考虑桩-筒变形协调的钢护筒-碎石复合桩水平承载力计算理论

doi:10.3785/j.issn.1008-973X.2026.02.023

浙江大学学报(工学版)

2026, Vol. 60

Issue (2): 445-454 DOI: 10.3785/j.issn.1008-973X.2026.02.023

交通工程、土木工程

考虑桩-筒变形协调的钢护筒-碎石复合桩水平承载力计算理论

徐瑞麟1,2(

),易恩泽1,2,吴君涛1,2,*(

),王奎华1,2,张智卿3,汤旅军4

1. 浙江大学建筑工程学院，浙江杭州 310058
2. 浙江大学平衡建筑研究中心，浙江杭州 310063
3. 温州理工学院建筑与能源工程学院，浙江温州 325035
4. 浙江水利水电学院建筑工程学院，浙江杭州 310018

Analytical method for evaluating lateral bearing capacity of gravel-filled canister-monopile considering pile-canister deformation coordination

Ruilin XU1,2(

),Enze YI1,2,Juntao WU1,2,*(

),Kuihua WANG1,2,Zhiqing ZHANG3,Lüjun TANG4

1. College of Civil Engineering and Architecture, Zhejiang University, Hangzhou 310058, China
2. Center for Balance Architecture, Zhejiang University, Hangzhou 310063, China
3. College of Architecture and Energy Engineering, Wenzhou University of Technology, Wenzhou 325035, China
4. College of Civil Engineering and Architecture, Zhejiang University of Water Resources and Electric Power, Hangzhou 310018, China

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摘要：

为了解决深远海海上风机基础成本较高的问题，提出由大直径单桩、钢护筒与桩筒间填充碎石3个部分组成的新型钢护筒-碎石复合桩. 在服役期间，碎石能够填充桩-土因长期循环作用产生的间隙，有效抑制桩周土体弱化，提升单桩的水平承载力. 针对水平受荷状态下的钢护筒-碎石复合桩进行承载力分析，考虑桩筒间填充碎石对桩身侧向支承刚度的提升作用以及护筒受荷后的水平位移发展，提出考虑桩-筒变形协调的应变楔耦合计算模型. 通过将筒径缩小至桩径，筒高缩减至零，填充碎石设置为桩周土体，使所提计算模型退化至单桩水平承载力计算模型，并与已有解析理论进行对比验证. 将所提模型计算结果与有限元计算结果对比，进一步验证模型的合理性及可靠性. 基于验证后的计算模型对钢护筒-碎石复合桩的主要设计参数进行分析，结果表明，钢护筒直径、高度与筒内碎石弹性模量均与钢护筒-碎石复合桩水平承载力呈正相关关系，护筒埋深存在最优设计值.

关键词： 复合桩; 海上风电; 修正应变楔方法; 水平承载力; 参数分析; 砂土

Abstract:

To address the high cost of foundations for offshore wind turbines in deep and far-sea environments, a novel gravel-filled canister-monopile (GCM) was proposed, which consists of three components: a large-diameter monopile, a steel canister, and gravel filled between the pile and the canister. During service, the gravel was able to fill gaps generated in the pile–soil interface due to long-term cyclic loading, effectively mitigating the weakening of the surrounding soil and thereby enhancing the lateral bearing capacity of the monopile. To analyze the lateral bearing behavior of the gravel-filled canister-monopile, a strain wedge coupled model considering pile–canister deformation coordination was developed, taking into account the increase in lateral support stiffness provided by the filled gravel and the horizontal displacement development of the canister under load. By reducing the canister diameter to that of the pile, setting the canister height to zero, and treating the filled gravel as surrounding soil, the proposed model degenerated into a conventional monopile lateral bearing model, which was validated through comparison with existing analytical theories. Further comparisons with finite element analysis results confirmed the reasonableness and reliability of the proposed model. Based on the validated model, a parametric analysis of the main design parameters of the gravel-filled canister-monopile was conducted. The results indicated that the steel canister diameter, height, and the elastic modulus of the gravel were all positively correlated with the lateral bearing capacity, while the canister embedment depth exhibited an optimal design value.

Key words: composite pile offshore wind turbine modified strain wedge method lateral bearing capacity parameter analysis sand

收稿日期: 2025-02-07 出版日期: 2026-02-03

CLC:

TU 437

基金资助: 中国工程院战略研究与咨询项目（2025-XZ-75）；国家自然科学基金资助项目（52178358, 52108349, 52178367）；浙江省自然科学基金重点资助项目（LTGG24E080001）.

通讯作者: 吴君涛 E-mail: ruilinxu@zju.edu.cn;wujuntao31@126.com

作者简介: 徐瑞麟（2001—），男，硕士生，从事桩基承载力研究. orcid.org/0009-0008-2088-3783. E-mail：ruilinxu@zju.edu.cn

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引用本文:

徐瑞麟,易恩泽,吴君涛,王奎华,张智卿,汤旅军. 考虑桩-筒变形协调的钢护筒-碎石复合桩水平承载力计算理论[J]. 浙江大学学报(工学版), 2026, 60(2): 445-454.

Ruilin XU,Enze YI,Juntao WU,Kuihua WANG,Zhiqing ZHANG,Lüjun TANG. Analytical method for evaluating lateral bearing capacity of gravel-filled canister-monopile considering pile-canister deformation coordination. Journal of ZheJiang University (Engineering Science), 2026, 60(2): 445-454.

链接本文:

https://www.zjujournals.com/eng/CN/10.3785/j.issn.1008-973X.2026.02.023 或 https://www.zjujournals.com/eng/CN/Y2026/V60/I2/445

图 1 钢护筒-碎石复合桩示意图

图 2 应变楔模型示意图

图 3 应变楔模型分层计算示意图[12]

图 4 筒体运动及修正应变楔竖向剖面示意图

图 5 钢护筒-碎石复合桩水平承载力计算模型示意图

图 6 钢护筒-碎石复合桩水平承载力理论计算流程图

图 7 不同应变楔计算模型的计算结果对比

图 8 钢护筒-碎石复合桩的建模示意图

表 1 有限元模型各部件参数

图 9 不同工况下桩身位移沿深度的分布

表 2 桩体性能试验用参数

图 10 钢护筒-碎石复合桩与单桩位移-荷载曲线对比

表 3 钢护筒-碎石复合桩主要设计参数的取值

图 11 不同筒径下的钢护筒-碎石复合桩性能参数对比

图 12 不同筒高下的钢护筒-碎石复合桩性能参数对比

图 13 不同护筒埋深下的钢护筒-碎石复合桩性能参数对比

图 14 不同碎石弹性模量下的钢护筒-碎石复合桩性能参数对比

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