 40(11): 1332.
[5] LI Nan, LIU Jian-bao, DUAN Xian-zhe, et al(李 南, 刘见宝, 段先哲, 等). Modern Chemical Industry(现代化工), 2016, 36(4): 182.
[6] TAN Sheng, LI Yong-bin, QIN Zhi(覃 晟, 李勇宾, 覃 智). Light Industry Science and Technology(轻工科技), 2016, 32(8): 91.
[7] Ferreira V J, Lemos V A, Teixeira L S G. Teixeira. Journal of Food Composition and Analysis, 2023, 117: 105098.
[8] Meira L A, Almeida J S, Dias F D S, et al. Microchemical Journal, 2018, 142: 144.
[9] WU Shi-hao, SONG Xiang-rui, ZHAO Peng, et al(吴世昊, 宋祥瑞, 赵 鹏, 等). Chinese Journal of Analysis Laboratory(分析试验室), 2023, 42(7): 878.
[10] Wang J, Mao M, Liu K, et al. Physical Testing and Chemical Analysis Part B: Chemical Analysis, 2016, 52(11): 1282.
[11] Almeida J S, Meira L A, Oliveira M S, et al. X-Ray Spectrometry, 2021, 50(1): 2.
[12] SANG Xiao-xia, MA Jiang-yuan, WEN Dan-hua, et al(桑晓霞,马江媛,温丹华,等). Science and Technology of Food Industry(食品工业科技), 2020, 41(8): 268. |
| [1] |
LIU Wen-bo, LI Han, XU Yuan-cong, LIU Meng-dong, WANG Hui-qin, LIN Tai-feng, ZHENG Da-wei, ZHANG Ping*. Rapid Detection of Bacterial Conjunctivitis Pathogens Using SERS@Au Microarray Chip[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(02): 476-482. |
| [2] |
ZHANG Chao1, 2, 3, WU Xuan1, 3, YANG Ke-ming4*, QI Fan-yu1, 3, XIA Tian5. Exploration of Spectral Characteristics of Crop Leaves Under Cu2+ Pollution[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(01): 264-271. |
| [3] |
WANG Yi-fei1, WANG Xiao-dong1, Zakhar Maletskyi2, WANG Sha-sha1, MA Ji-ping1*. Determination of Two Quinolone Antibiotics in Environmental Water Samples Using Fluorescence Spectrum Coupled With Support Vector
Machine Regression[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(12): 3576-3582. |
| [4] |
WANG De-ying1, 2, SHENG Wan-li3, ZOU Ming-qiang1, PEI Jia-huan1, 2, LUO Yun-jing2, QI Xiao-hua1*. Research Progress of Detection Based on Hydrogel Surface Enhanced
Raman Spectroscopy (SERS) Substrate[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(10): 2701-2708. |
| [5] |
ZHOU Lei-jinyu1, ZHOU Li-na1*, CHEN Li-mei1, KONG Li-juan1, QIAO Jian-lei2, LI Ming-tang3. Visible/Near Infrared Spectroscopic Modeling for Cadmium
Contaminated Lettuce[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(10): 2805-2811. |
| [6] |
JIANG Yu-heng1, YAN Bo1, ZHUANG Qing-yuan1, WANG Ai-ping1, CAO Shuang1, TIAN An-hong1, 2, FU Cheng-biao1*. Quantitative Inversion Model of Soil Heavy Metals Zn and Ni Based on Fractional Order Derivative[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(10): 2850-2857. |
| [7] |
SHI Chuan-qi1, LI Yan2, HU Yu3, MENG Ling-bo1, JIN Liang2, YU Shao-peng1*. Fluorescence Spectral Characteristics of Forest Soil Dissolved Organic Matter and Its Correlation With Heavy Metal[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(10): 2884-2889. |
| [8] |
NI Xiao-fang1, 3, ZHANG Chang-bo1, 2, 3*, TANG Xiao-yong2*. Pattern Recognition-Based X-Ray Fluorescence Spectroscopy for Rapid Detection of Heavy Metals in Soil[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(09): 2692-2700. |
| [9] |
LÜ Shu-bin1, 2, YANG Wan-qi1, 2, LI Fu-sheng1, 2*. Quantitative Analysis of Lead and Cadmium Heavy Metal Elements in Soil Based on Principal Component Analysis and Broad Learning System[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(07): 1852-1857. |
| [10] |
WU Yan-hua1, ZHAO Heng-qian1, 2*, MAO Ji-hua1, JIN Qian3, 4, WANG Xue-fei3, 4, LI Mei-yu1. Study on Hyperspectral Inversion Model of Soil Heavy Metals in Typical Lead-Zinc Mining Areas[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(06): 1740-1750. |
| [11] |
BAI Zong-fan1, HAN Ling1*, JIANG Xu-hai1, WU Chun-lin2. Effect of Differential Spectral Transformation on Soil Heavy
Metal Content Inversion Accuracy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(05): 1449-1456. |
| [12] |
NING Jing1, 2, ZOU Bin1, 2*, TU Yu-long1, 2, ZHANG Xia3, WANG Yu-long1, 2, TIAN Rong-cai1, 2. Evaluation of Soil As Concentration Estimation Method Based on Spectral Indices[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(05): 1472-1481. |
| [13] |
LIU Zong-yi1, 2, ZHANG Cai-hong1, 2, JIANG Jian-kang1, 2, SHEN Bin-guo3, DING Yan-fei1, 2, ZHANG Lei-lei1, 2*, ZHU Cheng1, 2*. Rapid Determination of Total Flavonoids in Dendrobium Officinale Based on Raman Spectroscopy and CNN-LSTM Deep Learning Method[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(04): 1018-1024. |
| [14] |
YANG Wan-qi1, 2, LI Zhi-qi1, 3, LI Fu-sheng1, 2*, LÜ Shu-bin1, 2, FAN Jia-jing1, 2. A Combined CARS and 1D-CNN Method for the Analysis of Heavy Metals Exceedances in Soil by XRF Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(03): 670-674. |
| [15] |
LIANG Ye-heng1, DENG Ru-ru1, 2*, LIANG Yu-jie1, LIU Yong-ming3, WU Yi4, YUAN Yu-heng5, AI Xian-jun6. Spectral Characteristics of Sediment Reflectance Under the Background of Heavy Metal Polluted Water and Analysis of Its Contribution to
Water-Leaving Reflectance[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 111-117. |
|
|
|
|
