黄土地基微型群桩抗拔承载力及群桩效应研究
引用文献:
张爱军 付红安 王佳佳 王学平 田帅 孙清. 黄土地基微型群桩抗拔承载力及群桩效应研究[J]. 建筑结构,2022,48(24):120-125.
ZHANG Aijun FU Hongan WANG Jiajia WANG Xueping TIAN Shuai SUN Qing. Study on uplift bearing capacity and group pile effect of micro-pile group in loess foundation[J]. Building Structure,2022,48(24):120-125.
摘要:微型桩因其受力性能好及施工优势逐渐应用于输电线路杆塔基础,但群桩基础承载性能的研究相对较少。基于黄土地基微型群桩现场静载试验,研究了桩数和桩间距对微型群桩抗拔承载性能的影响;并建立了精细化有限元模型,进行了极限承载力分析。通过与试验结果对比,验证了有限元模型的合理性,在此基础上分析了桩间距、桩倾角对微型群桩抗拔承载性能的影响。结果表明:随着桩数、桩间距及桩倾角增加,微型群桩抗拔承载力均表现出不同程度的提高。结合试验和有限元分析可得黄土地基微型群桩的桩间距建议值4d,桩倾角建议值10°,群桩抗拔效应系数建议值0.80。
关键词:微型群桩;静载试验;数值模拟;抗拔承载性能;桩间距;桩倾角;群桩效应;
基金:国家自然科学基金(51978570)。
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[2] 刘兵民,孙慧峰.微型桩基础的实践与技术探讨[J].建筑结构,2017,47(15):102-105.
[3] SHELKE A,PATRA N R.Effect of arching on uplift capacity of single piles[J].Geotechnical and Geological Engineering,2009,27(3):365-377.
[4] 曹明星,高永涛,周喻.基于树根桩地基加固法的井塔纠偏方案[J].中南大学学报(自然科学版),2020,51(10):2906-2916.
[5] 崔小连,宋宇航,徐元卿,等.天津某物流基地库房地面沉陷加固处理方案[J].建筑结构,2020,50(S2):716-720.
[6] 李善,王凯,邵孟新,等.某在建高层建筑桩基加固技术方案与应用[J].建筑结构,2021,51(8):115-118,131.
[7] 李楠,门玉明,汪班桥,等.微型桩群桩支护均质土滑坡的振动台模型试验[J].工程地质学报,2019,27(6):1371-1378.
[8] 顾绍付,刘维正,石志国,等.在役高速公路深厚软基滑移病害微型桩处治分析[J].土木与环境工程学报(中英文),2019,41(6):43-51.
[9] 王祥.微型桩在高速铁路滑坡治理中的设计和应用[J].铁道工程学报,2021,38(2):19-22,29.
[10] 周勇发,蔡兴杰,龚健.软土地基中杆塔微型桩基础的设计方法研究[J].工业建筑,2005,35(S1):532-536.
[11] 吕凡任,陈仁朋,陈云敏,等.软土地基上微型桩抗压和抗拔特性试验研究[J].土木工程学报,2005,38(3):99-105.
[12] SHIN E C,DAS B M,PURI V K,et al.Ultimate uplift capacity of model rigid metal piles in clay[J].Geotechnical & Geological Engineering,1993,11(3):203-215.
[13] KHATRI V N,KUMAR J.Uplift capacity of axially loaded piles in clays[J].International Journal of Geomechanics,2011,11(1):23-28.
[14] 王成华,刘庆晨.考虑基坑开挖影响的群桩基础竖向承载性状数值分析[J].岩土力学,2012,33(6):1851-1856.
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[16] DEENDAYAL R,MUTHUKKUMARAN K,SITHARAM T G.Analysis of laterally loaded group of piles located on sloping ground[J].International Journal of Geotechnical Engineering,2020,14(5):580-588.
[17] 屈伟,朱锐,居俊,等.黄土地区微型桩基础承载特性现场试验研究[J].建筑科学,2020,36(1):98-105.
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Study on uplift bearing capacity and group pile effect of micro-pile group in loess foundation
Abstract: The micro-pile has gradually been applied to the foundation of transmission line tower due to its good mechanical performance and construction advantages, but the bearing performance of pile group is relatively little researched. Based on the field static load test of the micro-pile group in loess foundation, the influence of the number of piles and the distance between the piles on the uplift bearing performance of the micro-pile group were studied. And a refined finite element model was established to carry out analysis of the ultimate bearing capacity. By comparing with the test results, the reasonableness of the finite element model was verified, and on this basis, the influence of pile spacing and pile inclination angle on the uplift bearing performance of micro-pile group was analyzed. The results show that with the increase of the number of piles, pile spacing and pile inclination angle, the uplift bearing capacity of micro-pile groups shows different degrees of improvement. According to the results of experiment and numerical simulation, the recommended values of pile spacing, pile inclination angle and anti-pull effect coefficient of micro-pile group in loess foundation are 4d, 10° and 0.80 respectively.
Keywords: micro-pile group; static test; numerical simulation; uplift bearing capacity; pile spacing; pile inclination; pile group effect
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