Details

Autor(en) / Beteiligte

• Singh, M
• Ohji, T
• Asthana, R

Titel

Green and sustainable manufacturing of advanced material

Ort / Verlag

Amsterdam, Netherlands : Elsevier Science,

Erscheinungsjahr

[2016]

Link zum Volltext

• Elsevier Books AutoHoldings

Beschreibungen/Notizen

• Description based upon print version of record.
• Includes bibliographical references and indexes.
• Front Cover; Green and Sustainable Manufacturing of Advanced Materials; Copyright; Contents; Contributors; Preface; Part I: Material Conservation, Recovery, Recycling and Reuse ; Chapter 1: Green and Sustainable Manufacturing of Advanced Materials-Progress and Prospects; 1. Introduction; 2. Focus Areas; 2.1 Material Conservation, Recovery, and Recycling; 2.2 Sustainable Manufacturing-Metallic Materials; 2.3 Sustainable Manufacturing-Ceramic Materials; 2.4 Sustainable Manufacturing-Polymeric and Composite Materials
• Chapter 2: Moving Beyond Single Attributes to Holistically Assess the Sustainability of Materials1. Evolution of Views of Environmentally Preferable Materials and Products; 2. Examination of Specific Single Environmental Attributes; 2.1 Recycled Content; 2.2 Recyclability; 2.3 Bio-Based Materials; 3. The Use of Life-Cycle Analysis to Evaluate Multiple Product Attributes; 3.1 The Development of LCA as a Methodology; 3.2 Use of Life-Cycle Assessment to Quantify and Reduce Environmental Impacts; 3.3 The Use of Life-Cycle Analyses to Compare Products or Materials
• 3.4 Requirements for Using Life-Cycle Assessments and Environmental Product Declarations4. Design for the Environment; 5. Continual Evolution; 6. Conclusions; Acknowledgments; References; Chapter 3: Eco-Materials and Life-Cycle Assessment; 1. Eco-Materials; 1.1 Introduction to Eco-Materials; 1.2 Development of Eco-Materials Concept; 1.3 Research and Development of Eco-Materials and Related Technology in China; 2. Introduction of Life-Cycle Assessment; 2.1 Sustainability and Life-Cycle Thinking; 2.2 Definition of Life-Cycle Assessment; 2.3 Framework of Life-Cycle Assessment
• 2.4 Development and Application of Life-Cycle Assessment2.5 Database and Analysis Tool of LCA; 3. Development of LCIA Methodology in China; 3.1 LCIA Model of Abiotic Resource Depletion in China; 3.2 LCIA Model of Land Use in China [24]; 3.3 Methodology of LCIA Needs to Be Improved Continuously; 4. LCA Practice on Materials Industry in China; 4.1 Case Study: LCA of Iron and Steel Production in China; 4.2 Case Study: LCA of Magnesium Production in China [28]; 4.3 Case Study: Greenhouse Gas Analysis of Chinese Aluminum Production Based on LCA [29]
• 4.4 Case Study: Layout Adjustment of Cement Industry in Beijing Based on LCA [30]4.5 Case Study: LCA of Flat Glass Production in China [31]; 4.6 Case Study: CO 2 Emission Analysis of Calcium Carbide Sludge Clinker [32]; 4.7 Case Study: LCA in Chinese Energy Sector; 4.8 Case Study: LCA of Civilian Buildings in Beijing [35]; 5. Conclusions; References; Chapter 4: Exergetic Aspects of Green Ceramic Processing; 1. Introduction; 2. Illustrative Example for Understanding Exergy and Heat Energy [1-3]
• 2.1 Exergy Analysis 1: Entropy Increase due to Mixture and Exergy Calculation of N 2 and O 2 Gas
• Sustainable development is a globally recognized mandate and it includes green or environment-friendly manufacturing practices. Such practices orchestrate with the self-healing and self-replenishing capability of natural ecosystems. Green manufacturing encompasses synthesis, processing, fabrication, and process optimization, but also testing, performance evaluation and reliability. The book shall serve as a comprehensive and authoritative resource on sustainable manufacturing of ceramics, metals and their composites. It is designed to capture the diversity and unity of methods and approaches
• Description based on online resource; title from PDF title page (ebrary, viewed September 3, 2015).