光催化优化海水生物降解性的实验与计算分析

IF 0.6 Q3 ENGINEERING, MULTIDISCIPLINARY

IIUM Engineering Journal Pub Date : 2023-07-04 DOI:10.31436/iiumej.v24i2.2650

M. Nayeemuddin, Puganeshwary Palaniandya, F. Shaik, Hiren K. Mewada

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引用次数: 0

摘要

海水污染是一个重大的全球性环境问题。人们使用了各种技术和方法来去除海水中的污染物。本实验研究利用太阳能光催化降解海水中存在的污染物，其中使用了TiO2和ZnO的组合。通过总有机碳(TOC)、化学需氧量(COD)、生物需氧量(BOD)和生物可降解性(BOD/COD)的去除率来评估催化剂用量、pH和反应时间的影响。生物可降解性对于去除海水中的污染物至关重要，起着至关重要的作用。生物可降解性越高，处理过程越有效。实验结果表明，TOC=59.80%， COD=75.20%， BOD=23.94%，生物可降解性=0.055。为了建模、优化和评估参数的影响，使用了基于Box Behnken设计的Design Expert (RSM-BBD)和基于MATLAB自适应神经模糊推理系统(ANFIS)的预测模型工具。RSM-BBD模型的决定系数R2为0.977,ANFIS模型的决定系数R2为0.99。根据RSM-BBD设计，最大百分比污染物消除效率为TOC=55.4, COD=73.4, BOD=23.70%， BOD/COD=0.054，而对于ANFIS模型，最大百分比污染物消除效率为TOC=59.4, COD=75.4, BOD=24.1%， BOD/COD=0.055。结果表明，ANFIS模型在工艺优化方面优于RSM-BBD模型。摘要:彭塞马兰空气质量指数、空气质量指数、空气质量指数、空气质量指数、空气质量指数。Pelbagai技术dan kaedah telah digunakan bagi menyingkirkan penemaran yang dijumpai dalam air laut。Kajian的实验结果表明，二氧化钛和氧化锌在空气中的降解作用是很重要的。Kesan dos pemangkin, pH, dan tempoh reaksi dipantau menggunakan peratus keecekapan penyingkiran jumlah碳有机(TOC)， keperluan kimia oksigen (COD)， keperluan biologioksigen (BOD)， dan kebolehderacasian (BOD/COD)。keboleh。他说:“我是说，我是说，我是说，我是说，我是说。”实验结果表明:水体TOC=59.80%， COD=75.20%， BOD=23.94%，生物降解率=0.055。Bagi mengkaji kesan参数terhadap模型，kadar优化，dan memantau keberkesanan参数，kaedah Pakar Reka Bentuk paada rekaan Kotak Behnken (RSM-BBD) dan模型ramalan berdasarkan系统pengaruh menggunakan系统MATLAB iiiiiiens Neural-Fuzi Boleh Suai (ANFIS) digunakan。Pekali penentu R2 terhasil模型0.977模型RSM-BBD和0.99模型ANFIS。Berdasarkan reka bentuk rms - bbd, peratus maksimum keberkesanan penyingkiran bahan cemar dijumpai pada TOC=55.4, COD=73.4, BOD=23.70%， dan BOD/COD=0.054, tetapi bagi模型ANFIS, TOC=59.4, COD=75.4, BOD=24.1%， dan BOD/COD=0.055。模型RSM-BBD dalam过程是最优的。

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EXPERIMENTAL AND COMPUTATIONAL ANALYSIS FOR OPTIMIZATION OF SEAWATER BIODEGRADABILITY USING PHOTO CATALYSIS

Seawater pollution is a significant global environmental problem. Various technologies and methods have been used to remove the contaminants found in saltwater. This experimental study investigates the degradation of contaminants present in seawater using solar photocatalysis, where a combination of TiO2 and ZnO was used. The effects of catalyst dosage, pH, and reaction duration were assessed using percentage removal efficiencies of total organic carbon (TOC), chemical oxygen demand (COD), biological oxygen demand (BOD), and biodegradability (BOD/COD). Biodegradability is essential for removing pollutants from saltwater and plays a vital role. The higher the biodegradability, the more efficient the treatment procedure will be. The most effective percentage reduction rates from the experimental data obtained were TOC=59.80%, COD=75.20%, BOD=23.94%, and biodegradability=0.055. For modeling, optimizing, and assessing the effects of parameters, the Design Expert based on Box Behnken design (RSM-BBD) and a predictive model based on the MATLAB adaptive neuro-fuzzy inference system (ANFIS) tools were used. The coefficient of determination R2 was found to be 0.977 for the RSM-BBD model and 0.99 for the ANFIS model. According to the RSM-BBD design, the maximum percentage pollutant elimination efficiencies were found to be TOC=55.4, COD=73.4, BOD=23.70%, and BOD/COD=0.054, but for the ANFIS model, they were TOC=59.4, COD=75.4, BOD=24.1%, and BOD/COD=0.055. It was discovered that the ANFIS model outperformed RSM-BBD in process optimization. ABSTRAK: : Pencemaran air laut adalah masalah alam sekitar global yang ketara. Pelbagai teknologi dan kaedah telah digunakan bagi menyingkirkan pencemaran yang dijumpai dalam air laut. Kajian eksperimen ini menilai degradasi pencemaran yang hadir dalam air laut menggunakan fotopemangkin, di mana kombinasi TiO2 dan ZnO digunakan. Kesan dos pemangkin, pH, dan tempoh reaksi dipantau menggunakan peratus kecekapan penyingkiran jumlah karbon organik (TOC), keperluan kimia oksigen (COD), keperluan biologi oksigen (BOD), dan kebolehdegradasian (BOD/COD). Kebolehdegradasian adalah sangat penting bagi menyingkirkan bahan cemar dari air laut dan berperanan penting. Semakin tinggi kebolehdegradasian, semakin cekap prosedur rawatan. Peratus kadar pengurangan yang paling berkesan daripada data eksperimen adalah didapati pada TOC=59.80%, COD=75.20%, BOD=23.94%, dan biodegradasi=0.055. Bagi mengkaji kesan parameter terhadap model, kadar optimum, dan memantau keberkesanan parameter, kaedah Pakar Reka Bentuk pada rekaan Kotak Behnken (RSM-BBD) dan model ramalan berdasarkan sistem pengaruh menggunakan sistem MATLAB iaitu Inferens Neural-Fuzi Boleh Suai (ANFIS) digunakan. Pekali penentu R2 terhasil pada 0.977 bagi model RSM-BBD dan 0.99 pada model ANFIS. Berdasarkan reka bentuk RSM-BBD, peratus maksimum keberkesanan penyingkiran bahan cemar dijumpai pada TOC=55.4, COD=73.4, BOD=23.70%, dan BOD/COD=0.054, tetapi bagi model ANFIS, TOC=59.4, COD=75.4, BOD=24.1%, dan BOD/COD=0.055. Model ANFIS adalah lebih berkesan daripada model RSM-BBD dalam proses pengoptimuman.

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来源期刊

IIUM Engineering Journal ENGINEERING, MULTIDISCIPLINARY-

CiteScore

2.10

自引率

20.00%

发文量

审稿时长

40 weeks

期刊介绍： The IIUM Engineering Journal, published biannually (June and December), is a peer-reviewed open-access journal of the Faculty of Engineering, International Islamic University Malaysia (IIUM). The IIUM Engineering Journal publishes original research findings as regular papers, review papers (by invitation). The Journal provides a platform for Engineers, Researchers, Academicians, and Practitioners who are highly motivated in contributing to the Engineering disciplines, and Applied Sciences. It also welcomes contributions that address solutions to the specific challenges of the developing world, and address science and technology issues from an Islamic and multidisciplinary perspective. Subject areas suitable for publication are as follows: -Chemical and Biotechnology Engineering -Civil and Environmental Engineering -Computer Science and Information Technology -Electrical, Computer, and Communications Engineering -Engineering Mathematics and Applied Science -Materials and Manufacturing Engineering -Mechanical and Aerospace Engineering -Mechatronics and Automation Engineering