Abstract
SummaryAdditive manufacturing (AM) proposes a novel paradigm for engineering design and manufacturing, which has profound economic, environmental, and security implications. The design freedom offered by this category of manufacturing processes and its ability to locally print almost each designable object will have important repercussions across society. While AM applications are progressing from rapid prototyping to the production of end‐use products, the environmental dimensions and related impacts of these evolving manufacturing processes have yet to be extensively examined. Only limited quantitative data are available on how AM manufactured products compare to conventionally manufactured ones in terms of energy and material consumption, transportation costs, pollution and waste, health and safety issues, as well as other environmental impacts over their full lifetime. Reported research indicates that the specific energy of current AM systems is 1 to 2 orders of magnitude higher compared to that of conventional manufacturing processes. However, only part of the AM process taxonomy is yet documented in terms of its environmental performance, and most life cycle inventory (LCI) efforts mainly focus on energy consumption. From an environmental perspective, AM manufactured parts can be beneficial for very small batches, or in cases where AM‐based redesigns offer substantial functional advantages during the product use phase (e.g., lightweight part designs and part remanufacturing). Important pending research questions include the LCI of AM feedstock production, supply‐chain consequences, and health and safety issues relating to AM.
Highlights
Additive manufacturing (AM) is the process of producing objects from a three-dimensional (3D) model by joining materials layer by layer, directly from raw material in powder, liquid, sheet, or filament form without the need for molds, tools, or dies
The term AM encompasses a broad variety of manufacturing technologies, which are used in a wide range of industries: from consumer electronics to aerospace and numerous examples of medical applications, such as, for example, dental implants and hearing aids (Wohlers 2016; Materialise 2016). (See table 1 for definitions of all abbreviated terms used throughout this article.)
Faludi and colleagues (2015) performed a cradle-to-grave life cycle assessment (LCA) and compared the environmental impact of two AM systems (FDM Dimension 1200BST and Object Connex 350 inkjet) to a traditional computer numerical controlled (CNC) milling machine tool (Haas VF0) for the production of two specific acrylonitrile butadiene styrene (ABS) polymer parts
Summary
Additive manufacturing (AM) proposes a novel paradigm for engineering design and manufacturing, which has profound economic, environmental, and security implications. Limited quantitative data are available on how AM manufactured products compare to conventionally manufactured ones in terms of energy and material consumption, transportation costs, pollution and waste, health and safety issues, as well as other environmental impacts over their full lifetime. AM manufactured parts can be beneficial for very small batches, or in cases where AM-based redesigns offer substantial functional advantages during the product use phase (e.g., lightweight part designs and part remanufacturing). Important pending research questions include the LCI of AM feedstock production, supply-chain consequences, and health and safety issues relating to AM. Conflict of interest statement: Reid Lifset is the editor-in-chief of the Journal of Industrial Ecology. He was recused from his role as editor during the review process for this article
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