Relevant bibliographies by topics / Sustainable Manufacturing

Academic literature on the topic 'Sustainable Manufacturing'

Author: Grafiati
Published: 4 June 2021
Last updated: 14 March 2023

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Journal articles on the topic "Sustainable Manufacturing"

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Rashid, Mohd Warikh Abd, Fariza Fuziana, Effendi Mohamad, Mohd Rizal Saleh, Teruaki Ito, and Toshihiro Moriga. "Aluminium Alloy Recycling for Sustainable Manufacturing." Proceedings of Manufacturing Systems Division Conference 2016 (2016): 504. http://dx.doi.org/10.1299/jsmemsd.2016.504.

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Wang, Lihui, Xun Xu, Robert Gao, and Andrew Y. C. Nee. "Sustainable cybernetic manufacturing." International Journal of Production Research 57, no. 12 (June 18, 2019): 3799–801. http://dx.doi.org/10.1080/00207543.2019.1598153.

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Frăţilă, Domniţa, and Horaţiu Rotaru. "Additive manufacturing – a sustainable manufacturing route." MATEC Web of Conferences 94 (2017): 03004. http://dx.doi.org/10.1051/matecconf/20179403004.

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GÜNTHER, Seliger. "Approaches for sustainable manufacturing." Chinese Journal of Mechanical Engineering (English Edition) 20, no. 01 (2007): 86. http://dx.doi.org/10.3901/cjme.2007.01.086.

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Gupta, Surendra M., Aşkıner Güngör, Kannan Govindan, Eren Özceylan, Can Berk Kalaycı, and Rajesh Piplani. "Responsible & sustainable manufacturing." International Journal of Production Research 58, no. 23 (November 19, 2020): 7181–82. http://dx.doi.org/10.1080/00207543.2020.1841968.

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Seliger, G., H. J. Kim, S. Kernbaum, and M. Zettl. "Approaches to sustainable manufacturing." International Journal of Sustainable Manufacturing 1, no. 1/2 (2008): 58. http://dx.doi.org/10.1504/ijsm.2008.019227.

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UMEDA, Yasushi, and Jun FUJIMOTO. "Globalization in Sustainable Manufacturing." Journal of the Japan Society for Precision Engineering 74, no. 1 (2008): 16–19. http://dx.doi.org/10.2493/jjspe.74.16.

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Shojaeipour, Shahed. "Sustainable manufacturing process planning." International Journal of Advanced Manufacturing Technology 78, no. 5-8 (January 9, 2015): 1347–60. http://dx.doi.org/10.1007/s00170-014-6705-7.

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Mohd Farid, Nur Sarah Hidayah, Nurazwa Ahmad, and Noor Aslinda Abu Seman. "THE RELATIONSHIP BETWEEN SUSTAINABLE MANUFACTURING PRACTICES AND SUSTAINABLE PERFORMANCE IN MANUFACTURING SECTOR." International Journal of Innovation and Industrial Revolution 3, no. 8 (September 30, 2021): 10–30. http://dx.doi.org/10.35631/ijirev.38002.

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The implementation of sustainable manufacturing practices has brought many benefits not only to the manufacturing industry itself but also to the environment. Among the benefits are increasing productivity, bringing a good image, and producing environmentally friendly products. However, there are still many manufacturing organizations that still do not implement sustainable manufacturing practices due to factors such as high cost and organizational culture that does not accept such practices. Thus, this study aims to identify the relationship between sustainable manufacturing practices (SMP) and the sustainable performance of manufacturing organizations. Data were collected based on quantitative methods using a questionnaire survey. This study employed a simple random sampling method and SPSS was used to analyze the descriptive and correlation data for a sample of 51 manufacturing companies in Johor. Clean production practices and employee relations show a significant relationship with sustainable performance. Eco-efficiency practices show no relationship to economic sustainability, yet there is a significant relationship to environmental sustainability and social sustainability. The benefit of this study is that manufacturing organizations can see some SMPs acting as drivers to improve the sustainable performance of the organization because of the long-term benefits it offers.
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Singh, Karmjit, and Ibrahim Sultan. "Sustainable Manufacturing Modelling: A Case for Milling Process." International Journal of Materials, Mechanics and Manufacturing 7, no. 1 (February 2019): 46–50. http://dx.doi.org/10.18178/ijmmm.2019.7.1.427.

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Dissertations / Theses on the topic "Sustainable Manufacturing"

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Alayón, Claudia. "Exploring sustainable manufacturing principles and practices." Licentiate thesis, Tekniska Högskolan, Högskolan i Jönköping, JTH, Industriell organisation och produktion, 2016. http://urn.kb.se/resolve?urn=urn:nbn:se:hj:diva-32016.

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The manufacturing industry remains a critical force in the quest for global sustainability. An increasing number of companies are modifying their operations in favor of more sustainable practices. It is hugely important that manufacturers, irrespective of the subsector they belong to, or their organizational size, implement practices that reduce or eliminate negative environmental, social and economic impacts generated by their manufacturing operations. Consequently, scholars have called for additional studies concerning sustainable manufacturing practices, not only to address the paucity of related literature, but also to contribute to practitioners’ understanding of how to incorporate sustainability into their operations. However, apart from expanding the knowledge of sustainable manufacturing practices, it is first key to understand the ground set of values, or principles, behind sustainable manufacturing operations. For that reason, the purpose of this thesis is to contribute to the existing body of knowledge regarding sustainable manufacturing principles and practices. The results presented in this thesis are based on three studies: a systematic literature review exploring sustainability principles applicable to manufacturing settings, and two empirical studies addressing sustainable manufacturing practices. In general, it is concluded from the literature that there is a little knowledge about sustainability principles from a manufacturing perspective. In relation to the most common sustainable manufacturing practices, it is concluded that these practices mainly refer to energy and material management, and waste management. Similarly, the study of the adherence of sustainable manufacturing practices to sustainable production principles concluded that the principles concerning energy and materials conservation, and waste management were found to create the highest number of practices. Although most manufacturers still engage in reactive sustainable manufacturing practices driven by regulatory and market pressures, some industrial sectors were found to be more prone to develop proactive sustainable manufacturing strategies than others. Furthermore, SMEs were found to lag behind large organizations regarding adherence to sustainable manufacturing principles.
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Mohanty, Smruti Smarak, and Rohan S. Jagtap. "Sustainable Manufacturing: Green Factory : A case study of a tool manufacturing company." Thesis, Uppsala universitet, Institutionen för samhällsbyggnad och industriell teknik, 2020. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-414983.

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Efficient use of resources and utility is the key to reduce the price of the commodities produced in any industry. This in turn would lead to reduced price of the commodity which is the key to success. Sustainability involves integration of all the three dimensions: environmental, economic and social. Sustainable manufacturing involves the use of sustainable processes and systems to produce better sustainable products. These products will be more attractive, and the industry will know more about the climate impact from their production.   Manufacturing companies use a considerable amount of energy in their production processes. One important area to understand the sustainability level at these types of industries is to study this energy use. The present work studies energy use in a large-scale tool manufacturing company in Sweden. Value Stream Mapping method is implemented for the purpose of mapping the energy use in the different operations. To complement this, an energy audit has been conducted, which is a method that include a study and analysis of a facility, indicating possible areas of improvements by reducing energy use and saving energy costs. This presents an opportunity for the company to implement energy efficiency measures, thus generating positive impacts through budget savings. Less energy use is also good for the environment resulting in less greenhouse gas emissions level. This also helps in long-term strategic planning and initiatives to assess the required needs and stabilize energy use for the long run. Social sustainability completes the triad along with environmental and economic sustainability. In this study, the latter is reflected with the company’s relationship with its working professionals, communities and society.
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Jagtap, Rohan Surendra, and Smruti Smarak Mohanty. "Sustainable Manufacturing: Green Factory : A case study of a tool manufacturing company." Thesis, Linköpings universitet, Energisystem, 2020. http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-168688.

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Efficient use of resources and utility is the key to reduce the price of the commodities produced in any industry. This in turn would lead to reduced price of the commodity which is the key to success. Sustainability involves integration of all the three dimensions: environmental, economic and social. Sustainable manufacturing involves the use of sustainable processes and systems to produce better sustainable products. These products will be more attractive, and the industry will know more about the climate impact from their production. Manufacturing companies use a considerable amount of energy in their production processes. One important area to understand the sustainability level at these types of industries is to study this energy use. The present work studies energy use in a large-scale tool manufacturing company in Sweden. Value Stream Mapping method is implemented for the purpose of mapping the energy use in the different operations. To complement this, an energy audit has been conducted, which is a method that include a study and analysis of a facility, indicating possible areas of improvements by reducing energy use and saving energy costs. This presents an opportunity for the company to implement energy efficiency measures, thus generating positive impacts through budget savings. Less energy use is also good for the environment resulting in less greenhouse gas emissions level. This also helps in long-term strategic planning and initiatives to assess the required needs and stabilize energy use for the long run. Social sustainability completes the triad along with environmental and economic sustainability. In this study, the social sustainability is reflected with the company’s relationship with its working professionals by conducting a survey. The sustainable manufacturing potential found in the case study indicates that significant progress can be made in the three sustainability dimensions. Although, the scope of the thesis is limited to a tool manufacturing company, several of the findings could be implemented in other tool companies as well as industries belonging to other sectors.

The thesis is a joint report between Linköping and Uppsala University. My thesis teammate has published it before at UU Diva Portal. The URL is: https://uu.diva-portal.org/smash/record.jsf?dswid=8179&pid=diva2%3A1449223&c=1&searchType=SIMPLE&language=en&query=sustainable+manufacturing&af=%5B%22dateIssued%3A2020%22%5D&aq=%5B%5B%5D%5D&aq2=%5B%5B%5D%5D&aqe=%5B%5D&noOfRows=50&sortOrder=author_sort_asc&sortOrder2=title_sort_asc&onlyFullText=false&sf=undergraduate

 


Green Factory project, AB Sandvik Coromant
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Batley, A. "Sustainable improvement processes for 21st century manufacturing enterprises." Thesis, Open University, 2006. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.494572.

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Bautista, Lazo Samuel. "Sustainable manufacturing : turning waste into profitable co-products." Thesis, University of Liverpool, 2013. http://livrepository.liverpool.ac.uk/12933/.

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At 2009 rates of disposal, there are only 8 years of remaining landfill capacity at permitted sites in England and Wales. Industry – encouraged by financial penalties from the Government – faces the challenges of cleaner and more sustainable production whilst trying to remain competitive in the market place. This thesis presents development of several theoretical propositions: a ‘fit thinking’ design framework, the ‘All Seeing Eye of Business’ (All-SEB) and the ‘waste alchemist’ industrial role. The ALL-SEB is a model to understand the impact and potential uses of manufacturing waste. The insights provided by the All-SEB model, resulted in a general waste elimination framework developed to serve as a guiding strategy for waste elimination. The main objective of this study was to investigate a major hypothesis derived from the All-SEB: unavoidable waste could be transmuted into profitable co-products as a measure to divert waste from landfill. The ATM (analyse, transform and market) methodology was developed as a way to help companies transmute waste into ‘co-products’. A tool for idea generation (the wheel of waste) was developed to be used in the Analysis phase of the ATM methodology. Case study research was undertaken in order to test the ATM methodology and the way in which unavoidable waste could be transmuted into a profitable co-product in a real world manufacturing setting. The case study results revealed the generative mechanisms that enable waste transmutation into profitable co-products; based on these findings a refined ATM methodology for waste transmutation was proposed. The implementation of the theoretical propositions in industrial settings shed light into strategic aspects of resource efficiency: from waste prevention through ‘fit thinking’, to manufacturing process innovation all the way to a better company integration into the industrial ecosystem. Companies looking to achieve zero waste to landfill status would benefit from using the refined ATM methodology. It was found that the ATM methodology and the wheel of waste are useful to several other actors in the industrial ecosystem: waste management companies looking to transform themselves into ‘resource and energy providers’, to external consultants and to third party companies dubbed ‘waste alchemists’ that could offer waste transmutation services to manufacturers.
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Batley, Alun. "Sustainable improvement processes for 21st century manufacturing enterprises." n.p, 2003. http://ethos.bl.uk/.

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Kågesson, Gustav, and Zainalabidin Tahir. "Manufacturing processes and materials selection for a sustainable future." Thesis, Blekinge Tekniska Högskola, Institutionen för maskinteknik, 2015. http://urn.kb.se/resolve?urn=urn:nbn:se:bth-1047.

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This study focuses on different manufacturing processes and material choices for products that are designed to help the future to be more sustainable. These products were developed in a global project that explored the field and subfields of urban mining. This thesis is a part of that project and is meant to come with valuable input to the results. In this urban mining project two products were developed. The two different products that has been developed during this project is the NIX and the UM Factory. They work together with keeping material on the construction site when space is limited in order to reduce the transportation, both for the environmental benefit and also from a cost perspective. Together they will not only keep the material on the site but also refine them so they can be used again. This thesis will look into how these two products can be manufactured and what materials is a suitable choice for the products. These two factors were also thought about during the development of the products, both how to make it as simple design that was easy to produce while still fulfilling the requirements set. Also what materials might be a suitable choice for different parts of the products is considered, in order to be reliable, easy to work with, and relatively cheap. The study also explored some methods and materials that might be worth looking into in a few years. Methods and materials that today are undeveloped or not economically viable.
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McKenney, Kurtis G. (Kurtis Gifford) 1979. "Sustainable approach to achieving energy efficiency in manufacturing operations." Thesis, Massachusetts Institute of Technology, 2012. http://hdl.handle.net/1721.1/73387.

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Thesis (M.B.A.)--Massachusetts Institute of Technology, Sloan School of Management; and, (S.M.)--Massachusetts Institute of Technology, Engineering Systems Division; in conjunction with the Leaders for Global Operations Program at MIT, 2012.
Cataloged from PDF version of thesis.
Includes bibliographical references (p. 75-76).
Energy management in industrial facilities is becoming increasingly popular as firms attempt to become more environmentally responsible and reduce cost by improving operational efficiency. Raytheon is a leader in their industry in energy management, and they view the initiative as a way to become more competitive along with being environmentally responsible. The goal of this project was to develop a framework for achieving sustainable cost reduction in production operations through energy efficiency. The energy efficiency framework will build off the existing lean and six sigma tools and philosophies in an attempt to accelerate acceptance and deployment by using a common language and proven methods in the company and industry. A 1.6 million square foot manufacturing facility at Raytheon IDS consumed $13 million of energy (90% electric) in 2010, 75% of which was consumed directly by production equipment. The equipment is diffuse, highly specialized, and used in "high mix, low volume" manufacturing. The challenge with improving production energy efficiency in this environment is that it requires a combination of technology improvements, processes modifications, and changes in the way employees conduct their work every day. The project's success relied on cross-functional (i.e., operations, engineering, and facilities) engagement from senior management to front-line operators. To sustain results, energy performance metrics were designed to keep production area leaders engaged and allow management to set progressive goals over time and reward success. The proposed metrics use a combination of tracked energy use and a "best practice" scorecard that promotes proactive engagement. Lean "Energy Gemba Walks" were initiated to generate and manage best practices and to share knowledge among production areas. The implementation phase of the pilot project (October and November 2011) resulted in an 18% energy reduction compared with the average for the year. Meanwhile, production output and total labor hours were up 18% and 11%, respectively, during the pilot, while the product mix remained constant throughout the year. The improvements, if sustained, correspond to a $74,000 per year cost savings in the pilot area.
by Kurtis McKenney.
S.M.
M.B.A.
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Niakan, Farzad. "Design and configuration of sustainable dynamic cellular manufacturing systems." Thesis, Lyon, INSA, 2015. http://www.theses.fr/2015ISAL0123/document.

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La révolution la plus récente dans l'industrie (révolution industrielle 4.0) nécessite une plus grande flexibilité, agilité et efficacité dans l'utilisation des équipements de production. Le système manufacturier cellulaire dynamique (DCMS) est l'un des meilleurs systèmes de production qui répondent à ces exigences. En outre, l'importance croissante du développement durable force les fabricants et les gestionnaires à prendre en compte les enjeux environnementaux et sociaux dans la conception et la configuration des systèmes de fabrication. Cette thèse porte sur la configuration durable des DCMS en proposant trois modèles mathématiques. Le plus grand challenge de cette étude est (i) de choisir des critères sociaux et environnementaux appropriés, (ii) de les intégrer dans des modèles mathématiques et (iii) d'étudier l'impact de ces critères sur des DCMS. Le premier modèle est bi-objectif afin de faire un compromis entre certains critères sociaux (offres d'emplois, risques de la machine, etc.) et économiques (divers coûts liés à la formation de cellules). Pour être plus proche de situations de la vie réelle, certains paramètres tels que la demande, les coûts liés aux machines et la capacité en temps des machines sont considérés comme incertains. Pour résoudre ce problème, une méthode d'optimisation robuste est appliquée pour faire face à cette incertitude. Dans le deuxième modèle, toutes les dimensions du développement durable sont prises en compte dans le modèle mathématique bi-objectif proposé. La première fonction objectif modélise des critères économiques (coûts) et la seconde des aspects environnementaux (déchets de production), tandis que certaines contraintes représentent des questions sociales (principalement le « Daily Noise » à cause de la complexité de calcul). En raison de la NP-difficulté du problème, une nouvelle approche novatrice appelée NSGA II-MOSA est proposée. Le troisième modèle proposé a trois fonctions objectif, une pour chaque type d’enjeux : environnemental, social et économique. Afin d'être proche de la vie réelle, certains paramètres du modèle sont exprimés en termes de valeur floue. Nous proposons une méthode possibiliste hybride pour faire face à l'incertitude et une approche floue interactive est considérée pour résoudre un modèle multi-objectif déterministe pour des solutions de compromis. Enfin, la dernière partie de la thèse étudie la possibilité d'appliquer les trois modèles proposés à l’industrie grâce à une méthode plus facile. Une approche d'optimisation-simulation innovante est introduite pour faire face à la configuration de DCMS : (i) La phase d'optimisation fonctionne comme méthode de fractionnement de scénarii pour réduire le nombre de configurations alternatives en se concentrant sur les niveaux stratégique et tactique. (ii) Ensuite, un outil de simulation détaille le niveau opérationnel en étudiant la performance de chaque alternative et l'interaction entre plusieurs composants de cellules
The most recent revolution in industry (Industrial Revolution 4.0) requires increased flexibility, agility and efficiency in the use of production equipment. Dynamic Cellular Manufacturing System (DCMS) is one of the best production systems to meet such requirements. In addition, the increasing importance of sustainable development forces manufacturers and managers to take account of the environmental and social issues in the design and configuration of manufacturing systems. This thesis focuses on the sustainable configuration of DCMS by proposing three mathematical models. The main challenge of this study is to (i) choose appropriate social and environmental criteria, (ii) integrate them in mathematical models, and (iii) study the impact of these criteria on DCMS. The first model is bi-objective in order to make a trade-off between some social (job opportunity, potential machine hazards, etc.) and economic (various costs related to cell formation) criteria. To get closer to real-life situations, some parameters such as demand, machine-related costs and time capacity of the machines are considered as uncertain. To solve this problem, a robust optimization method is applied to cope with this uncertainty. In the second model, all dimensions of sustainable development are taken into account in a new bi-objective mathematical model. The first objective function models economic criteria (costs) and the second one environmental aspects (production waste), while social issues (mainly Daily Noise Dosage because of computational complexity) are modeled as constraints. Due to the NP-hardness of the problem, a new innovative approach called NSGA II-MOSA is proposed. The last model has three objective functions, one for each dimension of the sustainable development: environmental, social and economic. In order to be close to real life, some parameters of the model are expressed in terms of fuzzy value. We propose a hybridized possibilistic method to deal with uncertainty and an interactive fuzzy approach is considered to solve an auxiliary crisp multi-objective model in order to find trade-off solutions. Finally, the last part of the thesis studies the possibility to apply the three proposed models to the industry thanks to an easier method. A novel optimization-simulation approach is introduced to deal with the configuration of DCMS: (i) the optimization phase operates as scenario fraction method in order to reduce the number of alternative configurations by focusing on strategic and tactical levels; (ii) next, a simulation tool investigates the operational level by studying the performance of each alternative and the interaction between several components of the cells
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Plant, Alexander Victor Charles. "Standards in sustainable engineering and design." Thesis, Brunel University, 2012. http://bura.brunel.ac.uk/handle/2438/6559.

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The financial and environmental costs associated with the manufacture and consumption of products may be reduced through design for efficient production, service life extension and post-consumer value recovery. In response to today’s need to design with consideration for the whole product life cycle, British Standards Institution (BSI) published BS 8887-1 (2006) Design for Manufacture, Assembly, Disassembly and End-of-life processing (MADE). Original research into the distribution and use of this first part of the MADE series is reported in this thesis. The organizations that accessed BS 8887-1 were categorised using their Standard Industrial Classification (SIC) code. The results are presented graphically in multilevel charts using the hierarchical structure of the SIC system. The study found that the majority of standards users that purchased or downloaded BS 8887-1 were companies in the manufacturing sector and particularly electronics producers. Educational institutions also showed high levels of interest in the standard. For the first time, the use of BS 8887-1 in practice has been investigated. The purpose was to discover if, why and how it is being used and to identify examples of its application in design practice. This was accomplished through semi-structured interviews with design practitioners from both industry and academia, thus helping to explain the results of the earlier SIC study. The information gathered through the interviews shows how BS 8887-1 has informed the design process and how it has been used in combination with various design and management techniques e.g. Advanced Product Quality Planning (APQP). These studies suggest that demand for the standard has been stimulated by the introduction of Extended Producer Responsibility (EPR) legislation, especially the Waste Electrical and Electronic Equipment (WEEE) directive. Importantly, the use of BS 8887-1 has been found to be helpful in winning new business and reducing the costs associated with manufacture, product maintenance and waste management. Based on the result of the qualitative research, a new model of the use of standards in the New Product Development (NPD) process is presented. The research was proposed by the Chairman of the BSI technical committee responsible for the BS 8887 series. The beneficiaries are BSI, industry and academia, since the investigation has shown BS 8887-1 to be of value, and has informed the continuing development of this series of standards. The thesis concludes by arguing for BS 8887 to become the basis of an International Organization for Standardization (ISO) standard in order to reach a wider audience. It also identifies a need for the standard’s design requirements to be supported with additional supplementary interpretation expanding on, and adding detail to, the information in the standard itself. Influenced by this research, at the time of writing a new BSI working group was being formed to consider developing BS 8887 as an ISO standard. BSI had also begun the process of commissioning a handbook to assist designers in the practical application of BS 8887 in industrial design.
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Books on the topic "Sustainable Manufacturing"

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Davim, J. Paulo, ed. Sustainable Manufacturing. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2013. http://dx.doi.org/10.1002/9781118621653.

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Stark, Rainer, Günther Seliger, and Jérémy Bonvoisin, eds. Sustainable Manufacturing. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-48514-0.

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Seliger, Günther, ed. Sustainable Manufacturing. Berlin, Heidelberg: Springer Berlin Heidelberg, 2012. http://dx.doi.org/10.1007/978-3-642-27290-5.

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Davim, J. Paulo. Sustainable manufacturing. Hoboken, NJ: John Wiley, 2010.

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Paulo, Davim J., ed. Sustainable manufacturing. Hoboken, NJ: John Wiley, 2010.

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Scholz, Steffen G., Robert J. Howlett, and Rossi Setchi, eds. Sustainable Design and Manufacturing. Singapore: Springer Singapore, 2022. http://dx.doi.org/10.1007/978-981-16-6128-0.

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Seliger, Günther, Marwan M. K. Khraisheh, and I. S. Jawahir, eds. Advances in Sustainable Manufacturing. Berlin, Heidelberg: Springer Berlin Heidelberg, 2011. http://dx.doi.org/10.1007/978-3-642-20183-7.

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Scholz, Steffen G., Robert J. Howlett, and Rossi Setchi, eds. Sustainable Design and Manufacturing. Singapore: Springer Nature Singapore, 2023. http://dx.doi.org/10.1007/978-981-19-9205-6.

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K, Khraisheh Marwan M., Jawahir I. S, and SpringerLink (Online service), eds. Advances in Sustainable Manufacturing: Proceedings of the 8th Global Conference on Sustainable Manufacturing. Berlin, Heidelberg: Springer-Verlag Berlin Heidelberg, 2011.

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Setchi, Rossi, Robert J. Howlett, Ying Liu, and Peter Theobald, eds. Sustainable Design and Manufacturing 2016. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-32098-4.

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Book chapters on the topic "Sustainable Manufacturing"

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Madu, Christian N. "Sustainable Manufacturing." In Handbook of Environmentally Conscious Manufacturing, 1–26. Boston, MA: Springer US, 2001. http://dx.doi.org/10.1007/978-1-4615-1727-6_1.

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Hauschild, Michael Z., David Dornfeld, Margot Hutchins, Sami Kara, and Francesco Jovane. "Sustainable Manufacturing." In CIRP Encyclopedia of Production Engineering, 1–7. Berlin, Heidelberg: Springer Berlin Heidelberg, 2018. http://dx.doi.org/10.1007/978-3-642-35950-7_16-4.

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Hauschild, Michael, David Dornfeld, Margot Hutchins, Sami Kara, and Francesco Jovane. "Sustainable Manufacturing." In CIRP Encyclopedia of Production Engineering, 1208–14. Berlin, Heidelberg: Springer Berlin Heidelberg, 2014. http://dx.doi.org/10.1007/978-3-642-20617-7_16.

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Hauschild, Michael Z., David Dornfeld, Margot Hutchins, Sami Kara, and Francesco Jovane. "Sustainable Manufacturing." In CIRP Encyclopedia of Production Engineering, 1695–701. Berlin, Heidelberg: Springer Berlin Heidelberg, 2019. http://dx.doi.org/10.1007/978-3-662-53120-4_16.

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Bonvoisin, Jérémy, Rainer Stark, and Günther Seliger. "Field of Research in Sustainable Manufacturing." In Sustainable Manufacturing, 3–20. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-48514-0_1.

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Seidel, Johannes, Ana-Paula Barquet, Günther Seliger, and Holger Kohl. "Future of Business Models in Manufacturing." In Sustainable Manufacturing, 149–62. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-48514-0_10.

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Halstenberg, Friedrich A., Jón G. Steingrímsson, and Rainer Stark. "Material Reutilization Cycles Across Industries and Production Lines." In Sustainable Manufacturing, 163–73. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-48514-0_11.

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Oertwig, Nicole, Mila Galeitzke, Hans-Georg Schmieg, Holger Kohl, Roland Jochem, Ronald Orth, and Thomas Knothe. "Integration of Sustainability into the Corporate Strategy." In Sustainable Manufacturing, 175–200. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-48514-0_12.

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Evans, Steve, Lloyd Fernando, and Miying Yang. "Sustainable Value Creation—From Concept Towards Implementation." In Sustainable Manufacturing, 203–20. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-48514-0_13.

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Chang, Ya-Ju, Sabrina Neugebauer, Annekatrin Lehmann, René Scheumann, and Matthias Finkbeiner. "Life Cycle Sustainability Assessment Approaches for Manufacturing." In Sustainable Manufacturing, 221–37. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-48514-0_14.

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Conference papers on the topic "Sustainable Manufacturing"

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Sarkar, Prabir, Che Bong Joung, John Carrell, and Shaw C. Feng. "Sustainable Manufacturing Indicator Repository." In ASME 2011 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. ASMEDC, 2011. http://dx.doi.org/10.1115/detc2011-47491.

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Sustainable manufacturing promotes manufacturing processes that minimize environmental and social impacts while maintaining economic benefits. To achieve this, manufacturers seek metrics and measurement methods to enable them to track the progress and manage their manufacturing processes and product designs. A number of indicator sets have been devised to analyze and score sustainable manufacturing; however, presence of many indicator sets has created difficulty in selecting the appropriate set. This paper presents a sustainability indicator repository, called Sustainable Manufacturing Indicator Repository (SMIR), an integration and extension of thirteen popular sustainability indicator sets. From an extensive review of publicly available indicator sets, the SMIR is based on five dimensions of sustainability: environmental stewardship, economic growth, social well-being, technological advancement, and performance management. The purpose of the SMIR is to provide an organized set of centralized, Web-based, open, and neutral indicators that can be accessible by small and medium size manufacturing enterprises. The SMIR can be an application as well as educational tool for manufacturers by providing them with necessary information on in-process and off-line sustainability measures.
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Reich-Weiser, Corinne, Athulan Vijayaraghavan, and David A. Dornfeld. "Metrics for Sustainable Manufacturing." In ASME 2008 International Manufacturing Science and Engineering Conference collocated with the 3rd JSME/ASME International Conference on Materials and Processing. ASMEDC, 2008. http://dx.doi.org/10.1115/msec_icmp2008-72223.

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A sustainable manufacturing strategy requires metrics for decision making at all levels of the enterprise. In this paper, a methodology is developed for designing sustainable manufacturing metrics given the specific concerns to be addressed. A top-down approach is suggested that follows the framework of goal and scope definition: (1) goal - what are the concerns addressed and what is the appropriate metric type to achieve the goal (2) scope - what is the appropriate geographic and manufacturing extent. In this methodology a distinction is made between environmental cost metrics and sustainability metrics. Utilizing this methodology, metrics focused on energy use, global climate change, non-renewable resource consumption, and water consumption are developed.
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Valivullah, Lina, Mahesh Mani, Kevin W. Lyons, and S. K. Gupta. "Manufacturing Process Information Models for Sustainable Manufacturing." In ASME 2014 International Manufacturing Science and Engineering Conference collocated with the JSME 2014 International Conference on Materials and Processing and the 42nd North American Manufacturing Research Conference. American Society of Mechanical Engineers, 2014. http://dx.doi.org/10.1115/msec2014-4105.

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Sustainable manufacturing systems use processes, methodologies, and technologies that are energy efficient and environmentally friendly. To create and maintain such systems, well-defined measurement methodologies and corresponding manufacturing information models play a crucial role to consistently compute and evaluate sustainability performance indicators of manufacturing processes that will result in reliable decision support. However, when it comes to describing sustainability of product manufacturing, the presently available methods and tools do not account for manufacturing processes explicitly and hence result in inaccurate and ambiguous decisions between alternate systems. Furthermore, there are no formal methods for acquiring and exchanging sustainability-related information that help establish a consolidated sustainability information base for decision support. This paper presents a study on the scope of the currently available manufacturing information models to incorporate sustainability. Identifying the requirements for information models that cater to sustainable manufacturing was done utilizing an earlier developed Systems Integration for Manufacturing Applications (SIMA) reference architecture model. We propose an extension to the SIMA architecture considering sustainability and refer to it as a GreenSIMA architecture. We present injection-molding unit manufacturing process as an example.
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McCusker, Edel Kathleen. "Manufacturing SME's — A sustainable approach, a sustainable leader." In 2018 2nd International Symposium on Small-scale Intelligent Manufacturing Systems (SIMS). IEEE, 2018. http://dx.doi.org/10.1109/sims.2018.8355299.

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Burow, Kay, Marco Franke, Quan Deng, Karl Hribernik, and Klaus-Dieter Thoben. "Sustainable Data Management for Manufacturing." In 2019 IEEE International Conference on Engineering, Technology and Innovation (ICE/ITMC). IEEE, 2019. http://dx.doi.org/10.1109/ice.2019.8792808.

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Lobov, Andrei, and Karl R. Haapala. "Towards sustainable manufacturing by extending Manufacturing Execution System functions." In 2019 IEEE International Conference on Industrial Technology (ICIT). IEEE, 2019. http://dx.doi.org/10.1109/icit.2019.8755102.

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Packianather, Michael S., Alan Davies, Mohamed AlNemr AlZarooni, Sajith Soman, and John White. "Manufacturing process flow improvements using simulation and sustainable manufacturing." In 2016 World Automation Congress (WAC). IEEE, 2016. http://dx.doi.org/10.1109/wac.2016.7582970.

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"Sustainable construction." In The International Conference on Sustainable Smart Manufacturing (S2M). Taylor & Francis Group, 6000 Broken Sound Parkway NW, Suite 300, Boca Raton, FL 33487-2742: CRC Press, 2017. http://dx.doi.org/10.1201/9781315198101-83.

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Li, W. D., and X. T. Cai. "Intelligent Immune System for Sustainable Manufacturing." In 2018 IEEE 22nd International Conference on Computer Supported Cooperative Work in Design (CSCWD). IEEE, 2018. http://dx.doi.org/10.1109/cscwd.2018.8465214.

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Eastlick, Dane D., Misha V. Sahakian, and Karl R. Haapala. "Sustainable Manufacturing Analysis for Titanium Components." In ASME 2011 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. ASMEDC, 2011. http://dx.doi.org/10.1115/detc2011-48854.

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Product designers are seeking effective ways to meet customer requirements, government policies, and internal business drivers for sustainability. Sustainable products encompass attributes including recyclable and renewable materials use, low energy consumption, cost competitiveness, and consideration of safety and health concerns. Beyond product attributes, however, sustainable products are cognizant of a broader life cycle perspective, which necessitates consideration of manufacturing and supply chain issues during design. Current life cycle assessment tools are often deficient in assisting design for manufacturing efforts due to coarseness of available process data or even a lack of representative process models. In addition, such tools consider only the environmental impacts and do not account for broader sustainability measures. Research with a titanium component manufacturer is addressing these deficiencies. A unit process modeling-based method is described to assist in strategic decision making to balance cradle-to-gate economic, environmental, and social attributes. A set of metrics is defined and used as a basis for comparison of design alternatives. The method is demonstrated for analysis of titanium component alternatives resulting from design for manufacturing activities. It is shown that this method can assist engineers in developing more sustainable products.
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Reports on the topic "Sustainable Manufacturing"

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Rachuri, Sudarsan, Ram D. Sriram, Anantha Narayanan, Prabir Sarkar, Jae Hyun Lee, Kevin W. Lyons, and Sharon J. Kemmerer. Sustainable manufacturing program workshop report :. Gaithersburg, MD: National Institute of Standards and Technology, 2010. http://dx.doi.org/10.6028/nist.ir.7683.

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Rachuri, Sudarsan, K. C. Morris, Utpal Roy, David Dornfeld, and Soundar Kumara. Sustainable manufacturing program workshop report. Gaithersburg, MD: National Institute of Standards and Technology, 2013. http://dx.doi.org/10.6028/nist.ir.7975.

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Rachuri, Sudarsan, and Sanjay Jain. Maturity Model Concepts for Sustainable Manufacturing. National Institute of Standards and Technology, April 2014. http://dx.doi.org/10.6028/nist.ir.7989.

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Das, Sujit, and Prashant Nagapurkar. Sustainable Coal Tar Pitch Carbon Fiber Manufacturing. Office of Scientific and Technical Information (OSTI), May 2021. http://dx.doi.org/10.2172/1784125.

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Brodsky, Alexander, Guodong Shao, and Frank Riddick. Processes Analytics Formalism for Decision Guidance in Sustainable Manufacturing. National Institute of Standards and Technology, November 2013. http://dx.doi.org/10.6028/nist.ir.7961.

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Narayanan, Anantha, David Lechevalier, KC Morris, and Sudarsan Rachuri. A methodology for handling standards terminology for sustainable manufacturing. National Institute of Standards and Technology, October 2013. http://dx.doi.org/10.6028/nist.ir.7965.

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Herbst, Diana-Lynn, and Leonard J. Mecca. Sustainable Precision Green Manufacturing: Advanced Hybrid Reactive Armor Materials. Fort Belvoir, VA: Defense Technical Information Center, April 2014. http://dx.doi.org/10.21236/ada627544.

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Ayyub, Bilal, Gerald Galloway, and Richard Wright. Proceedings of the Measurement Science for Sustainable Construction and Manufacturing Workshop Volume II. Presentations. National Institute of Standards and Technology, March 2015. http://dx.doi.org/10.6028/nist.gcr.15-986-2.

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Stershic, Jessica, Tsisilile Igogo, and Alberta Carpenter. Sustainability of the U.S. Manufacturing Sector: Use of the United Nations Sustainable Development Goals. Office of Scientific and Technical Information (OSTI), December 2021. http://dx.doi.org/10.2172/1834733.

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Woodhouse, Michael A., Brittany Smith, Ashwin Ramdas, and Robert M. Margolis. Crystalline Silicon Photovoltaic Module Manufacturing Costs and Sustainable Pricing: 1H 2018 Benchmark and Cost Reduction Road Map. Office of Scientific and Technical Information (OSTI), February 2019. http://dx.doi.org/10.2172/1495719.

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