高层结构“塔-钢筋混凝土基础-地基土组合”体系的应力-应变状态

L. Mailyan, S. Yazyev, L. Sabitov, Yu.V. Konoplev, O. Radaykin
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引用次数: 2

摘要

本研究以某1.5-2.0 MW风力发电厂(风力机)为例,利用Ansys软件进行计算机建模,评估“塔-钢筋混凝土基础-基础土组合”体系在高层结构中的有效性。由此可见,本文所指的组合式塔是指高层建筑,由两部分组成:下部为组合式,上部为薄壁芯壳封闭型材形式。在这两种情况下,壳体都是一个具有弱锥度的管道。作为类比,采用国外文献中考虑的WPP:转子半径R=41 m,风轮距轴线高度zhub=80 m。外壳由高强度C355钢制成,与本作品中的模拟物不同,塔下部20米高的空腔由B60级混凝土填充。建模考虑了结构系统元素的空间工作和制造它们的材料的物理非线性。同时,米塞斯强度理论用于钢材,威廉姆斯-瓦纳克理论用于混凝土,德鲁克-普拉格理论用于地基土。计算结果与模拟结果的比较表明,在塔的下部填充混凝土后,塔的破坏荷载提高了37%,表明了所提出的解决方案的有效性。在这种情况下,有混凝土核心和没有混凝土核心的塔的破坏是由于塔与基础连接处(带有压缩区)钢壳的局部稳定性丧失而发生的。
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STRESS-STRAIN STATE OF THE SYSTEM "COMBINED TOWER-REINFORCED CONCRETE FOUNDATION-FOUNDATION SOIL" OF HIGH-RISE STRUCTURES
The aim of the work was to evaluate the effectiveness of the system "combined tower-reinforced concrete foundation-foundation soil" for high-rise structures on the example of a wind power plant (wind turbine) with a capacity of 1.5-2.0 MW using computer modeling in the PC "Ansys". Thus, under the combined tower the article refers to high-rise building, consisting of two parts: the lower composite, the upper – in the form of a thin-walled core-shell closed profile. In both cases, the shell is a pipe with a weak taper. As an analogue, the WPP considered in foreign literature is adopted: the radius of the rotor is R=41 m, the height to the axis of the wind wheel is zhub=80 m. The shell is made of high-strength C355 steel and, unlike the analog in this work, the cavity of the lower part of the tower to a height of 20 m was filled with B60 class concrete. The modeling took into account the spatial work of the elements of the structural system and the physical nonlinearity of the materials from which they are made. At the same time, the Mises strength theory was used for steel, the Williams – Varnake theory for concrete, and the Drukker – Prager theory for the foundation soil. Comparison of the calculation results with the analog showed that the destructive load of the tower increased by 37% due to filling the lower part of it with concrete, which indicates the effectiveness of the proposed solution. In this case, the destruction of the tower with a concrete core and without it occurred from the loss of local stability of the steel shell at the level of the junction of the tower with the foundation (with a compressed zone).
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