The City of Manchester, once the birthplace of the 1st Industrial Revolution, is today a pioneering hub of the 4th Industrial Revolution (Industry 4.0), offering Industry 4.0 solutions in advanced materials, engineering, healthcare and social sciences. Indeed, the creation of some of the citys greatest academic institutions was a direct outcome of the industrial revolution, so it was something of a homecoming that the Sustainable Smart Manufacturing (S2M) Conference was hosted by The University of Manchester in 2019.
The conference was jointly organised by The University of Manchester, The University of Lisbon and The Polytechnic of Leiria the latter two bringing in a wealth of expertise in how Industry 4.0 manifests itself in the context of sustainably evolving, deeply-rooted cities.
S2M-2019 instigated the development of 61 papers selected for publication in this book on areas of Smart Manufacturing, Additive Manufacturing and Virtual Prototyping, Materials for Healthcare Applications and Circular Economy, Design Education, and Urban Spaces.
| Preface |
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| Committee members |
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| Keynote speakers |
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| International scientific committee |
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Towards a digital revolution in the UK apparel manufacturing: An industry 4.0 perspective |
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3 | (6) |
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Towards fault detection and self-healing of chemical processes over wireless sensor networks |
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9 | (6) |
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Pattern recognition based on neural network for sign language interpretation system using flexes sensor |
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15 | (3) |
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A framework for intelligent monitoring and control of chemical processes with multi-agent systems |
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18 | (6) |
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The transport of domestic animals and the Internet of Things: Guidelines for the development of a smart carrier |
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24 | (6) |
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Development of production monitoring systems on labor-intensive manufacturing industries |
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30 | (5) |
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Importance of maturity assessments in promoting adoption of i4.0 concepts in SMEs |
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35 | (6) |
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Fashion segment and Industry 4.0: Brazilian textile and clothing industry -- perspective into the new industrial paradigms |
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41 | (6) |
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Jumping to Industry 4.0 through process design and managing information for smart manufacturing: configurable virtual workstation |
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47 | (5) |
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A framework for Industry 4.0 implementation: A case study at King Saud University |
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52 | (5) |
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Health and safety in smart industry: State-of-the-art and future trends |
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57 | (6) |
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BIM - based machine learning engine for smart real estate appraisal |
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63 | (6) |
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Data analytics applied to sand casting foundry industries |
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69 | (6) |
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The role of "JavaMach Cluster" to training for Industry 4.0 |
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75 | (4) |
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Machine learning approach for biological pattern based shell structures |
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79 | (5) |
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Machine learning, the Internet of Things, and the seeds of un-behavioral operations: Conceptual bases for the industry of the future |
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84 | (6) |
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Two-phase methodology for smart reconfigurable assembly systems |
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90 | (5) |
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A screw unfastening method for robotic disassembly |
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95 | (6) |
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Using active adjustment and compliance in robotic disassembly |
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101 | (5) |
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An ontology for sensors knowledge management in intelligent manufacturing systems |
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106 | (6) |
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Long range RFID indoor positioning system with passive tags |
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112 | (7) |
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Additive manufacturing and virtual prototyping |
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3D printing for sustainable construction |
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119 | (5) |
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Galvanometer calibration using image processing for additive manufacturing |
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124 | (6) |
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A multi-material extrusion nozzle for functionally graded concrete printing |
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130 | (6) |
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Analysis of 3D printed 17-4 PH stainless steel lattice structures with radially oriented cells |
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136 | (6) |
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Control of process parameters for directed energy deposition of PHI 5-5 stainless steel parts |
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142 | (6) |
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Investigation into post-processing electron beam melting parts using jet electrochemical machining |
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148 | (7) |
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Manufacturing of a hollow propeller blade with WAAM process - from the material characterisation to the achievement |
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155 | (6) |
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Fully 3D printed horizontally polarised omnidirectional antenna |
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161 | (6) |
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Paper in architecture: The role of additive manufacturing |
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167 | (6) |
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Towards an integrated sensor system for additive manufacturing |
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173 | (6) |
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3D printing artefacts made of the ashes after the fire of the National Museum in Brazil |
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179 | (4) |
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Slot-Die simulations for 3D printing of Perovskite Solar Cells (PSCs) |
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183 | (5) |
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Remote monitoring and controlling of an additive manufacturing machine |
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188 | (5) |
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Virtual prototyping for fashion 4.0 |
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193 | (4) |
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Could the food market pull 3D printing appetites further? |
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197 | (7) |
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Configuration of fashion design in the contemporaneity: Innovation through additive manufacturing |
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204 | (6) |
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Multimodal virtual reality based maintenance training system for Industry 4.0 |
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210 | (6) |
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Knowledge-driven holistic decision making supporting multi-objective innovative design |
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216 | (6) |
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Portable eye tracking and the study of vision |
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222 | (7) |
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Materials for healthcare applications and circular economy |
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Self-assembly of a bioinspired, photoactive-centered nanocontainer for drug delivery |
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229 | (5) |
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Physical and biological properties of electrospun PCL meshes as a function of polymer concentration and voltage |
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234 | (6) |
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Microcrystalline cellulose as filler in polycaprolactone matrices |
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240 | (6) |
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Towards a circular economy - recycling of polymeric waste from end-of-life vehicles, electrical and electronic equipment |
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246 | (7) |
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Ligno project: Development of composite waste material from wood and MDF applied to the design |
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253 | (10) |
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A multi-platform virtual practice for education in chemical engineering |
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263 | (6) |
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Can Digital Fabrication education affect the South African Science, Technology and innovation objectives through curriculum infiltration? |
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269 | (6) |
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TERA SABI: Meta-design between design education and craft industry |
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275 | (5) |
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The materials platforms and the teaching of product design |
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280 | (4) |
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Action Research: A strategical methodology for applied research |
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284 | (6) |
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Fashion design course, a collaborative online learning experience |
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290 | (6) |
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Design drawing/drawing design |
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296 | (7) |
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Modularization of integrated photovoltaic-fuel cell system for remote distributed power systems |
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303 | (6) |
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Control systems of regional energy resources as a digital platform for smart cities |
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309 | (5) |
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Climate Smart Cities in architecture knowledge nowadays |
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314 | (6) |
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A.C. Figueiredo de Oliveira |
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Collaborative fabrication 1:1 scale Prototyping and its space experiencing |
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320 | (5) |
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Prefabrication in construction: A preliminary study in India and Portugal |
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325 | (6) |
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From conflicts to synergies between mitigation and adaptation strategies to climate change: Lisbon Sponge - City 2010-2030 |
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331 | (6) |
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Designing inclusive hospital wayfinding |
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337 | (6) |
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The building to let in Lisbon, a built resource for a sustainable city |
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343 | (6) |
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BREEAM and LEED in architectural rehabilitation |
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349 | (5) |
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| Author index |
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354 | |
Paulo Bartolo is Head of the Manufacturing Group and Innovative Manufacturing Theme at the School of Mechanical, Aerospace and Civil Engineering, The University of Manchester. He is the Universitys Industry 4.0 Academic Lead, theme leader of the Industry 4.0 Societal Challenge at Digital Futures and sits on the Management Board of the Centre for Doctoral Training in Regenerative Medicine funded by the Engineering and Physical Sciences Research Council (EPSRC) and the Medical Research Council (MRC). He authored more than 600 publications in journal papers, book chapters and conference proceedings, co-edited 18 books and holds 14 patents, is the Founding Editor of the Virtual and Physical Prototyping Journal (Taylor & Francis) and Editor-in-Chief of Biomanufacturing Reviews (Springer). He has been engaged in around 90 research projects funded by the EPSRC, Innovate UK, Bill and Melinda Gates Foundation, the Royal Society, the Portuguese Foundation for Science and Technology, the Portuguese Agency for Innovation, the European Commission, as well as industry. Paulo is a Fellow of the International Academy of Production Engineering and chairs their Scientific Technical Committee on Electro-Physical and Chemical Processes. He is also member of the MANUFUTURE High Level Group, advisor to the Brazilian Institute of Biofabrication and several national and international funding agencies.
Fernando Moreira da Silva is Full Professor of Design at the Lisbon Faculty of Architecture, Universidade de Lisboa, and has been President of CIAUD - Research Centre for Architecture, Urbanism and Design - since 2009. He obtained his PhD in Built Environments from the University of Salford (Greater Manchester) and the Technical University of Lisbon. His early research work included Inclusive Design, Communication Design and Colour (University of Salford) and Aggregation in Design (Universidade de Lisboa). He has been Coordinator for: the PhD degree in Design at the Faculty of Architecture, Universidade de Lisboa since 2006, the International PhD degree in Design and Innovation (with the Universitą della Campania, Naples, Italy) since 2012, and the Evaluation Panel for PhD grants in Design, Architecture and Urbanism for FCT (Foundation of Science and Technology, Portugal) since 2007. He has also been CnPq International Evaluator, for research projects, Brazil, since 2012. Fernando is Honorary Researcher at the Surface Inclusive Design Research Centre, University of Salford. He is a regular participant in collaborations with national and international universities, jury member in several international competitions, and member of the scientific commissions of several international scientific journals. He has coordinated or participated in several research projects funded by FCT and the EU, published many papers in peer-reviewed scientific journals, and written three books and several book chapters.
Shaden Jaradat has been Manager of the Sustainable Smart Manufacturing (S2M) conference in Manchester in 2019, which instigated the papers published in this book. He obtained his BA and MSci in Natural Sciences from the University of Cambridge in 2002 and a PhD in Physics from The University of Manchester in 2006 on the topic of Synchrotron Studies of Liquid Crystals. He worked as a Research Associate in the Nonlinear Dynamics and Liquid Crystals Group and the Biological Physics Group, University of Manchester, between 2007 and 2012. He then moved to the Universitys International Development Division where he developed and managed a number of overseas collaborations and strategic relations. In 2018, Shaden joined the Research Strategy Team in the Faculty of Science and Engineering and has since supported the development of the Universitys Industry 4.0 Strategy. He has also been coordinating some of the Universitys strategic research proposals around smart manufacturing and circular economy, and liaised between the University and the Greater Manchester Combined Authority on Industry 4.0 aspects of Manchesters industrial strategy. He published over 17 papers in peer-reviewed journals including Soft Matter, Applied Physics Letters and Journal of Materials Chemistry, co-edited a Special Issue on Advancements in Mechatronics and Manufacturing Propelling Industry 4.0 in the International Journal of Mechatronics and Manufacturing Systems, and co-authored several articles in Industry 4.0 focussed periodicals.
Helena Bįrtolo is Professor of Sustainable Construction at the Department of Civil Engineering, Polytechnic of Leiria (PIL), Portugal. She holds a PhD degree in Construction Management from the University of Reading, UK, a Master of Science degree in Structural Engineering from the University of Porto and a Licenciatura degree from the University of Coimbra, Portugal. Helena is currently a member of the Research Centre for Architecture, Urbanism and Design (CIAUD) of the Lisbon School of Architecture, and has been a founding member of the PIL Centre for Rapid and Sustainable Product Development. Her areas of interest focus on sustainable construction, circularity in construction, bio-inspired computational techniques to support conceptual design, technology innovations in the built environment, new materials for digital construction and advanced additive manufacturing processes. Helena is also co-editor of several books and co-author of about 80 scientific papers published in peer review international journals, book chapters and conference proceedings. She was Co-chair of the International Conferences on Sustainable Intelligent Manufacturing (SIM), and the International Conferences on Sustainable Smart Manufacturing (S2M). She participated in national and international projects funded by the European Commission, the British Council, the Portuguese Agency for Innovation, the Portuguese Foundation for Science and Technology, the Portuguese Institute for SMEs and Innovation, and industry.
