Integrated Platform for the Analysis and Design of Tall Buildings for Wind Loads

Mathematical Modelling in Civil Engineering Pub Date : 2019-12-01 DOI:10.2478/mmce-2019-0009

Mihail Iancovici

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引用次数: 2

Abstract

Abstract The Romanian, as well as other wind design codes for building structures, provides with limited degree of accuracy, the aerodynamic loads distribution on buildings up to 200 meters tall in an equivalent static approach (ESWL). For tall wind-sensitive building structures, especially for those with irregular shapes, most of the codes or standards recommend for design to use pressure data recorded in the wind tunnel. The ESWL approach is however used as reference estimation and structural first phase design. Advances on experimental and computational capabilities, led in the past decade to a significant development of time-domain analysis framework, both for seismic and wind loads. While the major outcome for earthquake engineering practitioners is to select appropriate design input ground motions at a particular site, the wind engineering practitioners are facing numerical difficulties to handle large wind loading durations, especially dealing with nonlinear-induced effects. The paper presents a real-time integrated framework for the analysis and design of tall buildings to wind loads, based on the time-domain analysis tool, as a prerequisite for higher level modules as vulnerability, risk and loss estimation, and optimization analyses.

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高层建筑风荷载分析与设计集成平台

罗马尼亚以及其他建筑结构的风设计规范，在一定程度上提供了等效静态方法(ESWL)中高达200米建筑的气动载荷分布的精度。对于对风敏感的高层建筑结构，特别是那些形状不规则的建筑结构，大多数规范或标准建议使用风洞中记录的压力数据进行设计。然而，ESWL方法被用作参考估计和结构第一阶段设计。在过去十年中，实验和计算能力的进步导致了地震和风荷载时域分析框架的重大发展。虽然地震工程从业者的主要成果是在特定地点选择适当的设计输入地震动，但风工程从业者面临着处理大风荷载持续时间的数值困难，特别是处理非线性诱导效应。本文提出了一种基于时域分析工具的高层建筑风荷载分析与设计实时集成框架，并以此为前提，实现更高层次的易损性、风险与损失估计、优化分析等模块。

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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Mathematical Modelling in Civil Engineering

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