Sustainable industrial design and waste management cradle-to-cradle for sustainable development

Sustainable industrial design and waste management cradle-to-cradle for sustainable development

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Bibliographic Details
Main Author: Haggar, Salah El-
Format: Book
Published: Amsterdam Elsevier Academic Press 2007
Online Access:Click Here to View Status and Holdings.
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Table of Contents:
  • Chapter 1. Current practice and future sustainability
  • 1.1. Introduction
  • 1.2. Waste management
  • 1.3. Treatment
  • 1.4. Incineration
  • 1.5 Landfill.
  • 1.6. Zero pollution and 7Rs rule
  • 1.7. Life cycle analysis and extended producer responsibility
  • 1.8. Cradle-to-cradle concept
  • Chapter 2. Cleaner production
  • 2.1. Introduction
  • 2.2. Promoting cleaner production
  • 2.3. Benefits of cleaner production
  • 2.4. Obstacles to cleaner production and solutions
  • 2.5. Cleaner production techniques
  • 2.6. Cleaner production opportunity assessment
  • 2.7. Cleaner production case studies
  • Chapter 3. Sustainable development and industrial ecology
  • 3.1. Introduction
  • 3.2. Industrial ecology
  • 3.3. Industrial ecology barriers
  • 3.4. Eco-industrial parks
  • 3.5. Recycling economy/circular economy initiatives
  • 3.6. Eco-industrial parks case studies
  • Chapter 4. Sustainable development and environmental reform
  • 4.1. Introduction
  • 4.2. Sustainable development proposed framework
  • 4.3. Sustainable development tools, indicator, and formula
  • 4.4. Sustainable development facilitators
  • 4.5. Environmental reform
  • 4.6. Environmental reform proposed structure
  • 4.7. Mechanisms for environmental impact assessment
  • 4.8. Sustainable development road map
  • Chapter 5. Sustainability of municipal solid waste management
  • 5.1. Introduction
  • 5.2. Transfer stations
  • 5.3. Recycling of waste paper
  • 5.4. Recycling of plastic waste
  • 5.5. Recycling of bones
  • 5.6. Recycling of glass
  • 5.7. Foam glass
  • 5.8. Recycling of aluminum and tin cans
  • 5.9. Recycling of textiles
  • 5.10. Recycling of composite packaging materials
  • 5.11. Recycling of laminated plastics
  • 5.12. Recycling of food waste
  • 5.13. Rejects
  • Chapter 6. Recycling of municipal solid waste rejects
  • 6.1. Introduction
  • 6.2. Reject technologies
  • 6.3. Product development from rejects
  • 6.4. Construction materials and their properties
  • 6.5. Manhole
  • 6.6. Breakwater
  • 6.7. Other products
  • Chapter 7. Sustainability of agricultural and rural waste management
  • 7.1. Introduction
  • 7.2. Main technologies for rural communities
  • 7.3. Animal fodder
  • 7.4. Briquetting
  • 7.5. Biogas
  • 7.6. Composting
  • 7.7. Other applications/technologies
  • 7.8. Integrated complex
  • 7.9. Agricultural and rural waste management case studies
  • Chapter 8. Sustainability of construction and demolition waste management
  • 8.1. Introduction
  • 8.2. Construction waste
  • 8.3. Construction waste management guidelines
  • 8.4. Demolition waste
  • 8.5. Demolition waste management guidelines
  • 8.6. Final remarks
  • 8.7. Construction waste case studies
  • Chapter 9. Sustainability of clinical solid waste management
  • 9.1. Introduction
  • 9.2. Methodology
  • 9.3. Clinical waste management
  • 9.4. Disinfection of clinical wastes
  • 9.5. Current experience of clinical wastes
  • 9.6. Electron beam technology
  • 9.7. Electron beam for sterilization of clinical wastes
  • Chapter 10. Sustainability of industrial waste management
  • 10.1. Introduction
  • 10.2. Cement industry
  • 10.3. Iron and steel industry case study
  • 10.4. Aluminum foundries case study
  • 10.5. Drill cuttings, petroleum sector case study
  • 10.6. Marble and granite industry case study
  • 10

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