Design rules for timber log reciprocal floors, based on mass optimization under stiffness constraint

Q1 Arts and Humanities

International Journal of Space Structures Pub Date : 2021-09-01 DOI:10.1177/09560599211041699

P. Latteur, J. Geno, M. VanDamme

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引用次数: 1

Abstract

Building with raw timber allows to reduce the price of construction and to make it more competitive with respect to concrete or steel construction. For a few years now, the combination of parametric design and robotic tools make possible the fast and precise milling of timber logs for their accurate connection. However, the spans are quickly limited by the logs length. In this context, reciprocal structures are relevant, since they allow to build large spans structures with short beams. Finally, the architectural interest of reciprocal structures is not to prove. However, the choice of the most efficient reciprocal frame, as well as its structural relevance in terms of mass and stiffness is, most of the time, ruled by subjective considerations. This paper focuses on rectangular floors composed of reciprocal moduli and has three objectives: (1) to develop a general mass and stiffness optimization method for reciprocal floors, which is not only necessary to limit the price, but also to reduce their thickness, (2) to define design rules for reciprocal floors, in particular for the choice of the best engagement ratio, and (3) to compare the structural efficiency of reciprocal floors with the one of “traditional” floors with parallel logs. Coming from a dimensionless transformation of the equilibrium equations, the results of this article will thus give the designers keys to better design reciprocal structures, evaluate their structural performances and relevance, and justify their choices.

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基于刚度约束下质量优化的原木交互楼板设计规则

用生木建造可以降低建筑价格，并使其相对于混凝土或钢结构更具竞争力。几年来，参数化设计和机器人工具的结合使原木的快速精确铣削成为可能，以实现其精确连接。但是，跨度很快就会受到原木长度的限制。在这种情况下，相互作用结构是相关的，因为它们允许用短梁建造大跨度结构。最后，互惠结构的建筑兴趣是无法证明的。然而，在大多数情况下，选择最有效的倒数框架及其在质量和刚度方面的结构相关性是由主观因素决定的。本文主要研究由互易模量组成的矩形楼板，目标有三：（1）开发一种通用的互易楼板质量和刚度优化方法，这不仅有助于限制价格，而且有助于减少厚度；（2）定义互易楼板的设计规则，特别是最佳接合比的选择，以及（3）将倒排地板的结构效率与具有平行原木的“传统”地板的结构性能进行比较。本文的结果来自平衡方程的无量纲变换，因此将为设计者提供更好地设计互惠结构的关键，评估其结构性能和相关性，并证明其选择的合理性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Space Structures Arts and Humanities-Conservation

CiteScore

2.00

自引率

0.00%

发文量

期刊介绍： The aim of the journal is to provide an international forum for the interchange of information on all aspects of analysis, design and construction of space structures. The scope of the journal encompasses structures such as single-, double- and multi-layer grids, barrel vaults, domes, towers, folded plates, radar dishes, tensegrity structures, stressed skin assemblies, foldable structures, pneumatic systems and cable arrangements. No limitation on the type of material is imposed and the scope includes structures constructed in steel, aluminium, timber, concrete, plastics, paperboard and fabric.