基于时变太阳辐射模型的大跨度悬索桥温度分析

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2020-01-01 DOI:10.12989/SSS.2020.25.1.023
Q. Xia, Li Senlin, Jian Zhang
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引用次数: 2

摘要

在评估桥梁结构状态时,考虑桥梁的热性能是很重要的。基于太阳辐射模型的数值模拟是研究大跨度桥梁温度效应的有效方法。本研究的目的是建立一个时变的太阳辐射模型,该模型可以考虑实时天气的变化,如云层的变化。首先对长期监测数据进行统计分析,特别是对大桥南锚和北锚之间的温度数据进行统计分析,确认温差可以用来描述实时天气变化。其次,在温度场模拟中发现了传统太阳辐射模型的缺陷,即浊度系数tu的值是主观的,不能实时描述天气的变化。因此,本文首先基于南北锚点温差建立了一个修正浊度系数γ的太阳辐射模型。第三,选取多日温度数据进行模型验证,结果表明,模拟温度分布与实测温度吻合较好,而传统模型计算结果由于浊度系数tu存在不确定性,误差较小。此外,还研究了典型截面的垂直和横向温度梯度以及塔内的温度分布。
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Temperature analysis of a long-span suspension bridge based on a time-varying solar radiation model
It is important to take into account the thermal behavior in assessing the structural condition of bridges. An effective method of studying the temperature effect of long-span bridges is numerical simulation based on the solar radiation models. This study aims to develop a time-varying solar radiation model which can consider the real-time weather changes, such as a cloud cover. A statistical analysis of the long-term monitoring data is first performed, especially on the temperature data between the south and north anchors of the bridge, to confirm that temperature difference can be used to describe real-time weather changes. Second, a defect in the traditional solar radiation model is detected in the temperature field simulation, whereby the value of the turbidity coefficient tu is subjective and cannot be used to describe the weather changes in real-time. Therefore, a new solar radiation model with modified turbidity coefficient γ is first established on the temperature difference between the south and north anchors. Third, the temperature data of several days are selected for model validation, with the results showing that the simulated temperature distribution is in good agreement with the measured temperature, while the calculated results by the traditional model had minor errors because the turbidity coefficient tu is uncertainty. In addition, the vertical and transverse temperature gradient of a typical cross-section and the temperature distribution of the tower are also studied.
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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