单片增材制造绝缘壁件的多目标参数化设计优化

IF 2.2 Q2 CONSTRUCTION & BUILDING TECHNOLOGY
David Briels, Mauritz Renz, Ahmad Saleem Nouman, Alexander Straßer, Maximilian Hechtl, Maximilian Dahlenburg, Bruno Knychalla, Patrick Sonnleitner, Friedrich Herding, Julia Fleckenstein, Ema Krakovská, Kathrin Dörfler, Thomas Auer
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引用次数: 0

摘要

增材制造(AM)为创建功能杂交、绝缘、单片增材制造壁件提供了变革性的机会。增材制造的新制造方法允许生产具有复杂内部和外部几何形状的高度差异化的建筑部件,旨在减少材料使用,同时集成和增强包括隔热性能在内的建筑性能。本研究的重点是通过利用三种不同AM工艺的个体特征来整合这种隔热性能:选择性浆料侵入(SPI),选择性水泥活化(SCA)和挤出3D混凝土打印(E3DCP)。采用基于仿真的参数化设计方法,本研究调查了4500种单片AM farade元件的变化,这些元件来自具有不同壁宽的生成六角形单元布局、三种各自的AM工艺、不同的材料成分(含或不含轻质骨料)以及三种不同的隔热策略,即充气单元、封装轻质骨料和在腔内添加隔热材料。热性能反馈通过嵌入到参数化设计工作流中的二维热流模拟实现,结构性能通过几何和材料特定评估以简化的方式考虑。总体研究目标是一个多目标的设计优化,特别是确定达到u值小于0.28 W/ m2 K和理论抗压强度超过2.70 MN /m壁长的farade配置。本研究的结果检测出所有产生的变化中有7%符合这些热和结构要求,验证了单片隔热AM壁元件的可行性。提出的工作流程有助于开发功能杂交增材制造组件的新设计潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Monolithic AM façade: multi-objective parametric design optimization of additively manufactured insulating wall elements
Additive Manufacturing (AM) offers transformative opportunities to create functionally hybridized, insulating, monolithic AM wall elements. The novel fabrication methods of AM allow for the production of highly differentiated building components with intricate internal and external geometries, aiming for reduced material use while integrating and enhancing building performance features including thermal insulation performance. This study focuses on integrating such thermal insulation performance by leveraging the individual features of three distinct AM processes: Selective Paste Intrusion (SPI), Selective Cement Activation (SCA), and Extrusion 3D Concrete Printing (E3DCP). Using a simulation-based parametric design approach, this research investigates 4,500 variations of monolithic AM façade elements derived from a generative hexagonal cell layout with differing wall widths, the three respective AM processes, different material compositions with and without lightweight aggregates, and three different insulation strategies, namely, air-filled cells, encapsulated lightweight aggregates, and additional insulation material within the cavities. Thermal performance feedback is realized via 2D heat flux simulations embedded into a parametric design workflow, and structural performance is considered in a simplified way via geometric and material-specific evaluation. The overall research goal is a multi-objective design optimization, particularly identifying façade configurations that achieve a U-value of less than 0.28 W/m 2 K and a theoretical compressive strength exceeding 2.70 MN per meter wall length. The results of this study detect 7% of all generated variations in line with these thermal and structural requirements, validating the feasibility of monolithic, thermally insulating AM wall elements. The presented workflow contributes to exploiting the potential of a new design of functionally hybridized AM components.
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来源期刊
Frontiers in Built Environment
Frontiers in Built Environment Social Sciences-Urban Studies
CiteScore
4.80
自引率
6.70%
发文量
266
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