Researchers from the University of Birmingham, UK, have proposed a new approach to design for additive manufacturing, suggesting there is much to learn from the prenatal development of a human baby.
The work by Birmingham’sSchool of Engineeringand theCentre for Human Reproductive Scienceand published inThe International Journal of Advanced Manufacturing Technologyhighlights how developing biological systems, tissues and organs, are built up incrementally via the division and replication of cells.
The influence of prenatal development on additive manufacturing
The study notes both growth rate and region of growth change during pregnancy. Conversely, in additive manufacturing, the development or “growth” of a 3D printed part is solely reliant on the spatial domain, determined only by where the filament is deposited. In this regard, the temporal dimension (aka time) is an inoperative process variable when it comes to design for additive manufacturing. The study explores how an implementation of the temporal domain could lead to the development of previously unseen material properties and structures.
Previously, researchers have attempted to alter the properties of 3D printed materials but it has been through thespatial variation of the composition of the deposited material, leaving out the temporal domain. This also limits the studied materials to multi-material composites. The methodology of the present study can be applied to single-material filaments.
What do the researchers say?
主要研究员,机械工程系的劳伦·托马斯·塞尔(Lauren Thomas-Seale)博士指出:“尽管我们将其称为增材制造业,但传统上工程师学会根据悠久的减法制造历史来设计零件。雷电竞充值这导致了设计创造力的限制。雷电竞充值如果要在设计和基本技术中发挥全部潜力,则必须摆脱这种惯性。”
Co-author of the study, Dr. Jackson Kirkman-Brown of the Institute of Metabolism and Systems Research adds: “Whilst using biological inspiration in engineering design is commonplace, studying the growth of humans and translating this to advanced manufacturing systems offers a whole new perspective. The way in which biological systems develop from incrementally adding cells to form tissues and organs, which both grow and modulate each other to function in synergy, is the epitome of sophisticated additive manufacturing.”
The study, funded by the Royal Society, is named ‘Temporal design for additive manufacturing’. It is co-authored by Saliba, S., Kirkman-Brown, J.C. & Thomas-Seale, L.E.J..
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Featured image shows a render of the new School of Engineering, currently under construction at the University of Birmingham. Image via the University of Birmingham.
