Cover image for Industrial wastewater treatment, recycling, and reuse
Title:
Industrial wastewater treatment, recycling, and reuse
Conference Author:
Publication Information:
Waltham, MA. : Butterworth-Heinemann, 2014
Physical Description:
xvi, 560 pages : illustrations (black and white) ; 24 cm.
ISBN:
9780080999685
General Note:
"This book essentially originated from the Indus Water workshop."--Preface.

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PSZ JB 30000010329163 TD745 I53 2014 Open Access Book Book
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Summary

Summary

Industrial Wastewater Treatment, Recycling and Reuse is an accessible reference to assist you when handling wastewater treatment and recycling. It features an instructive compilation of methodologies, including advanced physico-chemical methods and biological methods of treatment. It focuses on recent industry practices and preferences, along with newer methodologies for energy generation through waste.

The book is based on a workshop run by the Indus MAGIC program of CSIR, India. It covers advanced processes in industrial wastewater treatment, applications, and feasibility analysis, and explores the process intensification approach as well as implications for industrial applications. Techno-economic feasibility evaluation is addressed, along with a comparison of different approaches illustrated by specific case studies.

Industrial Wastewater Treatment, Recycling and Reuse introduces you to the subject with specific reference to problems currently being experienced in different industry sectors, including the petroleum industry, the fine chemical industry, and the specialty chemicals manufacturing sector.


Author Notes

Vivek V. Ranade leads the Chemical Engineering and Process Development division of the CSIR-National Chemical Laboratory, Pune, India, where he has worked since 1990. His research interests center on process intensification, reactor engineering and modeling of industrial flow processes.
Vinay M. Bhandari is Senior Principal Scientist at the CSIR-National Chemical Laboratory, Pune, India. His research interests include: advanced separation processes; catalytic reaction engineering; applied research in nanomaterials; process development; bioseparations; and wastewater treatment and environmental pollution control.


Table of Contents

Vivek V. Ranade and Vinay M. BhandariVinay M. Bhandari and Vivek V. RanadeVirendra K. Saharan and Dipak V. Pinjari and Parag R. Gogate and Aniruddha B. PanditHaresh BhutaJohannes Leonhauser and Jyoti Pawar and Udo BirkenbeulS. Venkata MohanR. Saravanane and Vivek V. Ranade and Vinay M. Bhandari and A. Seshagiri RaoLaxmi Gayatri Sorokhaibam and M. AhmaruzzamanNilesh Tantak and Nitin Chandan and Pavan RainaJanardhan Bornare and V. Kalyanraman and R. R. SondeManish Singh and Ling Liang and Atanu Basu and Michael A. Belsan and G. Anders Hallsby and William H. Tripp MorrisJignasa Panigrahi and Sharad C. SharmaShrikant AhirraoVivek V. Ranade and Vinay M. Bhandari
Prefacep. xi
Contributorsp. xv
1 Industrial Wastewater Treatment, Recycling, and Reuse: An Overviewp. 1
1.1 Water Usage in Industryp. 1
1.2 Characterization of Industrial Wastewaterp. 13
1.3 Strategy for Wastewater Managementp. 18
1.4 Separation Processes and Conventional Methods of Wastewater Treatmentp. 23
1.5 Industry Sectors Where Wastewater Treatment, Recycling, and Reuse Can Have a High Impactp. 47
1.6 Industrial Wastewater Treatment Process Engineeringp. 58
1.7 Advanced Modeling for Water Treatmentp. 67
1.8 Cost of Wastewater Treatment and Possible Value Additionp. 69
1.9 Summaryp. 74
Acronymsp. 76
Referencesp. 76
2 Advanced Physico-Chemical Methods of Treatment for Industrial Wastewatersp. 81
2.1 Introductionp. 81
2.2 Advanced Coagulation Processesp. 86
2.3 Advanced Adsorption and Ion Exchange Processesp. 96
2.4 Other Advanced Physico-Chemical Methods of Treatmentp. 114
2.5 Cavitationp. 120
2.6 Cost Considerationsp. 130
2.7 Summaryp. 133
Nomenclaturep. 133
Referencesp. 134
3 Advanced Oxidation Technologies for Wastewater Treatment: An Overviewp. 141
3.1 Introductionp. 141
3.2 Cavitationp. 142
3.3 Fenton Chemistryp. 158
3.4 Photocatalytic Oxidationp. 161
3.5 Hybrid Methodsp. 166
3.6 Case Studiesp. 178
3.7 Summaryp. 184
Referencesp. 186
4 Advanced Treatment Technology and Strategy for Water and Wastewater Managementp. 193
4.1 Introductionp. 193
4.2 Advanced Oxidation Treatmentp. 195
4.3 Fenton Process: Advanced Oxidation Technologiesp. 196
4.4 Electro-Fenton Advanced Oxidation Treatmentp. 199
4.5 Fenton Catalytic Reactor Advanced Oxidation Treatmentp. 202
4.6 Electrochemical Advanced Oxidation Treatment with BDDp. 206
4.7 Implementation of Advanced Oxidation Technologiesp. 207
4.8 Summary and Conclusionsp. 212
Referencesp. 213
5 Novel Technologies for the Elimination of Pollutants and Hazardous Substances in the Chemical and Pharmaceutical Industriesp. 215
5.1 Introductionp. 215
5.2 The Bayer Loprox Processp. 217
5.3 Bayer Tower Biologyp. 223
5.4 Summary of Loprox and Tower Biologyp. 232
Referencesp. 234
6 Reorienting Waste Remediation Towards Harnessing Bioenergy: A Paradigm Shiftp. 235
6.1 Introductionp. 235
6.2 Anaerobic Fermentationp. 236
6.3 Biohydrogen Production from Waste Remediationp. 238
6.4 MFCs for Harvesting Bioelectricity from Waste Remediationp. 248
6.5 Bioplasticsp. 257
6.6 Microalgae Cultivation Towards Biodiesel Productionp. 260
6.7 Summaryp. 265
Acknowledgmentsp. 265
Referencesp. 265
Further Readingp. 281
7 Urban Wastewater Treatment for Recycling and Reuse in Industrial Applications: Indian Scenariop. 283
7.1 Introductionp. 283
7.2 Urban Water Sector: Indian Scenariop. 284
7.3 Urban Sewage Treatment Optionsp. 300
7.4 Industrial Water Production and Reuse/Urban-Industry Joint Venturep. 306
7.5 Urban-Industrial Water Sustainability: 2030p. 314
7.6 Summary and Path Forwardp. 319
Referencesp. 320
8 Phenolic Wastewater Treatment: Development and Applications of New Adsorbent Materialsp. 323
8.1 Introductionp. 323
8.2 Newer Adsorbents and the Potential for Their Application in Phenolic Wastewater Treatmentp. 328
8.3 Adsorbent Characterizationp. 334
8.4 Single-Solute Adsorption Studies: Performance and Evalutionp. 347
8.5 Adsorption Mechanismp. 352
8.6 Results from Batch Adsorptionp. 354
8.7 Multicomponent Adsorption Studiesp. 356
8.8 Desorption Studiesp. 360
8.9 Disposal and Cost Analysisp. 362
8.10 Summaryp. 362
Nomenclaturep. 363
Subscriptsp. 364
Referencesp. 364
Further Readingp. 368
9 An Introduction to Biological Treatment and Successful Application of the Aqua EMBR System in Treating Effluent Generated from a Chemical Manufacturing Unit: A Case Studyp. 369
9.1 Introductionp. 369
9.2 Secondary Wastewater Treatmentp. 370
9.3 Aerobic Treatment Principlep. 372
9.4 Different Types of Aerobic Treatment Technologiesp. 374
9.5 Membrane Bioreactor Technologyp. 377
9.6 Aquatech MBR Systemp. 381
9.7 Case Studyp. 386
9.8 Typical Characteristics of Polymer-Based Chemical Manufacturing Industrial Wastewaterp. 387
9.9 Technology Selectionp. 388
9.10 Scheme and Process Descriptionp. 389
9.11 Results and Discussionp. 391
9.12 Application of Submerged MBRp. 395
9.13 Summaryp. 397
Referencesp. 397
10 Application of Anaerobic Membrane Bioreactor (AnMBR) for Low-Strength Wastewater Treatment and Energy Generationp. 399
10.1 Introductionp. 399
10.2 Existing Technologies for the Treatment of Sewage in Indiap. 403
10.3 Introduction to the AnMBRp. 407
10.4 Development of AnMBR and Evaluation Studies Undertakenp. 412
10.5 Summary and Conclusionsp. 430
10.6 Future Scope and Research Needsp. 432
Acknowledgmentsp. 432
Referencesp. 433
Further Readingp. 434
11 3D Trasarâ„¢ Technologies for Reliable Wastewater Recycling and Reusep. 435
11.1 Introductionp. 435
11.2 3D TRASAR Technology for Sugarp. 437
11.3 3D TRASAR Technology for Membranesp. 448
11.4 Summaryp. 461
Acknowledgmentp. 462
Referencesp. 462
12 Sumulation, Control, and Optimization of Water Systems in Industrial Plantsp. 463
12.1 Introductionp. 463
12.2 Applicability in Various Industriesp. 472
12.3 Technology Applicationp. 478
12.4 Conclusionp. 486
Referencesp. 487
13 Zero Liquid Discharge Solutionsp. 489
13.1 Introductionp. 489
13.2 Zero Liquid Dischargep. 490
13.3 Evaporationp. 492
13.4 Solids Separation Equipmentp. 499
13.5 Case Studiesp. 500
13.6 Summaryp. 519
14 Industrial Wastewater Treatment, Recycling, and Reuse-Past, Present, and Futurep. 521
14.1 Introductionp. 521
14.2 The Pastp. 522
14.3 The Presentp. 523
14.4 The Futurep. 530
Referencesp. 535
Notationsp. 537
Indexp. 543