Global ETD Search

1	Urban Mining potential in local power grids: Hibernating copper and aluminium in Linköping Andersson, Simon January 2013 (has links) Power grids have a high content of metal, mainly copper and aluminium. When old cables reach their end-of-life, or in some way lose their intended purpose, they are usually left lying in their subsurface position. Material no longer used, but not yet discarded as waste, is in a state known as hibernation. Over time there is an accumulation of hibernating cables under ground that potentially could be recovered or “mined”. The aim of this study is to examine the total hibernating metal content of an urban, subsurface power grid, how it is distributed and also what reasons for disconnection are the most common. The focus of the study is the power grid of Linköping. Using a GIS based variant of material flow analysis the hibernating metal stock is examined both in terms of size and spatial distribution. The results of the study show a significant amount of hibernating copper and aluminium; in total 240 tons of metal were identified. By comparing the results with previous studies both similar and differing patterns appear. The main differences lie in the distribution of the stock within the city which is affected by the characteristics of the cities. When examining the reasons for disconnection continuous repair and maintenance work seems to be the most common reason for disconnection of cables. Further studies on how the characteristics of a city affects the formation of hibernating metal stocks in the infrastructure are suggested. GIS metal stocks MFA power grid urban mining
2	Designing for the Unknown : Exploring Urban Mining as a case study Erlingsson, Oskar, Dahlqvist, Karin January 2015 (has links) The earth’s resources are limited; with the speed that humanity are using earth’s resources today, we would need 1.5 times of the earth’s regenerative capacity to compensate for what we use. Raw materials has since a long time ago been mined from the bedrock, which affects the earth in a negative way. If we could use materials and products that are circulating in our society, but are not being used and thereby considered as waste, traditional mining could be replaced with urban mining. Imagine what would happen if earth’s resources would be limited by laws and regulations in the future; mining as it is known today would not be allowed and there would be a need of resources that is gathered in another way, an unknown way. The world is constantly changing and this results in the fact that there will always be unexplored areas that needs to be defined and developed to be able to handle the changes in the future. Considering the fact that urban mining is such an unexplored field, there is a need of creating a process to define the segment in order to develop product/services within it. The outcome of this thesis is therefore recommendations for how a generic design process can be tailored and implemented for innovation development in undefined areas. The result is reached through investigating a development project, which focuses in the research area urban mining, as a case study and also by studying design processes in theory. The investigation is conducted with an explorative approach by observing the field and sub-fields of urban mining. This thesis shows that drivers and trends for urban mining exist, and that there is a future need to capitalize this market. The result also shows that the most important characteristics of the design process when designing for the unknown, is the fact that defining the research area requires even more effort when dealing with an initially unknown field, compared with known research areas. / Jordens resurser är begränsade; med den hastighet som mänskligheten använder jordens resurser idag, skulle vi behöva 1,5 gånger jordens återhämtningsförmåga för att kompensera för det vi använder. Råmaterial har sedan länge brutits från berggrunden, vilket påverkar jorden på ett negativt sätt. Om vi istället skulle kunna använda material och produkter som cirkulerar i vårt samhälle, men inte används och därmed betraktas som avfall, skulle traditionell materialutvinning kunna ersättas med urban mining. Tänk vad som skulle hända om jordens resurser i framtiden begränsas genom lagar och regler; materialutvinning som det är känt idag inte skulle tillåtas och det då skulle finnas ett behov att samla resurser på ett annat sätt, ett idag okänt sätt. Världen förändras ständigt vilket resulterar i det faktum att det alltid kommer att finnas outforskade områden som måste definieras och utvecklas för att kunna hantera dessa förändringar i framtiden. Urban mining är ett sådant outforskat område och därför finns det ett behov av att skapa en process för att definiera segmentet och på så vis kunna utveckla produkter och tjänster inom området. Resultatet av denna uppsats är därför rekommendationer för hur en allmän design process kan skräddarsys och implementeras för innovativ utveckling i odefinierade områden. Resultatet uppnås genom att analysera ett utvecklingsprojekt, som fokuserar på forskningsområdet urban mining, som en fallstudie, samt att studera designprocesser i teorin. Undersökningen genomförs med ett explorativt tillvägagångssätt genom att utföra observationer inom ämnet urban mining. Arbetet visar att drivfaktorer och trender för urban mining existerar och att det finns ett framtida behov att utforska och dra fördel av denna marknad. Resultatet visar också att de viktigaste egenskaperna hos design processen vid utveckling inom okända områden är det faktum att forskningsområdet kräver ännu större fokus på att definiera området, jämfört med kända forskningsområden. Design design process product development process undefined segment and urban mining. Design designprocess produktutvecklingsprocess odefinierade segment och urban mining.
3	[en] EVOLUTION OF MOBILE PHONES TECHNOLOGY AND THE IMPACT ON THE WASTE OF ELECTRICAL AND ELECTRONIC EQUIPMENT / [pt] EVOLUÇÃO DA TECNOLOGIA MÓVEL CELULAR E O IMPACTO NOS RESÍDUOS DE ELETROELETRÔNICOS FABRICIO ROBERTO SENA 06 November 2013 (has links) [pt] Os produtos da indústria de eletroeletrônicos possuem alta empregabilidade no dia a dia. No entanto, por terem um ciclo de vida curto impactam na demanda por recursos naturais não renováveis. Dentro do universo de equipamentos eletroeletrônicos, os telefones celulares estão entre os mais complexos e os que empregam maior quantidade de elementos químicos diferentes. Apesar de pequenos, são vendidos aos milhares, em parte devido a sua curta vida útil. Esses fatores aliados indicam a existência de riscos à saúde e ao meio ambiente, o que faz repensar como destinar corretamente esses aparelhos no pós-consumo. A proposta do trabalho é fazer uma análise de como os telefones celulares impactam no volume e na complexidade dos Resíduos de Equipamentos Eletroeletrônicos, explicar a razão desse bem essencial ter uma vida útil tão curta e expor os motivos que tornam a sua reciclagem absolutamente necessária para continuar o seu desenvolvimento tecnológico, atender a demanda dos consumidores e reduzir o impacto ambiental da produção ao descarte. / [en] In the last century, through new production processes, the industry has increased the variety and availability of products offered to the population, providing better quality of life. This has happened because the inception of series production has offered a greater supply of consumer goods, including the Electrical and Electronic Equipment (EEE). The evolution of electronics technology has provided, and will continue to provide a better quality of life than the one we used to have. However, the technology of these products is continuously evolving, and this brings advantages and disadvantages. [pt] RECICLAGEM [en] RECYCLING [pt] TELEFONE CELULAR [en] CELLULAR PHONE [pt] REEE [en] WEEE [pt] MINERACAO URBANA [en] URBAN MINING
4	Laptops and smartphones - a gold mine? : A material flow analysis of small electronics in a Swedish organisation with focus on metal resources Karlsson, Daniella January 2021 (has links) The aim of this study is to contribute to today´s knowledge about stocks of electronic products on the organisational level. This is done by using a bottom-up MFA on laptops and smartphones in a chosen organisation, the data collected for this study is done by both semi-structured interviews and literature searches. Investigating the associated metals in the laptops and smartphones is also an aim of this study. Having knowledge of the existing stocks and flows of materials is important for the prospects of urban mining. This study takes a circular economy aspect of the current state of stocks and flows of materials. Circulation of materials within society is an effective approach to saving resources rather than just recycling the materials since not all materials can be retrieved through recycling processes. The results show that there is a significant stock of metals embedded in the laptops and smartphones in the organisation. Metals found include Aluminium, Magnesium, Copper, Iron, Nickel, Tin, Gold, Silver, Palladium, Zinc, Lead, Cobalt, Barium and Neodymium. The results also indicates that some of the laptop stock is in hibernation and so is the associated metals in these laptops. These stocks could be of big importance for future sources of metal resources, but more studies are needed to fully understand the stocks of metals in society and how much of these stocks that are in hibernation. / Gruvan i garderoben Metals bottom-up MFA Recycling Reuse Urban mining Stocks Environmental Sciences Miljövetenskap
5	Exploring the potential for local end-processing of e-waste in South Africa Sadan, Zaynab 29 January 2020 (has links) E-waste is one of the fastest-growing waste streams in the world, and South Africa (SA) is no exception. This is driven by increased consumer demand and access to electrical and electronic equipment, in addition to perceived equipment obsolescence, and rapid advancements in technology. E-waste recycling presents an opportunity in providing a source of secondary resources such as metals, plastics and glass, as well as employment and economic opportunities in both developed and developing countries. Furthermore, the diversion of this waste stream from landfills or dumps prevents additional land use and the potential negative impacts on human health and the environment. E-waste collection and upgrading is a relatively small-scale but growing industry in SA. Only 12% of e-waste generated was estimated to be recycled in 2015. Most of SA’s ewaste volumes are inaccessible due to lack of formal take-back schemes, lack of consumer awareness, as well as e-waste being kept in storage or disposed of in landfills. E-waste recyclers in SA generally carry out collection, dismantling and sorting, refurbishing, as well as pre-processing of value fractions. There is currently limited local end-processing capacity, therefore partially upgraded value fractions are prepared for export, while non-viable fractions are stockpiled or disposed of in local landfills. The business case for local end-processing of e-waste value fractions, particularly metals, does not seem feasible due to the inconsistent and insufficient volumes available. Furthermore, SA faces unique socio-economic challenges such as an unregulated yet well-established informal sector. Additionally, the legal framework presents many inhibitors for e-waste recyclers. This research study builds upon the knowledge that there is a limited understanding of the feasibility of existing e-waste end-processing technologies for implementation in the South African socio-economic and legislative context. Therefore, this research intends to find out what are the key barriers and enablers to implementing e-waste end-processing technologies in SA. Qualitative research methods were used to uncover the current challenges faced by local recyclers and other stakeholders in the value chain. The data collection thus took the form of interviews, site visits and desktop research. The findings show that the e-waste recycling industry in SA is undergoing many new developments in terms of research and investment interest, as well as the anticipated outcomes from the recent submissions of Industry Waste Management Plans (IndWMP). The industry shows potential as an emerging secondary resource economy, however, the extent to which it will mature is dependent on the organisation of its collection network as well as the development of local end-processing and manufacturing capacity. The collection network and infrastructure are currently supported by both informal and formal recyclers who provide a diversity of collection strategies and a wide network of ewaste sources. However, efforts to increase recycling rates by accessing volumes in storage and increasing consumer awareness and engagement is necessary. Besides the economies of scale required to support the development of local end-processing, alternative technologies to large-scale smelting should be considered for the SA context. While this is seen through initiatives by SA Precious Metals, end-processing technologies is still inaccessible to small and medium recyclers due to cash flow issues as well as cherry-picking of high-grade materials. Therefore, recyclers require further support in terms of dealing with non-viable fractions. This includes research and investments into technologies and business models for the recycling of low-value materials including plastics, as well as subsidies for the cost of safe disposal or treatment of these fractions. Additionally, acquisition of product markets and an increase in manufacturing capacity is necessary to accelerate industry development. The legislative framework also poses limitations on recyclers in the e-waste value chain, stemming from the legal definition of e-waste as a liability as opposed to a resource. While the legislation is unlikely to change, provisions to relieve any legal barriers should be implemented. This includes permissions for pilot projects to test new technologies, as well as legal support for smaller recyclers in the form of consultancy as well as guidelines for sustainable waste management practices should be provided. Finally, while there are many challenges present in the e-waste recycling industry today, the IndWMP offers an opportunity for collaboration between key stakeholders, including the relevant government bodies. Plans have been submitted and the outcomes of approved plans will be revealed at the beginning of 2019. The plans offer solutions for recycling subsidies, increasing the collection and recycling rates, as well as investment into technology, research and enterprise development. However, successful implementation of these plans will only occur if integration and collaboration of the local e-waste community prevail over greed and the struggle for power. WEEE E-waste Recycling Value Extraction Circular Economy Urban Mining Waste Management Second
6	Product-Service System Innovation in Urban Mining-A case study with Volvo CE Chai, Yi, Gao, Zhenqing January 2014 (has links) Volvo Construction Equipment (Volvo CE) is one of the world's largest manufacturers of construction machines. Now they want to access a sustainability-focused mining field – urban mining. This study is to find a solution helping Volvo CE quickly access to urban mining with a Product-Service System (PSS) development concept. To do this, the authors completed surveys and several interviews with construction companies, to understand the user and customer needs. The authors also go through a functional analysis on a new prototype of their collaboration partner - Stanford University. The result of this thesis is a PSS concept for urban mining, developed with machine selection guidelines combined with Life Cycle Assessment, and Quality Function Deployment. Recommendations include: 1) Improve the communication between Volvo CE and their Customers. 2) Adding more visible services. 3) Adding multiple business solutions provide to customers. 4) Understanding relevant stakeholders in urban mining 5) Expand research on urban mining. Construction Equipment Urban Mining Product-Service System Sustainable Development Life Cycle Assessment Quality Function Deployment House of Quality Social Sciences Interdisciplinary Mechanical Engineering Maskinteknik
7	[pt] AVALIAÇÃO TECNOLÓGICA E ECONÔMICA DE UMA ROTA DE PROCESSAMENTO PARA RECICLAGEM DE SUCATAS ELETRÔNICAS / [en] TECHNOLOGICAL AND ECONOMIC ASSESSMENT OF A PROCESSING ROUTE FOR ELECTRONIC WASTE RECYCLING FELIPE SEABRA D ALMEIDA 07 June 2022 (has links) [pt] O Brasil é o segundo maior produtor de lixo eletrônico das Américas, com uma produção que cresce a cada ano e apenas 10 por cento dela sendo tratada de forma apropriada. Adicionalmente, o Brasil não possui tecnologia própria para tratamento de placas de circuito impresso, componente chave presente neste tipo de resíduo. Atualmente, o Brasil não possui uma planta industrial voltada para essa atividade extrativista a partir de resíduos eletrônicos, sendo a maior parte do seu tratamento realizado no exterior. A hipótese de pesquisa deste manuscrito é que as universidades e suas comunidades poderiam desenvolver fontes de matéria-prima para tais processos de extração e, portanto, merecem atenção para a criação de pontos de coleta e parcerias. Nesse contexto, é necessário entender o comportamento dessa comunidade em relação à aquisição, armazenamento e descarte de equipamentos eletrônicos, bem como informações sobre temas relacionados ao gerenciamento e reciclagem de resíduos eletrônicos. Adicionalmente, criou-se uma rota conceitual de tratamento, a partir da integração de tecnologias descritas na literatura. Após a criação do design da rota, foi realizado um balanço de massa e energia, considerando dois casos base de fonte de placas de circuito impresso como matéria prima matéria prima: A) Lixo eletrônico em geral; B) utilizando somente celulares. Para ambos os casos, foi considerado o tratamento de 2 t/h. Determinou-se que o grupo estudado possui mais de 16,96 milhões de telefones celulares em hibernação, além de outros equipamentos, com valor de estoque estimado em 67,45 milhões de dólares para o grupo estudado na região metropolitana do Rio de Janeiro. Se extrapolado para todo o Brasil, pode chegar a 797,50 milhões de dólares para o grupo estudado. uma taxa interna de retorno de 141,6 por cento e 3990,7 por cento para o caso A e B, respectivamente e valor presente líquido de USD 44,834,616 e USD 3,215,300,083 para o caso A e B, respectivamente. Adicionalmente, foi determinado que o caso A possui uma grande sensibilidade a variação da taxa de ocupação. Neste contexto, a presente pesquisa tem o potencial de ajudar na criação da primeira planta industrial brasileira voltada para a reciclagem de placas de circuito impresso, assim como entender quais são as variáveis chaves para o processamento destes componentes. Adicionalmente, o projeto apresenta o investimento necessário para a criação da planta, sendo uma informação crucial para potenciais investidores. / [en] Brazil is the second largest producer of electronic waste in the Americas, with a production that grows each year and only 10 percent of it is properly treated. Additionally, Brazil does not have its own technology for treating printed circuit boards, a key component present in this type of waste. Currently, Brazil does not have an industrial plant dedicated to this extractive activity from electronic waste, with most of its treatment carried out abroad. The research hypothesis of this manuscript is that universities and their communities could develop raw material sources for such extraction processes and, therefore, deserve attention for the creation of collection points and partnerships. In this context, it is necessary to understand the behavior of this community in relation to the acquisition, storage and disposal of electronic equipment, as well as information on issues related to the management and recycling of electronic waste. Additionally, a conceptual treatment route was created based on the integration of technologies described in the literature. After creating the route design, a mass and energy balance was carried out, considering two base cases of printed circuit boards as raw material: A) Electronic waste in general; B) using cell phones only. For both cases, the treatment of 2 t/h was considered. It was determined that the studied group has more than 16.96 million cell phones in hibernation, in addition to other equipment, with an estimated inventory value of 67.45 million dollars for the studied group in the metropolitan region of Rio de Janeiro. If extrapolated to all of Brazil, it could reach 797.50 million dollars for the studied group. an internal rate of return of 141.6 percent and 3990.7 percent for case A and B, respectively, and net present value of USD 44,834,616 and USD 3,215,300,083 for case A and B, respectively. Additionally, it was determined that case A is highly sensitive to occupancy rate variation. In this context, this research has the potential to help in the creation of the first Brazilian industrial plant dedicated to the recycling of printed circuit boards, as well as to understand the key variables for the processing of these components. Additionally, the project presents the investment necessary for the creation of the plant, being crucial information for potential investors. [pt] MINERACAO URBANA [pt] RECUPERACAO DE METAIS PRECIOSOS [pt] RECICLAGEM DE LIXO ELETRONICO [pt] ECONOMIA CIRCULAR [en] URBAN MINING [en] RECOVERY OF PRECIOUS METALS [en] E-WASTE RECYCLING [en] CIRCULAR ECONOMY
8	Chunk Metabolism : Exploring how to plan for reuse of structural elements / Chunk Metabolism : Hur man kan planera bättre för återbruk av tunga stomdelar Nilsson, Isabella January 2022 (has links) With a major share of the negative environmental impacts deriving from construction and its waste, ways to reduce the material and energy use in this sector have been the focus of studies for decades. Reuse of building elements and materials is gaining traction with researchers, architects, developers and real estate owners. However, it is rarely used in practice in Sweden. Barriers include fear of fluctuating supply, quality warranties, logistics, lack of experience in the design process and unknown availability. While many research projects are underway, a process of how to locate materials is still missing. Additionally, there is currently little connection between research and practice, and a lack of investigation into the long-term consequences that reuse will have on the design process and the role of the architect. Therefore, the aim of this study is to discover what heavy structural elements will be available for reuse in the Stockholm region and to explore which implications reuse will on the design process and the role of the architect. The study evaluated a new method for short-term mapping of available elements using demolition permits. It also intended to map available elements medium- term through detailed development plans, and long-term using comprehensive plans. The results showed that the medium-term span mapping was not plausible as there are too many detailed development plans and no feasible way to review them due to how they are accessible to the public. The long-term mapping showed potential in identifying characteristics of different areas and indicating where demolitions or transformations might occur. Given there might be a paradigm shift in the way the industry manages resource, as policy and industry goals indicate, the areas where demolition is planned today might be transformed tomorrow. The short-term mapping was the most promising method developed. It showed that significant amounts of heavy structural elements will be available within two years. The buildings with heavy structural elements that are now up for demolition are mostly from the 1960-1980s and are principally all non-residential. 16 different structural typologies were identified and evaluated for reuse potential. Four typologies were highlighted as especially valuable for reuse: 1) cast in-situ reinforced concrete structure 2) prefabricated reinforced concrete elements structure 3) brick structure from before 1960 and 4) steel structure. The dominant structural material was concrete, which was the core material in 93% of the total area found. To test the method’s usefulness and reveal implications on the design process, it was used for an ongoing residential project by developer NREP and architects Tengbom and Lendager Group. The case study showed that suitable structural elements could be sourced for the project with the short-term mapping. A new design proposal for the structure was made with elements from the mapping, which was estimated to avoid significant environmental impact compared to a new structure. According to international studies on this type of reuse, over 90% of CO2-equiv. emissions for new buildings can be saved reusing prefabricated concrete panels. For the design process, the implication of reuse is often an elongated introductory phase. The case study showed that studying grids and proportions of the existing system was essential to transform it into a new one, allowing the process to be more material-driven. Considerations on how to use the elements to minimise waste and environmental impact from preparing the elements for reuse are imperative when designing the system. It could be argued that waste is a design error, highlighting the need to educate new cohorts of architects and designers in designing for reuse. Potentials for reuse lie in maintaining the value of the structural elements, instead of paying to get rid of them, and to avoid large negative environmental impacts for raw material extraction and production. Projects realised today have shown large savings in CO2-equivalent and costs alike. Nevertheless, it requires innovative and non- conventional organisation and roles. Cooperation and trust amongst stakeholders is key. The design process needs to become more collaborative and iterative with higher frequency of information exchange. This requires designers, architects and engineers to look both backward, to understand the existing buildings and materials that we can use, and forward, in how to use them going forward with innovative strategies for project plausibility, the environment and great (longstanding) architecture. / Byggande och avfall står för en stor del av all negativ miljöpåverkan i världen. Sätt att minska material- och energianvändningen inom byggsektorn har därför varit i fokus för studier i årtionden. Återbruk av byggnadselement och material har ökat i intresse hos forskare, arkitekter, utvecklare och fastighetsägare senaste åren. Trots det implementeras det sällan i praktiken i Sverige. Barriärer för återbruk inkluderar rädsla för fluktuerande utbud, kvalitetsgarantier, logistik, bristande erfarenhet i designprocessen och brist på tillgänglighet. Många forskningsprojekt pågår men det saknas en process för hur man identifierar och lokaliserar material. Dessutom finns det för närvarande lite samband mellan forskning och praktik, och liten insikt i de långsiktiga konsekvenserna som återbruk kommer att ha på designprocessen och arkitektens roll. Därför är syftet med denna studie att ta reda på vilka tunga stomelement som kommer att finnas tillgängliga för återbruk i Stockholmsregionen och att undersöka konsekvenser för hur återbruk kommer att påverka designprocessen och arkitektens roll. Studien utvärderade en ny metod för kortsiktig kartläggning av tillgängliga stomelement med hjälp av rivningslov, samt utforskade kartläggning av tillgängliga stomelement på medellång sikt genom detaljplaner och på lång sikt med översiktsplaner. Resultaten visade att kartläggningen på medellång sikt inte var möjlig eftersom det finns för många detaljplaner och inget genomförbart sätt att granska dem på grund av hur de är tillgängliga för allmänheten. Den långsiktiga kartläggningen visade potential för att identifiera egenskaper hos olika områden i Stockholm och indikera var rivningar eller omvandlingar kan inträffa. Med tanke på att det kan komma ett paradigmskifte i hur industrin hanterar resurser, som policy och branschmål indikerar, kan de områden där rivning planeras idag komma att transformeras i morgon. Den kortsiktiga kartläggningen var den mest lovande metoden som utvecklats. Den visade att betydande mängder tunga stomelement kommer att finnas tillgängliga inom två år. De byggnader med tunga stomelement som nu ska rivas är till största delen från 1960-1980-talet och är generellt kontor och industribyggnader. 16 olika stomtypologier identifierades och utvärderades för återbrukspotential. Fyra typologier lyftes fram som särskilt värdefulla för återanvändning 1) platsgjuten armerad betongkonstruktion 2) prefabricerad armerad betongelementkonstruktion 3) Tegelkonstruktion från före 1960 och 4) stålkonstruktion. Det dominerande konstruktionsmaterialet var betong som var kärnmaterialet i 93 % av den totala ytan som hittades. För att testa användbarheten av metoden och identifiera implikationer på designprocessen användes den i ett pågående bostadsprojekt av utvecklaren NREP och arkitekterna Tengbom och Lendager Group. Fallstudien visade att lämpliga stomelement kunde identifieras för projektet med den kortsiktiga kartläggningen. Ett nytt förslag för stommen gjordes med element från kartläggningen, vilket bedömdes undvika betydande miljöpåverkan jämfört med en ny stomme. Enligt en tysk studie kan denna typ av återbruk undvika 90 % av CO2-ekv. utsläpp under produktion och byggande genom att återanvända prefabricerade betongpaneler. Implikationen av återbruk på designprocessen är ofta en utdragen introduktionsfas. Fallstudien visade att det var viktigt att studera måttkedjor och proportioner i det befintliga systemet för att omvandla det till ett nytt, vilket gör att processen kan bli mer materialdriven. Överväganden om hur man använder elementen för att minimera avfall och miljöpåverkan från att förbereda elementen för återanvändning är absolut nödvändiga vid utformningen av systemet. Avfall skulle kunna hävdas vara ett designfel, vilket understryker behovet av att utbilda nya arkitekter och designers i att designa för återbruk. Potential för återanvändning ligger i att bibehålla värdet på stomelementen, istället för att betala för att bli av med dem, och att undvika stora negativa miljöpåverkan för råvaruutvinning och produktion. Projekt som genomförs idag har visat på stora besparingar i både CO2-ekvivalenter och kostnader. Men det kräver et innovativ och icke-konventionell organisation och roller. Samarbete och förtroende mellan intressenter är centralt. Designprocessen måste bli mer kollaborativ och iterativ med högre frekvens av informationsutbyte. Detta kräver att konsulter ser både bakåt, förstår de befintliga byggnaderna och materialen som vi kan använda, och framåt, i hur man kan använda dem framåt med innovativa strategier för både genomförbarhet, miljö, bestående arkitektur. Architectural elements urban metabolism demolition deconstruction design process structural elements concrete steel circular construction circular economy material harvesting urban mining Arkitektoniska element urban metabolism rivning dekonstruktion designprocess tunga stomelement betong stål cirkulärt byggande cirkulär ekonomi material harvesting urban mining Engineering and Technology Teknik och teknologier
9	End-Of-Life Wind Turbines in the EU : An Estimation of the NdFeB-Magnets and Containing Rare Earth Elements in the Anthropogenic Stock of Germany and Denmark / Uttjänta vindturbiner i EU: En uppskattning av tillgången på sällsynta jordartsmetaller i NdFeB-magneter i vindturbinsbeståndet i Tyskland och Danmark Welzel, Lisa January 2019 (has links) Securing rare earth elements (REE) for a stable supply require sustainable management strategies in Europe due to a missing local primary production and a dependence on China as the main producer of REE. These elements, like neodymium (Nd) and dysprosium (Dy), are contained in permanent magnets (PM) (mostly NdFeB-magnets) in wind turbines. Addressing the question whether PM-material, Nd- and Dy-contents from wind turbines could help to meet future demands of REE in Europe while reducing simultaneously the import dependence, the purpose of the present work was to analyze the urban mining opportunities, recovery - and recycling potentials for REE from end-of-life (EoL) wind turbines. This thesis aimed to identify current and upcoming stocks as well as material flows of the PM and their containing REE in the wind energy sector. Two European countries, Germany and Denmark, were chosen as case studies to be compared based on created future scenarios and the modeling of the theoretical recycling potential of Nd and Dy in both countries. It could have been identified that the German anthropogenic stock contains greater amounts of NdFeB-magnets and REE compared to the Danish stock. Overall it could be concluded that the countries’ demand could partly be met by using secondary Nd and Dy from the EoL-wind turbines. Although future scenarios were used, the results realistically illustrate the German and Danish anthropogenic stock until 2035 by relying on data of already installed turbines up to 2018, which makes an evaluation of capacities and EoL-turbines, which need to be decommissioned by 2035, achievable. The provided information is valuable for further investigations regarding recovery strategies, feasibility analysis, and future decision-making processes. / För att säkra tillgången på jordartsmetaller (REE) i Europa krävs hållbara beslutsstrategier. Detta på grund av avsaknaden av en inhemsk primärproduktion samt ett beroende av Kina som en huvudprodu-cent av REE. Jordartsmetaller som neodymium (Nd) och dysprosium (Dy), finns kvar i permanenta magneter (PM) (mestadels NdFeB-magneter) i vindturbiner. För att ta itu med frågan om huruvida Nd- och Dy-innehållet i PM-material, från vindturbiner skulle kunna bidra till att uppfylla framtida efter-frågan på REE i Europa samtidigt som importberoendet skulle minskas, var syftet med detta arbete att analysera möjligheterna till urban utvininng, återvinning och materialutnyttjande av REE från vindtur-biner i uttjänt tillstånd (EoL).Syftet med denna uppsats var att identifiera nuvarande och kommande tillgångar samt materialflöden av PM och därav följande REE inom vindkraftsektorn. Två europeiska länder, Tyskland och Danmark, valdes ut som fallstudier och jämfördes i framtida scenarier och mo-dellering av Nd -och Dy teoretiska återvinningspotential i båda länderna. Det kunde konstaterats att det tyska antropogena beståndet innehåller större mängder NdFeB-magneter och REE än det danska beståndet. Sammanfattningsvis kan man dra slutsatsen att ländernas efterfrågan delvis kunde tillgodo-ses genom att man använde sekundär Nd och Dy från EoL-vindturbiner. Även om framtida scenarier användes illustreras resultatet på ett realistiskt sätt det det antropogena lagret i Tyskland och Danmark fram till 2035 genom att man förlitar sig på uppgifter om redan installerade turbiner fram till 2018, vilket gör det möjligt att göra en utvärdering av kapaciteten och antal EoL-turbiner, som måste av-vecklas senast 2035. Informationen är värdefull för ytterligare utredningar om återvinningsstrategier, genomförbarhetsanalys och framtida beslutsprocesser. rare earth elements neodymium dysprosium wind turbines permanent magnets recycling recovery closing the loop urban mining sustainability sällsynta jordartsmetaller neodymium dysprosium vindturbiner permanenta magneter återvinning cirkulärt system hållbarhet Earth and Related Environmental Sciences Geovetenskap och miljövetenskap
10	Staden som gruva : I fäders spår för framtids segrar / Urban mining : Past, present and future of recycling of disconnected underground infrasystems Gustafsson, Marcus January 2012 (has links) Naturens mineralresurser är till viss del utnyttjade och uttömda, och framtiden är osäker och omdebatterad. Ingen vet säkert exakt hur mycket metall som finns kvar i jordskorpan, hur mycket som går att utvinna eller hur länge resurserna kommer att räcka. Samtidigt har vi byggt in rena metallådror i våra städer i form av elkablar, telekablar och fjärrvärmerör. Många av dem används givetvis, men många är också uttjänta och urkopplade, och därmed tillgängliga för återvinning.Syftet med denna studie är att klarlägga hinder, drivkrafter och möjligheter för metallåtervinning av urkopplade infrasystem i mark inom lokala el-, tele- och fjärrvärmenät i Sverige. För att uppnå detta tillfrågades Sveriges tio största ägare av underjordiska lokala elnät om bl.a. sina rutiner för urkopplade ledningar och genomförda projekt där ledningar tagits upp. Samma bolag frågades även om sina respektive fjärrvärmenät. Utöver dessa ingick telenätägaren Skanova, kommuner med anknytning till de tillfrågade nätägarna, metallåtervinningsföretag, entreprenörer och myndigheter i studien. Dessutom gjordes en litteraturstudie på området metallåtervinning.De viktigaste drivkrafterna för upptagning och återvinning av urkopplade infrasystem i mark visade sig vara ekonomi, utrymmeskonflikt i ledningsgatorna, krav i form av lagar, avtal eller egen policy, samt risk för miljöpåverkan. Alla förutom utrymmeskonflikt kan dessutom, beroende på omständigheterna, vara hinder för återvinning. En viktig möjliggörande faktor är att ledningens läge är känt och att den inte riskerar att förväxlas med andra ledningar.I dag är det vanligt att ledningar ligger kvar i marken en tid efter att de tagits ur bruk. I de fall de tas upp sker det ofta i samband med andra grävarbeten längs ledningen. Miljörisker, utrymmeskonflikter och krav kan tvinga fram upptagning av en ledning, medan ekonomi, med nuvarande metallpriser, är mer av ett hinder. Om återvinning av ledningar i mark ska bli norm krävs det att lönsamheten ökar. Detta kan ske genom ökade metallpriser, användande av alternativa metoder för upptagning, ett bredare synsätt som tar hänsyn till att återvinning kan minska behovet av primära metallresurser, eller kanske subventionering av återvunnen metall. Hårdare lagstiftning skulle kunna tvinga fram ökad återvinning, men för att alla inblandade ska vara med på det är det bättre att låta marknadskrafterna styra och att det baseras på frivillighet.Om återvinningen av infrasystem i mark ska ökas måste det göras insatser på flera nivåer. Nya metoder, som utvecklas av fristående entreprenörer, kan göra återvinning mer lönsam. Nationella mål och riktlinjer bör tas fram av Naturvårdsverket för att vägleda nätägare och markägare. Om ekonomiska styrmedel behövs måste det beslutas om av Riksdagen. Branschorganisationer och länsstyrelser kan samordna arbetet bland sina medlemmar och inom sina regioner. Markägarna måste sedan komma överens med nätägarna om vad som är lämpligt och vad som fungerar för just deras områden. / Earth’s natural mineral resources have, to some extent, already been used and depleted, and the future is both uncertain and debated. No one knows for certain exactly how much metal there is left in Earth’s crust, how much we can extract or for how long the resources are going to last. Meanwhile, we have installed ores of metal in our cities, in the form of electric cables, telecom cables and district heating pipes. Many of these are of course in use, but many have also reached end of life and been disconnected, and are thus available for recycling.The purpose of this study is to clarify barriers, drivers and enablers for metal recycling of disconnected underground infrasystems within the local electricity, telecom and district heating networks in Sweden. In order to do this, ten of Sweden’s largest owners of local underground electricity networks were asked e.g. about their routines and about projects where cables were taken up. The same companies were also asked about their district heating networks. Apart from these, the study included the telecom network owner Skanova, municipalities with connections to the ten electricity network companies, metal recycling companies, contractors and authorities. Furthermore, a literature study on metal recycling was conducted.The main drivers for taking up and recycling disconnected underground infrasystems proved to be economy, conflicts of space in the ground, rules and regulations in terms of legislations, contracts or company policies, and environmental impact risks. All of these, except for conflicts of space, could also, depending on the circumstances, be barriers for recycling. One important enabler is to know the exact position of the cables or pipes and that they don’t risk being confused with other cables or pipes.Presently, cables and pipes are commonly left in the ground for some time after they have been taken out of service. When they are eventually taken up, it is often done simultaneously with other digging operations along the cable or pipe. Environmental risks, conflicts of space and rules and regulations can force the excavation of cables and pipes, while economy, with current metal prices, is more of a barrier. If recycling of underground infrasystems is to become norm, the profitability needs to increase. This can occur through increased metal prices, use of alternative excavation methods, a wider view that takes into account that increased recycling can decrease the need for primary metal resources, or perhaps through subsidization of recycled metals. Tougher legislations could force a higher recycling rate, but in order to include all involved parts and not upset anyone, it is better to let the market drive and base it all on free will.If the recycling of underground infrasystems is to increase, efforts must be made on several different levels. New methods, developed by independent entrepreneurs, could make recycling more profitable. National goals and guidelines should be presented by the Swedish EPA, to guide and direct network owners and landlords. If financial instruments are needed, these must be decided upon by the parliament. Business associations and county administrations can coordinate the work among their members and within their regions. The landlords and the network owners must then agree on what is appropriate and applicable for their specific areas. "Urban mining" "Technospheric mining" infrasystem "urkopplade ledningar" "industriell miljöteknik" "Gustav Vasa" "Staden som gruva" "Städer som gruvor"

Search results