Collaborative Research: Environmental Sustainability of Additive Manufacturing Processes: Bridging Geometry and Life Cycle Inventory

合作研究：增材制造工艺的环境可持续性：桥接几何形状和生命周期清单

• 批准号: 1605472
• 负责人: Fu Zhao
• 金额: $ 16.02万
• 依托单位: Purdue University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2016
• 资助国家: 美国
• 起止时间: 2016-07-01 至 2020-06-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1605472&HistoricalAwards=false
• 关键词: Collaborative; Research; Environmental; Sustainability; Additive

1605472 / 1604825Zhao, Fu / The past decade has seen a rapid proliferation of academic achievements and industrial applications of additive manufacturing (AM) processes. Today the interest in AM continues to grow. Although reducing environmental impact is considered among the main advantages, very limited efforts have been made to rigorously evaluate the environmental performance of AM processes using the well-accepted life cycle assessment (LCA) methodology; also, even less studies are oriented toward process improvement. The overarching goal of this research is to advance understanding on how product design affects energy/material consumption and air emissions of representative AM processes. If successful, this research will bridge geometry and life cycle inventory (LCI), which provides much needed data foundation for LCA of AM processes and furthermore, enables the exploration of opportunities to re-design AM process and equipment for smaller environmental impacts. The research will be undertaken by a team consisting of experts in life cycle assessment, additive manufacturing, manufacturing process modeling, and pollution prevention at the Purdue University and the University of Illinois at Chicago (UIC). Four research tasks will be jointly pursued: (1) Material flow modeling and feedstock chemical composition analysis, (2) Energy consumption modeling, (3) Air emission characterization and quantification, and (4) AM process and equipment redesign for improved environmental performance. The research findings will be verified in both laboratory and industrial settings. The research is an effort to systematically evaluate the environmental impacts of the emerging AM processes using LCA methodology, with particular focus on unit process level LCI. The project will advance understanding of the material/energy flow and air emissions associated with four representative AM processes. The proposed LCI model is capable of predicting inventory flows of environmental significance while requiring only minimal experimental efforts. The research is an effort to bridge geometry and LCI of AM processes, which can guide the design and development of AM equipment and processes for enhanced environmental sustainability. Deeper understanding on energy consumption, feedstock material composition, and occupation hazard risk due to particulate matters and volatile organic compounds can provide guidelines for designers, manufacturers, and government agencies to safeguard workforce and reduce environmental footprints of AM processes. This will in turn accelerate the larger scale technology adoption of AM, and offer a competitive edge regarding sustainability to the U.S. manufacturing sector in the global market. Research results will be broadly disseminated through journal papers, conference presentations, online demonstrations, and industrial collaboration. The educational activities will strengthen the awareness of advanced life cycle analysis on additive manufacturing in engineering and environmental fields. Research results will be incorporated into both graduate and undergraduate courses at the University of Illinois at Chicago and Purdue University to positively impact engineering education.

1605472 /1604825 Zhao，Fu /在过去的十年中，增材制造（AM）工艺的学术成果和工业应用迅速增加。今天，对AM的兴趣继续增长。虽然减少对环境的影响被认为是其中的主要优点，非常有限的努力已经作出了严格的评估AM过程中使用公认的生命周期评估（LCA）方法的环境性能，而且，更少的研究是面向过程的改进。本研究的总体目标是提高对产品设计如何影响代表性AM工艺的能源/材料消耗和空气排放的理解。如果成功的话，这项研究将桥梁几何和生命周期清单（LCI），这提供了急需的数据基础AM工艺的生命周期评估，此外，使探索的机会，重新设计AM工艺和设备，以更小的环境影响。该研究将由普渡大学和伊利诺伊大学芝加哥分校（UIC）的生命周期评估、增材制造、制造过程建模和污染预防专家组成的团队进行。四项研究任务将共同进行：（1）物质流建模和原料化学成分分析，（2）能源消耗建模，（3）空气排放的表征和量化，以及（4）AM工艺和设备的重新设计，以改善环境性能。研究结果将在实验室和工业环境中得到验证。该研究是一项努力，系统地评估新兴的AM过程中使用LCA方法的环境影响，特别是侧重于单元过程水平的LCI。该项目将推进与四个代表性AM过程相关的材料/能量流和空气排放的理解。所提出的LCI模型是能够预测库存流量的环境意义，而只需要最小的实验努力。该研究是一个努力的桥梁几何形状和增材制造过程的LCI，这可以指导增材制造设备和工艺的设计和开发，以提高环境的可持续性。对能源消耗、原料成分以及颗粒物和挥发性有机化合物造成的职业危害风险的深入了解，可以为设计人员、制造商和政府机构提供指导，以保护劳动力并减少AM工艺的环境足迹。这将反过来加速AM的大规模技术采用，并为美国制造业在全球市场上的可持续性提供竞争优势。研究成果将通过期刊论文、会议演示、在线演示和行业合作广泛传播。教育活动将加强对工程和环境领域增材制造先进生命周期分析的认识。研究成果将被纳入芝加哥伊利诺伊大学和普渡大学的研究生和本科课程，以积极影响工程教育。