Collaborative Research: Adaptive and Reconfigurable Tiles for Building Surfaces

合作研究:用于建筑表面的自适应和可重构瓷砖

基本信息

项目摘要

The environment continually changes at many different scales and with many different impact levels, and yet, the current U.S. building stock, in general, does not. Current practice for architects and engineers is to isolate the internal space of a building from the external environment with static barriers. Alternatively, substantially greater levels of energy efficiency can be realized by structures that interact with and respond to their environment. This project pursues fundamental research to utilize smart materials to design and optimize exterior building panels that operate as selective filters capable of adapting to environmental stimuli, such as solar insolation. Smart materials provide the unique ability to comprise structures that respond to external stimuli and transform into optimized geometric configurations. Such a morphing façade system will significantly alter the total sustainability of a building envelope and take advantage of available environmental energy sources. Beyond direct application to building technology, this work provides core concepts that can accelerate the implementation of novel adaptive structure concepts in fields such as aeronautics, astronautics, and the automotive industry. This research integrates multiple disciplines, including mechanics, materials engineering, architecture, and computer-aided engineering, as well as a geographically diverse team, and will facilitate mentorship and education of a diverse group of students. The smart material exterior building panels will be realized as modular building tiles comprised of shape memory polymer with controllable local activation and actuation. The technical approach involves three major thrusts: 1) Establishing a computational framework for the development of smart material tile morphing mechanisms; 2) Prototyping the tile concept to evaluate the feasibility of materials and morphing mechanisms and validating the computational methods; and 3) Numerical investigation of building case studies to evaluate the potential benefits of the smart material tile concept to overall building envelope efficiency. In addition to establishing a new concept in responsive building technologies, the computational efforts represent a substantial contribution to the field of computational methods for inverse problems, particularly the formulation of uniquely tractable and generalizable shape-based design objectives that could be used to facilitate accurate and efficient computational inverse solution procedures in a variety of shape-based applications. This work will further establish the concept of smart material morphing structures with controllable local actuation and activation.
环境在许多不同的规模和影响程度上不断变化,然而,目前的美国建筑存量总体上没有变化。建筑师和工程师目前的做法是用静态屏障将建筑物的内部空间与外部环境隔离。或者,可以通过与环境相互作用并对环境做出反应的结构来实现更高水平的能源效率。该项目致力于基础研究,利用智能材料设计和优化外部建筑面板,这些外部建筑面板作为选择性过滤器运行,能够适应环境刺激,如太阳辐射。智能材料提供了独特的能力来组成结构,这些结构对外部刺激做出反应,并转化为优化的几何配置。这种变形的幕墙系统将显著改变建筑围护结构的整体可持续性,并利用可用的环境能源。除了直接应用于建筑技术之外,这项工作还提供了核心概念,可以加速在航空、航天和汽车工业等领域实施新型自适应结构概念。这项研究整合了多个学科,包括力学、材料工程、建筑学和计算机辅助工程,以及一个地理上不同的团队,并将促进对不同学生群体的指导和教育。智能材料外墙板将实现为由形状记忆聚合物组成的模块化建筑瓷砖,具有可控的局部激活和致动。该技术方法涉及三个主要方面:1)建立用于开发智能材料瓷砖变形机制的计算框架;2)构建瓷砖概念的原型,以评估材料和变形机制的可行性并验证计算方法;以及3)建筑案例研究,以评估智能材料瓷砖概念对整体建筑围护结构效率的潜在好处。除了在响应性建筑技术中建立新的概念外,计算工作对反问题的计算方法领域做出了重大贡献,特别是基于形状的独特易处理和可推广的设计目标的制定,这些目标可以用于在各种基于形状的应用中促进准确和高效的计算反解程序。这项工作将进一步确立局部驱动和激活可控的智能材料变形结构的概念。

项目成果

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Dale Clifford其他文献

Dale Clifford的其他文献

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{{ truncateString('Dale Clifford', 18)}}的其他基金

Collaborative Research: Merging Human Creativity with Computational Intelligence for the Design of Next Generation Responsive Architecture
协作研究:将人类创造力与计算智能相结合,设计下一代响应式架构
  • 批准号:
    2329759
  • 财政年份:
    2024
  • 资助金额:
    $ 14.46万
  • 项目类别:
    Standard Grant

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