1. carlo vezzoli politecnico di milano . INDACO dpt. . DIS . faculty of design . Italy Learning Network on Sustainability course System Design for Sustainability subject 3. System design for eco-efficency learning resource 3.2 System design for eco-efficiency
2. CONTENTS System design for eco-efficiency: approach “ satisfaction-system” approach “ stakeholders’ interactions” approach “ eco-efficiency-oriented” system approach System design for eco-efficiency criteria System life optimisation Transportation-distribution reduction Resources reduction Waste minimisation-valorisation Conservation-biocompatibility Toxic reduction
3. new research frontier … low impact mat./energies design for social equity and cohesion system design for eco-efficiency Product Life Cycle Design ecodesign SYSTEM DESIGN FOR ECO-EFFICIENCY : STATE OF ART (in industrially mature countries) CONSOLIDATION (research achievements) (education and practice) DISSEMINATION 100% 100% 0 widening the “object” to be designed … aim at
12. > CRITERIA AND GUIDELINES ARE NEEDED > METHODS AND TOOLS ARE NEEDED to orientate design towards system eco-efficent stakeholder interactions 3. NOT ALL SYSTEM INNOVATION ARE ECO-EFFICENT!
16. some are the methods/tools for system design and its orientation towards eco-efficient solutions METHODS/TOOLS
17. some methods/tools developed to orientat e system design towards sustainable solutions: [EU RESEARCHES: MEPSS, HICS, PROSECCO, …] METHODS/TOOLS MEPSS, EU RESEARCH, 2005 van Halen, Vezzoli & Wimmer, Methodology for product service system innovation, Van Gorcum, Assen, The Netherlands, 2005 HiCS, EU RESEARCH, 2005 Manzini, Collina & Evans, Highly Customerised Solutions, Cranfield University, 2006
18. STRATEGIC ANALYSIS Gaining the information needed to facilitate the generation of ideas oriented towards sustainability EXPLORING OPPORTUNITIES SYSTEM CONCEPT DESIGN SYSTEM DESIGN (AND ENGIN.) COMMUNICATION MSDS PHASES OBJECTIVES Producing a “catalogue” of promising strategic possibilities, i.e. a sustainability design-orienting sceanario Defining one or more system concept oriented towards sustainability Developing the most promising system concept in a detailed version necessariy to its implementation Producing the documents for the external communication of the solution’s characteristics (general characteristics but above all the sustainability ones) ANALYSIS OF THE PROJECT PROMOTERS ANALYSIS OF THE REFERENCE CONTEXT ANALYSIS OF BEST PRACTICES ANALYSIS OF THE REFERENCE STRUCTURE DEFINITION OF SUSTAINABILITY DESIGN PRIORITIES IDEAS GENERATION ORIENTED TO SUSTAINABILITY DEVELEPMENT OF THE SUSTAINABILITY DESIGN ORIENTING SCENARIO - VISIONS/CLUSTERS/IDEAS VISIONS, CLUSTERS AND IDEAS SELECTION SYSTEM CONCEPT DEVELOPMENT ENV., SOC. & ECON. CHECK SYSTEM DEVELOPMENT (EXECUTIVE LEVEL) ENV., SOC. & ECON. CHECK DOCUMENTS EDITING
19. MODULAR METHOD : 1. enabling to START up the process at any stage 2. enabling to use a SELECTED set of processes and tools STRATEGIC ANALYSIS EXPLORING OPPORTUNITIES SYSTEM CONCEPT DESIGN SYSTEM DESIGN (AND ENGIN.) COMMUNICATION ANALYSIS OF THE PROJECT PROMOTERS ANALYSIS OF THE REFERENCE CONTEXT ANALYSIS OF BEST PRACTICES ANALYSIS OF THE REFERENCE STRUCTURE DEFINITION OF SUSTAINABILITY DESIGN PRIORITIES IDEAS GENERATION ORIENTED TO SUSTAINABILITY DEVELEPMENT OF THE SUSTAINABILITY DESIGN ORIENTING SCENARIO - VISIONS/CLUSTERS/IDEAS VISIONS, CLUSTERS AND IDEAS SELECTION SYSTEM CONCEPT DEVELOPMENT ENV., SOC. & ECON. CHECK SYSTEM DEVELOPMENT (EXECUTIVE LEVEL) ENV., SOC. & ECON. CHECK DOCUMENTS EDITING MSDS PHASES
20. SYSTEM DESIGN FOR ECO-EFFICIENCY CRITERIA System life optimisation Transportation-distribution reduction Resources reduction Waste minimisation-valorisation Conservation-biocompatibility Toxic reduction
21. SYSTEM LIFE OPTIMISATION DESIGN FOR, SYSTEM STAKEHOLDERS’ INTERACTIONS LEADING TO, EXTEND ING THE SUM OF THE PRODUCTS’ LIFE SPAN AND INTENS IFYING THE SUM OF THE PRODUCTS’ USE
22. given function in time USE AVOIDED IMPACTS LIGHTER IMPACTS short product’s (system sum) life extended product’s (system sum) life PRODUCTION DISTRIBUTION USE PRE-PRODUCTION NEW TECHNOLOGIES AND TECHNIQUES WITH LOWER USE CONSUMPTION USE DISP. P-PR. PROD . DISTR . UPDATING OF THE COMPONENTS CAUSING CONSUMPTION PRE-PRODUCTION PRODUCTION DISTRIBUTION USE DISPOSAL PRE-PRODUCTION PRODUCTION DISTRIBUTION USE
23. LIFE INDIPENDENT FROM LENGHT OF USE AVOIDED IMPACTS product’s (system sum) not intense life product’s (system sum) intense life P-PROD . PROD . DISTR . DISP . use (function) during time P-PROD . PROD . DISTR . DISP . P-PROD . PROD . DISTR . DISP. P-PROD . PROD . DISTR . DISP . B 1 B 2 B 3 A 1 A 2 A 3 C 1 C 2 C 3 A 1 A 2 A 3 B 1 B 2 B 3 C 1 C 2 C 3
24. PP P Dt PP P Dt PP P Dt PP P Dt Ds use (function) during of time NEW TECHNOLOGIES AND TECHNIQUES WITH LOWER USE CONSUMPTION NEW PRE AND POST CONSUMPTION TECHNOLOGIES WITH LOWER IMPACT LIFE FUNCTION OF LENGHT OF USE product’s (system sum) not intense life product’s (system sum) intense life LIGHTER IMPACTS LIGHTER IMPACTS Ds Ds Ds PP P Dt Ds PP P Dt Ds
25. TRANSPORTATION/DISTRIBUTION REDUCTION DESIGN FOR, SYSTEM STAKEHOLDERS’ INTERACTIONS LEADING TO, REDUCING THE SUM OF THE TRANSPORTATIONS AND PACKAGINGS
26. RESOURCES REDUCTION DESIGN FOR, SYSTEM STAKEHOLDERS ’ INTERACTIONS LEADING TO, REDUCING THE SUM OF THE RESOURCES USED BY ALL PRODUCTS AND SERVICES OF THE SYSTEM
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28. WASTE MINIMISATION/VALORISATION DESIGN FOR, SYSTEM STAKEHOLDERS’ INTERACTIONS LEADING TO, IMPROVING THE SUM OF THE SYSTEM RECYCLING, ENERGY RECOVERY AND COMPOSTING AND REDUCING THE SUM OF THE WASTE PRODUCED
29. material (system sum ) non-extended life material (system sum ) extended life AVOIDED IMPACTS ADDITIONAL IMPACTS PRE-PRODUCTION PRODUCTION DISTRIBUTION USE LANDFILL PRODUCTION DISTRIBUTION USE PRE-PRODUCTION PRODUCTION DISTRIBUTION USE RECYCLING COMBUSTION COMPOSTING PRE-PRODUCTION
31. TOXIC REDUCTION DESIGN FOR, SYSTEM STAKEHOLDERS’ INTERACTIONS LEADING TO, REDUCING/AVOIDING THE SUM OF THE SYSTEM’S RESOURCES TOXICITY AND HARMFULNESS