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Additive manufacturing (AM), also known as “3D printing,” is often touted as a sustainable technology, especially for metal components, since it produces either net or near-net shapes versus traditionally machined pieces from larger mill products. While traditional machining from mill products is often the case in aerospace, most of the metal parts used in the world are made from flat-rolled metal and are quite efficient in utilization. Additionally, some aspects of the AM value chain are often not accounted for when determining sustainability. Unsettled Issues in Additive Manufacturing and Improved Sustainability in the Mobility Industry uses a set of scenarios to compare the sustainability of parts made using additive and conventional technologies for both the present and future (2040) states of manufacturing. Click here to access The Mobility Frontier: Metals, Polymers, or Composites Click here to access the full SAE EDGETM Research Report portfolio. https://doi.org/10.4271/EPR2021015
Additive manufacturing (AM), also known as “3D printing,” now provides the ability to have an almost fully digital chain from part design through manufacture and service. This “digital thread” can bring great benefits in improving designs, processes, materials, operations, and the ability to predict failure in a way that maximizes safety and minimizes cost and downtime. Unsettled Aspects of the Digital Thread in Additive Manufacturing discusses what the interplay between AM and a digital thread in the mobility industry would look like, the potential benefits and costs, the hurdles that need to be overcome for the combination to be useful, and how an organization can answer these questions to scope and benefit from the combination. Click here to access The Mobility Frontier: Metals, Polymers, or Composites Click here to access the full SAE EDGETM Research Report portfolio. https://doi.org/10.4271/EPR2021026
Now that metal additive manufacturing (MAM), also known as “metal 3D printing,” has seen its first successful implementations across the mobility industry, the question is whether it will continue to grow beyond these initial applications or remain a niche manufacturing process. Moving to broader applications will require overcoming several barriers, namely cost and rate, size, and criticality limitations. Recent progress in MAM indicates that these barriers are beginning to come down, pointing to continued growth in applications for MAM through the end of the decade and beyond. Metal Additive Manufacturing in the Mobility Industry: Looking into 2033 discusses the obstacles to future MAM growth, how they can be conquered, and what its role in the mobility industry will look like in 2033. Click here to access The Mobility Frontier: Metals, Polymers, or Composites Click here to access the full SAE EDGETM Research Report portfolio. https://doi.org/10.4271/EPR2023022
Additive manufacturing (AM), also known as “3D printing,” has transitioned from concepts and prototypes to part-for-part substitution—and now to the creation of part geometries that can only be made using AM. As a wide range of mobility OEMs begin to introduce AM parts into their products, the question between insourcing and outsourcing the manufacturing of AM parts has surfaced. Just like parts made using other technologies, AM parts can require significant post-processing operations. Therefore, as AM supply chains begin to develop, the sourcing of AM part building and their post-processing becomes an unsettled and important issue. Unsettled Aspects of Insourcing and Outsourcing Additive Manufacturing discusses the approaches and trade-offs of the different sourcing options for production hardware for multiple scenarios, including both metallic and polymer technologies and components. Click here to access The Mobility Frontier: Metals, Polymers, or Composites Click here to access the full SAE EDGETM Research Report portfolio. https://doi.org/10.4271/EPR2021023
In the early days, there were significant limitations to the build size of laser powder bed fusion (L-PBF) additive manufacturing (AM) machines. However, machine builders have addressed that drawback by introducing larger L-PBF machines with expansive build volumes. As these machines grow, their size capability approaches that of directed energy deposition (DED) machines. Concurrently, DED machines have gained additional axes of motion which enable increasingly complex part geometries—resulting in near-overlap in capabilities at the large end of the L-PBF build size. Additionally, competing technologies, such as binder jet AM and metal material extrusion, have also increased in capability, albeit with different starting points. As a result, the lines of demarcation between different processes are becoming blurred. Internal Boundaries of Metal Additive Manufacturing: Future Process Selection examines the overlap between three prominent powder-based technologies and outlines an approach that a product team can follow to determine the most appropriate process for current and future applications. Click here to access The Mobility Frontier: Metals, Polymers, or Composites Click here to access the full SAE EDGETM Research Report portfolio. https://doi.org/10.4271/EPR2022006
As metal additive manufacturing (MAM), also known as "metal 3D printing,” moves from prototype to low-rate and high-rate production for increasingly critical applications for more industries, many product teams are tasked with determining design properties for the first time in many years. Not only is it necessary to determine basic material properties, but it is also necessary to accommodate new geometries and design concepts as well. While some of the methods and approaches are common to other product forms, others are unique to MAM. Determining Design Properties for Metal Additive Manufacturing in the Mobility Industry covers the challenges in determining design properties and provides a comparison with existing technologies, along with an example and recommendations for future work. Click here to access The Mobility Frontier: Metals, Polymers, or Composites Click here to access the full SAE EDGETM Research Report portfolio.. https://doi.org/10.4271/EPR2023004
The adoption of metallic additive manufacturing (AM) for heat exchangers offers significant thermal management benefits that range from optimized heat energy transfer to supporting integrated designs that can reduce weight, size, and component numbers. The benefits offered by utilizing AM for heat exchangers transcend industries and have relevance within the aerospace and automotive industries, where new mobility requirements result in the need for efficient energy systems, increasingly efficient component design, and higher temperatures. Additive Manufacturing of Thermal Management Components in Mobility Applications examines the critical unsettled issues, such as lack of understanding regarding metal AM material performance in high-temperature applications and the absence of significant standardization that goes beyond the material grades, printing process parameters, and characterization processes for performance reliability. The report also delves into design, regulation, and certification. Click here to access the full SAE EDGETM Research Report portfolio. https://doi.org/10.4271/EPR2024004
Additive manufacturing or 3D printing, manufacturing a product layer by layer, offers large design freedom and faster product development cycles, as well as low startup cost of production, on-demand production and local production. In principle, any product could be made by additive manufacturing. Even food and living organic cells can be printed. We can create, design and manufacture what we want at the location we want. 3D printing will create a revolution in manufacturing, a real paradigm change. 3D printing holds the promise to manufacture with less waste and energy. We can print metals, ceramics, sand, synthetic materials such as plastics, food or living cells. However, the production of plastics is nowadays based on fossil fuels. And that’s where we witness a paradigm change too. The production of these synthetic materials can be based also on biomaterials with biomass as feedstock. A wealth of new and innovative products are emerging when we combine these two paradigm changes: 3D printing and biomaterials. Moreover, the combination of 3D printing with biomaterials holds the promise to realize a truly sustainable and circular economy.
Leading the way in current thinking on environmental logistics, Green Logistics provides a unique insight on the environmental impacts of logistics and the actions that companies and governments can take to deal with them. It is written by leading researchers in the field and provides a comprehensive view of the subject for students, managers and policy-makers. Fully updated, the 3rd edition of Green Logistics has a more global perspective than previous editions. It introduces new contributors and international case studies that illustrate the impact of green logistics in practice. There is a new chapter on the links between green logistics and corporate social responsibility and a series of postscripts examining the effects of new developments, such as 3D printing, distribution by drone, the physical internet and the concept of peak freight. Other key topics examined include: carbon auditing of supply chains; transferring freight to greener transport modes; reducing the environmental impact of warehousing; improving the energy efficiency of freight transport; making city logistics more environmentally sustainable; reverse logistics for the management of waste; role of government in promoting sustainable logistics. The 3rd edition of Green Logistics includes indispensable online supporting materials, including graphics, tables, chapter summaries, and guidelines for lecturers.
This open access book explores supply chains strategies to help companies face challenges such as societal emergency, digitalization, climate changes and scarcity of resources. The book identifies industrial scenarios for the next decade based on the analysis of trends at social, economic, environmental technological and political level, and examines how they may impact on supply chain processes and how to design next generation supply chains to answer these challenges. By mapping enabling technologies for supply chain innovation, the book proposes a roadmap for the full implementation of the supply chain strategies based on the integration of production and logistics processes. Case studies from process industry, discrete manufacturing, distribution and logistics, as well as ICT providers are provided, and policy recommendations are put forward to support companies in this transformative process.