Optimal Design of Fibrous Concrete Beams Through Simulated Annealing

D. Suji, S. Natesan, R. Murugesan, R. Prabhu
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引用次数: 10

Abstract

In this paper formulation and solution technique using Simulated Annealing for optimizing the moment capacity of steel fiber reinforced concrete beams, with random orientated steel fibers, is presented along with identification of design variables, objective function and constraints. Steel fibers form an expensive constituent of steel fiber concrete and therefore it is important to determine ways and means of using these fibers in a judicial way with care consistent with economy for achieving the desired benefits. The most important factors which influence the ultimate load carrying capacity of FRC are the volume percentage of the fibers, their aspect ratios and bond characteristics. Hence an attempt has been made to analyze the effective contribution of fibers to bending of reinforced fiber concrete beams. Equations are derived to predict the ultimate strength in flexure of SFRC beam with uniformly dispersed and randomly oriented steel fibers. Predicted strengths using the derived expressions have been compared with the experimental data. A reasonable agreement (within the range of ±20 percent!) was evident with different types of steel fibers, aspect ratio, and material characteristics. A computer coding has been developed based on the formulations and the influence of various parameters on the ultimate flexural strength is discussed. A computer algorithm that conducts a random search in the space of four variables-beam width, beam depth, fiber content and aspect ratio-to yield an optimum solution for a given objective function (ultimate moment (Mu)) is presented. The outlined methods provide a simple and effective tool to assess the optimum flexural strength of steel fiber reinforced concrete beams. Using the results obtained the influence of various parameters on the ultimate strength are discussed. Particular attentions are given to the construction practice as well as the reduction of searching space. It has been shown that within a reasonable and finite number of searching the developed algorithm is able to yield optimum solutions for the given objective function.
纤维混凝土梁的模拟退火优化设计
本文提出了随机取向钢纤维钢筋混凝土梁弯矩承载力优化的模拟退火公式和求解技术,并确定了设计变量、目标函数和约束条件。钢纤维是钢纤维混凝土的一种昂贵成分,因此确定合理、谨慎、经济地使用这些纤维的方法和手段,以达到预期的效益是很重要的。影响frp极限承载能力的最重要因素是纤维的体积百分比、长径比和粘结特性。因此,本文尝试分析纤维对钢筋纤维混凝土梁弯曲的有效贡献。推导了钢纤维均匀分散和随机取向的钢纤维混凝土梁的极限抗弯强度方程。用推导式预测的强度与实验数据进行了比较。不同类型的钢纤维、长径比和材料特性之间的一致性很明显(在±20%的范围内!)。在此基础上编制了计算机编码,并讨论了各参数对极限抗弯强度的影响。提出了一种计算机算法,该算法对给定的目标函数(极限弯矩(Mu))在四个变量(光束宽度、光束深度、纤维含量和纵横比)的空间中进行随机搜索,以产生最优解。概述的方法为钢纤维混凝土梁的最佳抗弯强度评定提供了一种简单有效的工具。利用所得结果,讨论了各参数对极限强度的影响。特别注意构造实践和减少搜索空间。结果表明,在合理和有限的搜索次数内,所开发的算法能够得到给定目标函数的最优解。
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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