Sustainable and water engineering : theory and practice /

Ensuring safe and plentiful supplies of potable water (both now and for future generations) and developing sustainable treatment processes for wastewater are among the world's greatest engineering challenges. However, sustainability requires investment of money, time and knowledge. Some parts o...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Chandrappa, Ramesha
Otros Autores: Das, D. B. (Diganta Bhusan), 1974-
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Chichester, West Sussex, UK : Wiley, 2014.
Temas:
Water quality.
Water > Purification.
Water-supply > Management.
Hydraulic engineering.
Water Purification
Eau > Qualité.
Eau > Épuration.
Eau > Approvisionnement > Gestion.
Technologie hydraulique.
hydraulic engineering.
TECHNOLOGY & ENGINEERING > Environmental > General.
Hydraulic engineering
Water > Purification
Water quality
Water-supply > Management
Acceso en línea:Texto completo (Requiere registro previo con correo institucional)
Tabla de Contenidos:
  • Sustainable Water Engineering; Contents; Preface; Abbreviations; Glossary; 1 Water Crisis; 1.1 Water Resource Issues; 1.1.1 Water Footprint; 1.2 Climate Change and Its Influence on Global Water Resources; 1.3 Protection and Enhancement of Natural Watershed and Aquifer Environments; 1.4 Water Engineering for Sustainable Coastal and Offshore Environments; 1.5 Endangering World Peace and Security; 1.6 Awareness among Decision Makers and the Public across the World; 1.7 Criteria for Sustainable Water Management; 1.8 Water Scarcity and Millennium Development Goals.
  • 1.9 Lack of Access to Clean Drinking Water and Sanitation1.10 Fragmentation of Water Management; 1.11 Economics and Financial Aspects; 1.11.1 Water Treatment and Distribution; 1.11.2 Wastewater Treatment, Collection and Disposal; 1.12 Legal Aspects; References; 2 Requirements for the Sustainability of Water Systems; 2.1 History of Water Distribution and Wastewater Collection; 2.2 Integrated Water Management; 2.3 Sewerage Treatment and Urban Pollution Management; 2.4 Conventional Water Supply; 2.4.1 Features; 2.4.2 Capacity and Pressure Requirements.
  • 2.4.3 Design and Hydraulic Analysis of Distribution System2.4.4 Unsustainable Characteristics; 2.4.5 Sustainable Approach; 2.5 Conventional Wastewater Collection Systems; 2.5.1 Features; 2.5.2 Unsustainable Characteristics; 2.5.3 Sustainable Approach; References; 3 Water Quality Issues; 3.1 Water-Related Diseases; 3.1.1 Transmission Vectors; 3.1.2 Field Testing and Monitoring; 3.1.3 Village-Level Monitoring; 3.2 Selection Options for Water Supply Source; 3.2.1 Spring Capping; 3.2.2 Simple Tube Wells; 3.2.3 Hand Pumps; 3.2.4 Rainwater Harvesting; 3.2.5 Fog and Dew Harvesting.
  • 3.2.6 Snow Harvesting3.3 On-Site Sanitation; 3.3.1 Latrines; 3.3.2 Septic Tanks; 3.3.3 Aqua Privies; 3.3.4 Oxidation Pond Treatment Systems; 3.3.5 Storm Drainage; 3.4 Water Quality Characteristics of Potable Drinking Water and Wastewater Effluents; 3.4.1 Physical Parameters; 3.4.2 Chemical Parameters; 3.4.3 Solids in Water; 3.4.4 Biological Parameters; 3.5 Standards and Consents; 3.5.1 Potable Water Standards; 3.5.2 Wastewater Effluent Standards; 3.6 Kinetics of Biochemical Oxygen Demand; 3.7 Water Management for Wildlife Conservation; 3.8 Water-Quality Deterioration; References.
  • 4 Fundamentals of Treatment and Process Design, and Sustainability4.1 History of Water and Wastewater Treatment Regulatory Issues across the World; 4.1.1 Low-Tech versus Hi-Tech; 4.1.2 Low Cost versus High Cost; 4.2 Design Principles for Sustainable Treatment Systems; 4.2.1 Low Carbon; 4.2.2 Low Energy; 4.2.3 Low Chemical Use; 4.2.4 Modelling of Treatment Processes to Attain Sustainability; 4.2.5 Operation, Management, Financial, Socio-Economic Aspect; 4.3 Preliminary and Primary Treatment; 4.3.1 Screening; 4.3.2 Coarse-Solid Reduction; 4.3.3 Grease Removal Chamber; 4.3.4 Flow Equalization.

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