Multibody Analysis of a Tensegral Servo-Actuated Structure for Civil Applications

Volume 7: 17th IEEE/ASME International Conference on Mechatronic and Embedded Systems and Applications (MESA) Pub Date : 2021-08-17 DOI:10.1115/detc2021-70662

C. Scoccia, G. Palmieri, M. Callegari, M. Rossi, L. Carbonari, P. Munafò, F. Marchione, G. Chiappini

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引用次数: 1

Abstract

The use of glass elements in civil engineering is spreading in the last years beyond merely aesthetic functions for their ease of installation and production. Nonetheless, the structural performance of such materials in any condition of use is object of investigation. In this scenario, the paper analyses the performance of an innovative concept of tensegrity floor (Patent no 0001426973) characterized by a particular steel-glass adhesive junction that permits a profitable structural cooperation between such basically different materials. As known, at the base of the effectiveness of tensegral structures lies the correct tensioning of metal strands which are devoted at keeping the rigid elements compressed. The tensioning level is then responsible of the actual deformation of the structure, which is of course of uttermost importance while speaking of civil applications. To address this issue with the adequate level of confidence required by construction practice, a mechatronic servo-system is proposed, aimed at maintaining, and modifying when needed, the stress state of the metal cables to adjust the deformation of the upper plane in response to varying loads. Three different actuation schemes, with different levels of realization complexity, are analysed and compared in simulated environment by means of a hybrid multibody-finished elements mode.

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民用张拉体伺服驱动结构的多体分析

近年来，由于易于安装和生产，玻璃元素在土木工程中的应用已经超越了单纯的审美功能。尽管如此，这些材料在任何使用条件下的结构性能都是调查的对象。在这种情况下，本文分析了一种创新概念的张拉整体地板(专利号0001426973)的性能，其特征是一种特殊的钢-玻璃胶粘结，允许在这种基本不同的材料之间进行有益的结构合作。众所周知，张拉整体结构有效性的基础在于金属链的正确张拉，金属链致力于保持刚性元件的压缩。张拉水平负责结构的实际变形，这当然是最重要的，而谈到民用应用。为了在施工实践中以足够的信心解决这一问题，提出了一种机电伺服系统，旨在维持和在需要时修改金属电缆的应力状态，以调整响应不同载荷的上部平面的变形。在仿真环境下，采用混合多体成品单元模型，对三种不同实现复杂度的驱动方案进行了分析和比较。

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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Volume 7: 17th IEEE/ASME International Conference on Mechatronic and Embedded Systems and Applications (MESA)

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