| Subject |
Industrial ecology
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Sustainable development
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Industrial organization (Economic theory)
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Environmental education
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Environmental management
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Environmental policy
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Industrial organization
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| Descript |
1 online resource (203 pages) |
| Content |
text txt |
| Media |
computer c |
| Carrier |
online resource cr |
| Contents |
Intro -- Foreword -- Contents -- Contributors -- 1 Relating Industrial Symbiosis and Circular Economy to the Sustainable Development Debate -- 1.1 Introduction -- 1.2 Bridging Circular Economy and Sustainable Development -- 1.3 The Contribution of Industrial Symbiosis to the Sustainable Development Goals -- 1.4 Advancing the IS and CE Discussion Within the SD Research Community: The Contribution of the International Sustainable Development Research Society (ISDRS) Conferences -- 1.4.1 An Overview of the 2018 ISDRS Conference 'Actions for a Sustainable World: From Theory to Practice' in Messina (Italy) -- 1.4.2 The Theme Track 'Circular Economy, Zero Waste and Innovation' -- 1.4.3 The Theme Track 'Industrial Symbiosis, Networking and Cooperation as Part of Industrial Ecology' -- 1.5 'Industrial Symbiosis for the Circular Economy': A Book Overview -- 1.6 Conclusions -- References -- 2 Guiding SMEs Towards the Circular Economy: A Case Study -- 2.1 Introduction -- 2.2 Methodology -- 2.3 Circular Economy Fields of Action -- 2.3.1 Guide to Diagnosing and Planning Circular Economy Implementation -- 2.4 Case Study -- 2.4.1 Performance Diagnosis -- 2.4.2 Analysis of Opportunities Derived from CE -- 2.4.3 The Design of the Circular Economy Implementation Plan -- 2.5 Conclusions -- References -- 3 Resources Audit as an Effective Tool for the Implementation of Industrial Symbiosis Paths for the Transition Towards Circular Economy -- 3.1 Introduction -- 3.2 Resources Audit: The ENEA Methodology -- 3.2.1 Data Collection on Resources and on the Production Process -- 3.2.2 Searching for Industrial Symbiosis Matches -- 3.2.3 Operative Handbooks -- 3.2.4 LCA -- 3.3 Conclusions -- References -- 4 Structure and Relationships of Existing Networks in View of the Potential Industrial Symbiosis Development -- 4.1 Introduction -- 4.2 Theoretical Background -- 4.3 Methods. |
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4.3.1 Data Sources -- 4.3.2 The Analytical Model -- 4.4 Networks Morphology Emerged from Case Studies -- 4.5 Results and Discussion -- 4.5.1 Nodes (Companies) Features -- 4.5.2 Ties (Relations) Features -- 4.6 Conclusions -- References -- 5 Industrial Symbiosis for the Circular Economy Implementation in the Raw Materials Sector-The Polish Case -- 5.1 Introduction -- 5.2 EU Policy Promoting Industrial Symbiosis in the Raw Materials Sectors and Its Impact on Mining Waste Management -- 5.3 Circular Models for the Mining Sector and Possible Assessment of Mining Waste Management -- 5.4 Industrial Symbiosis for Polish Energy Production Based on the Example of Brown Coal (Lignite) Mining -- 5.5 Conclusions -- References -- 6 Towards Sustainable E-Waste Management Through Industrial Symbiosis: A Supply Chain Perspective -- 6.1 Introduction -- 6.2 Study Methodology -- 6.2.1 Lifecycle of Electronic Items -- 6.2.2 Global E-Waste Supply Chain Network -- 6.3 Discussion and Analysis -- 6.3.1 Proposed Framework for Industrial Symbiosis -- 6.3.2 Discussion from the Perspective of Sustainability -- 6.4 Conclusions -- References -- 7 Supply Chain Management for Circular Economy in Latin America: RedES-CAR in Colombia -- 7.1 Introduction: Challenges of Sustainability Management in Latin American Firms -- 7.2 Supply Chain Mechanisms for Cleaner Production and Industrial Symbiosis Dissemination -- 7.2.1 Dissemination of Circular Economy Related Strategies Such as CP and IS -- 7.3 The Sustainable Enterprise Network (RedES): Model for Change -- 7.3.1 RedES Methodological Pillars -- 7.4 The RedES-CAR Programme -- 7.4.1 Operating Structure -- 7.4.2 Supply Chains Participating in RedES-CAR -- 7.4.3 Site Visits: Enhancing Project Design -- 7.4.4 Train-the-Trainers: Service Centres and Facilitators -- 7.4.5 Dissemination of Outcomes. |
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7.4.6 Follow up to Cleaner Production and Industrial Symbiosis Implementation -- 7.5 RedES-CAR Dissemination Performance -- 7.5.1 CP and IS Projects' Benefits -- 7.5.2 Economic and Environmental Benefits -- 7.5.3 Organizational Learning -- 7.6 Conclusions -- References -- 8 Emilia-Romagna (Italy) Innovative Experiences on Circular Economy -- 8.1 Context -- 8.1.1 Circular Economy and Industrial Symbiosis Framework -- 8.1.2 Emilia-Romagna Ecosystem -- 8.2 Initiatives Supporting Resource Efficient Industrial Ecosystems in Emilia-Romagna -- 8.2.1 Introducing a Cooperation Culture: The "Green-Industrial Symbiosis" Project -- 8.2.2 Strengthening Policy Instruments with Interregional Cooperation: The "TRIS" Project -- 8.2.3 Promoting Secondary Raw Materials Uptake in the Agri-Food Sector: The "Food Crossing District" Project -- 8.3 Lessons Learnt and Conclusions -- References -- 9 The Role of Collaborative and Integrated Approach Towards a Smart Sustainable District: The Real Case of Roveri Industrial District -- 9.1 Introduction -- 9.2 Methods -- 9.3 Results -- 9.3.1 Innovation in Governance -- 9.3.2 Community Engagement and Common Vision for Roveri -- 9.3.3 Circular Economy: Industrial Symbiosis Scenarios -- 9.3.4 Energy-Saving Solutions -- 9.4 Discussion -- 9.5 Conclusions -- References -- 10 ALL YOU CAN'T EAT: Research and Experiences from Agri-Food Waste to New Building Products in a Circular Economy Perspective -- 10.1 Glossary -- 10.2 Introduction -- 10.3 From Agri-Food Waste to New Building Products -- 10.3.1 Experiences of International Scientific Literature Relating to Agri-Food Waste -- 10.3.2 The Researches Cluster: ALL YOU CAN'T EAT -- 10.3.3 CONCRICE -- 10.3.4 THERMALMOND -- 10.3.5 KERATOSTONE -- 10.4 ECOFFI -- 10.4.1 Concept and Methodology -- 10.4.2 Prototyping -- 10.4.3 Testing and Monitoring -- 10.4.4 Life Cycle Assessment. |
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10.4.5 Defining the Supply Chain and the Industrial Symbiosis Process -- 10.4.6 Exploring the Market -- 10.4.7 Results and Outlook -- 10.5 Discussions -- 10.6 Conclusions -- References -- 11 A Sustainable Approach to the Re-use of Biomass: Synergy Between Circular Agroindustry and Biorefinery Models -- 11.1 Introduction -- 11.2 Methodology -- 11.2.1 The Biorefinery Approach -- 11.2.2 Production Process of Biomolecules from Residual Biomass -- 11.3 Olea europaea L. (Olive Tree) -- 11.4 Vitis Vinifera L. (Grape and by-Products) -- 11.5 Castanea Sativa Mill (Sweet Chestnut) -- 11.6 Conclusive Considerations -- References -- 12 Valorization of Agricultural Wastes and Biorefineries: A Way of Heading to Circular Economy -- 12.1 Introduction -- 12.1.1 Circular Economy, Industrial Symbiosis and Waste Valorization -- 12.1.2 New and Sustainable Trends for Agriculture Waste Treatment -- 12.1.3 The Bio-based Economy -- 12.1.4 Biorefineries -- 12.2 A Biorefinery Based on Seeds and Vegetable Wastes -- 12.3 A Biorefinery for Food Based in Opuntia Joconostle -- 12.3.1 The Main Raw Material for the Biorefinery: Xoconostle -- 12.3.2 IPCA and Its Biorefinery Approach -- 12.3.3 Valorization of Xoconostle: Industrial Processes and Products Involved -- 12.3.4 Rural Enterprises Potential in the Bio-Based and Circular Economy: Barriers and Lessons Learned -- 12.4 Agricultural Valorizations in Symbiotic Systems -- 12.4.1 The Symbiotic Systems and Their Waste Valorizations in Mexico -- 12.4.2 Barriers and Lessons Learned -- 12.5 Conclusions -- References. |
| Note |
Unlimited number of concurrent users. UkHlHU |
| Alt author |
Cecchin, Andrea.
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Deutz, Pauline.
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Raggi, Andrea.
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Cutaia, Laura.
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| ISBN |
9783030366605 (electronic bk.) |
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