基于改进遗传算法的挤扩支盘群桩优化方法

doi:10.13229/j.cnki.jdxbgxb.20210983

Abstract

Abstract:

The disk-shaped settlement distribution of pile group may cause secondary stress， which possibly leads to overall tilting and cracking of the building. Therefore， it is necessary to optimize the design of the squeezed branch pile group. Based on this， we took an improved genetic algorithm to refine the method. The calculated top axial force of pile group was grouped according to the sizes， the number of bearing discs in each group of piles were used as the design variables. Then， a model with the minimum-number discs subject to the constraints of the bearing capacity and the maximum settlement and settlement difference was built. With the help of Python language， ABAQUS was developed to establish an automatic optimization platform to solve the above optimization model and obtain the best pile group arrangement. Result shows that the optimized pile group foundation can reduce the number of bearing discs while decreasing the differential settlement， leading to the uniform deformation of the raft slab and pile top forces， which are beneficial to use the structure securely.

Key words: geotechnical engineering, squeezed branch pile, pile foundation optimization, genetic algorithm, variable stiffness leveling

CLC Number:

TU473.1

Ying-xin HUI,Jia-wei CHEN. Squeezed branch pile groups optimization method based on improved genetic algorithm[J].Journal of Jilin University(Engineering and Technology Edition), 2023, 53(7): 2089-2098.

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类别	厚度/m	γ/（kN·m^-3）	E/MPa	ν/kPa	c/kPa	φ/（°）
桩身	-	25.0	3.0×10⁴	0.15	-	-
承台	1.5	25.0	3.15×10⁴	0.15	-	-
土1	3.5	18.0	24.6	0.30	8.2	8.3
土2	5.0	18.5	27.1	0.30	15.4	18.0
土3	15.0	19.0	36.0	0.30	28.0	20.8
土4	20.0	19.3	40.0	0.30	30.0	22.5

承力盘数	G1	G2	G3	G4	G5	G6	G7	G8
设计承力盘数	4	4	4	4	4	4	4	4
优化承力盘数	6	4	2	0	0	0	0	0

方案	最大沉降值/mm	最小沉降值/mm	沉降差异值/mm	桩顶轴力最大值/kN	桩顶轴力最小值/kN	桩顶轴力差异值/kN
设计方案	70.1	57.6	12.5	2381.4	1056.6	1324.8
优化方案	72.1	64.5	7.6	1572.3	1154.2	418.1

Squeezed branch pile groups optimization method based on improved genetic algorithm

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