生物设计原理作为建筑中生物设计和生物制造的模型

David Andréen, Ana Goidea
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引用次数: 1

摘要

生物材料代表了建筑行业减少其负面生态影响的潜在手段。这些材料需要与传统建筑材料截然不同的方法来最大限度地发挥其潜力。在本文中,我们概述了生物设计的四个原则,我们认为这是通过生物设计成功实施新建筑范式的核心。这些原则是:(形式)的多样性、复杂性和特殊性、弹性的持久性、反馈和适应性。当规模扩大到建筑行业时,材料的多样性是保持生物材料可持续性所必需的。当使用低冲击材料时,形式的复杂性和特殊性使建筑环境具有高性能。弹性带来的耐用性使设计师能够使用原本被认为过于脆弱的材料。最后,反馈和适应是生物设计的核心原则,使植物和动物能够不断进化,以应对不断变化的条件,跨越多个时间尺度,并在复杂系统中管理设计。总而言之,我们认为这些原则中有许多是在本土建筑传统中发现的,但新兴的设计和制造技术可以使更广泛的实施成为可能,将现代建筑和本土建筑的优点结合起来。
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Principles of biological design as a model for biodesign and biofabrication in architecture

Biomaterials represent a potential means for the construction industry to reduce its negative ecological impact. These materials require substantially different approaches from conventional construction materials to maximise their potential. In this paper we have outlined four principles of biological design that we argue are central for the successful implementation of a new construction paradigm through biodesign. These principles are: Diversity, complexity and specificity (of form), durability through resilience, and feedback and adaptation. Diversity of material is necessary to maintain the sustainability of biomaterials when scaled up to construction industry volumes. Complexity and specificity of form enable high performativity of the built environments when using low-impact materials. Durability through resilience allows designers to work with materials that would otherwise be considered too weak. Finally, feedback and adaptation are core principles of biological design that allow plants and animals to constantly evolve in response to changing conditions, across multiple time scales, and to manage design in complex systems. In conclusion we have argued that many of these principles are found in vernacular architectural traditions, but that emerging design and fabrication technologies can enable broader implementation that can combine the benefits of modern and vernacular buildings practice.

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