Refine
Has Fulltext
- yes (26) (remove)
Year of Publication
Document Type
- Peer-Reviewed Article (17)
- Conference Object (4)
- Report (3)
- Working Paper (2)
Language
- English (26) (remove)
Division
This manual sets out to be an instruction guide for the implementation of analyses according to the MIPS concept. MIPS stands for Material Input Per Service unit, a measure developed at the Wuppertal Institute, which serves as an indicator of precautionary environmental protection. However, this publication is not a comprehensive description of the methods used, but should rather be seen as supplementing existing publications, in particular, the MAIA Handbook. This practical guide contains additional information, which cannot be part of a methodological description, but which is indispensable for the practical work. This manual is directed at enterprises and persons, who wish to carry out MIPS or a material analysis in relation to products or services. It gives a general impression of what MIPS is, and how MIPS is calculated.
This compendium "Resource Productivity in 7 Steps" is intended to give practical advice to designers, engineers, distributors, banks, lawmakers and others how to increase the resource productivity of goods and services (dematerialisation).
The eco-innovative (re-)design of products begins with the definition/description of the benefit or service, which a product provides to its user. The use of MIPS (Material Input Per unit Service) helps to develop solutions that can provide this benefit with the least possible quantity of natural resources, from. It measures the material and energy input of a product throughout its life-cycle, "from cradle to cradle" (production of raw materials, manufacturing, transportation, use, disposal). Thus, material and energy consumption can be minimised while satisfying the demand and decoupling of the economic activities from resource use.
The brochure describes in seven steps how to gain more resource productivity. It provides several worksheets for the innovation process and material intensity factors for the calculation of the material footprint. A translation into traditional chinese is also available.
The article estimates the natural resource consumption due to nutrition from the supply and demand sides. Using the MIPS (Material Input per Service Unit) methodology, we analyzed the use of natural resources along the supply chains of three Italian foodstuffs: wheat, rice and orange-based products. These figures were then applied for evaluating the sustainability of diets in 13 European countries. The results outline which phases in food production are more natural resource demanding than others. We also observed different levels of sustainability in the European diets and the effect of different foodstuffs in the materials, water and air consumption.
Purpose - The purpose of this paper is to summarize and discuss the results from the LIVING LAB design study, a project within the 7th Framework Programme of the European Union. The aim of this project was to develop the conceptual design of the LIVING LAB Research Infrastructure that will be used to research human interaction with, and stimulate the adoption of, sustainable, smart and healthy innovations around the home.
Design/methodology/approach - A LIVING LAB is a combined lab-/household system, analysing existing product-service-systems as well as technical and socioeconomic influences focused on the social needs of people, aiming at the development of integrated technical and social innovations and simultaneously promoting the conditions of sustainable development (highest resource efficiency, highest user orientation, etc.). This approach allows the development and testing of sustainable domestic technologies, while putting the user on centre stage.
Findings - As this paper discusses the design study, no actual findings can be presented here but the focus is on presenting the research approach.
Originality/value - The two elements (real homes and living laboratories) of this approach are what make the LIVING LAB research infrastructure unique. The research conducted in LIVING LAB will be innovative in several respects. First, it will contribute to market innovation by producing breakthroughs in sustainable domestic technologies that will be easy to install, user friendly and that meet environmental performance standards in real life. Second, research from LIVING LAB will contribute to innovation in practice by pioneering new forms of in-context, user-centred research, including long-term and cross-cultural research.
Technical innovations can contribute significantly to increase resource efficiency. A selection of 21 examples for resource efficient technologies, products and strategies from the field shows the brochure Resource Efficiency Atlas, which was created in line with the same titled project. Overall the project team analysed several hundred technical solutions and strategies and assessed its possible contributions to increases in resource efficiency. The project was arranged co-operatively by the Fraunhofer Institute for Industrial Engineering IAO, the Trifolium-Beratungsgesellschaft mbH and the Institut für Arbeitswissenschaften und Technologiemanagement of the University Stuttgart. The examples from the brochure and further 70 examples can be seen on the project website www.ressourceneffizenzatlas.de.
The purpose of the paper is to share the findings of a European innovation transfer project (2008-2010) for strengthening sustainability in European handicraft with the aim of transferring a German qualification and consulting concept. The focus of the paper is a train-the-trainer design, which was developed, tested and evaluated with regard to the specific qualification needs and the existing qualification concepts of five European countries. The paper provides content, didactic approach and methods of the train-the-trainer design and the key results of the related analysis of research data. Furthermore, the train-the-trainer design is embedded within the project approach, the methodology of realising an innovation transfer and the associated project products. The results of the train-the-trainer design evaluation are reflected upon with regard to starting points of a European qualification concept for sustainability in handicraft.
Assessing the natural resource use and the resource efficiency potential of the Desertec concept
(2013)
Considering global warming, increasing commodity prices, and the dramatic consequences of the over-exploitation and overuse of resources, a transition to a renewable energy supply is necessary. This requires an (resource) efficient and renewable supply of operating reserve. In this article, a possible solution to this problem is analysed: the Desertec concept. It is meant to convert solar energy in areas with high solar irradiation into electrical energy by means of Concentrated Solar Power (CSP) transferring this energy by High Voltage Direct Current (HVDC) lines into the whole European Union Middle East and North Africa (EU-MENA) area. In order to assess the resource efficiency potential of Desertec, three different kinds of CSP plants (parabolic trough, Fresnel collector and central receiver of the building classes Inditep, Novatec and Solar Tres) including heat storage systems (Molten Salt and Phase-Changing-Material) and the necessary HVDC are analysed using the Material Input per Service Unit (MIPS) methodology. The assessment is accomplished for three different locations (Morocco, Tunisia and Egypt) and two points of time (2025 and 2050). With these results, a scenario of electricity supply in Germany in 2050 with a 20% share of solar power import is calculated. Central receivers are the most resource efficient ones: their consumption of abiotic materials is only half of parabolic trough plants and two thirds of Fresnel trough plants. Water and air consumption is the lowest of all analyzed CSP plants as well. The scenario for Germany's fuel mix in 2050 shows that a predominantly renewable fuel mix reduces the consumption of abiotic materials by 75%, of water by 60% and of air by 45%. Only the consumption of biotic materials rises due to the higher share of biomass conversion.
Resource efficiency in production and technological innovations are inadequate for considerably reducing the current use of natural resources. Both social innovations and a complementary and equally valued strategy of sustainable consumption are required: goods must be used longer, and services that support collaborative consumption (CC) patterns must be extended. "Using rather than owning" strategies, such as product sharing, have the potential to conserve resources. Based on the results of different German studies, this article highlights the resource-saving potentials of CC patterns and recommendations proposed for policies and further research questions. The purpose of this paper is to show that a general resource-saving potential can be realized by "use rather than own" schemes, depending on the application field and the framework for implementation. CC is suitable for making a positive contribution to achieving the Factor 10 target by playing an important role in changing consumer patterns.