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用于可持续城市淡水生态系统的仿生自适应建筑立面建模:将自然集水策略融入遮阳板

Biomimetic Adaptive Building Façade Modeling for Sustainable Urban Freshwater Ecosystems: Integration of Nature's Water-Harvesting Strategy into Sun-Breakers.

作者信息

Kahvecioğlu Berkan, Mutlu Avinç Güneş, Arslan Selçuk Semra

机构信息

Department of Architecture, Faculty of Architecture, Gazi University, 06560 Ankara, Turkey.

Department of Construction and Technical, Erciyes University, 38280 Kayseri, Turkey.

出版信息

Biomimetics (Basel). 2024 Sep 19;9(9):569. doi: 10.3390/biomimetics9090569.

DOI:10.3390/biomimetics9090569
PMID:39329591
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11429842/
Abstract

Urban freshwater ecosystems have many critical functions, such as providing water to all living things and supporting biodiversity. Factors such as water pollution, increased water consumption, habitat loss, climate change, and drought threaten the health of urban freshwater ecosystems. Looking for solutions to these challenges, this article aims to recycle water and return it to its life cycle using a climate-sensitive water collection strategy. The model focuses on the biomimetic method as a basic strategy. In this regard, the concept of water-harvesting has been examined in detail by conducting a deep literature review, including architecture and engineering disciplines. With all these data obtained, a synthesis/integration study was carried out by developing a model proposal based on adaptive building façade elements to solve the water problems experienced in cities. The model proposal, which is directly related to the titles of "Clean Water and Sanitation (SDG 6)" and "Sustainable Cities and Communities (SDG 11)", which are among the Sustainable Development Goals (SDGs), aims to provide different perspectives on the disciplines with its superficial and functional features. In this context, it is anticipated that the article will become an indispensable resource for other researchers working on the subject.

摘要

城市淡水生态系统具有许多关键功能,例如为所有生物提供水源并支持生物多样性。水污染、用水量增加、栖息地丧失、气候变化和干旱等因素威胁着城市淡水生态系统的健康。为寻求应对这些挑战的解决方案,本文旨在采用一种对气候敏感的集水策略来回收水并使其回归生命周期。该模型将仿生方法作为基本策略。在这方面,通过深入的文献综述,包括建筑学和工程学学科,对集水概念进行了详细研究。利用所获得的所有这些数据,通过基于自适应建筑立面元素开发模型提案来开展综合/整合研究,以解决城市中遇到的水问题。该模型提案与可持续发展目标(SDGs)中的“清洁饮水和卫生设施(可持续发展目标6)”和“可持续城市和社区(可持续发展目标11)”直接相关,旨在通过其表面和功能特征为各学科提供不同视角。在此背景下,预计本文将成为从事该主题研究的其他研究人员不可或缺的资源。

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本文引用的文献

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Biomimicry: the nexus for achieving sustainability in the people-process-planet relationship.仿生学:实现人、过程、地球关系可持续发展的纽带。
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作为一种可持续设计方法的仿生学——介绍“可持续发展的仿生学”框架。
Biomimetics (Basel). 2022 Mar 30;7(2):37. doi: 10.3390/biomimetics7020037.
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Biomimicry for Energy-Efficient Building Design: A Bibliometric Analysis.用于节能建筑设计的仿生学:文献计量分析
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