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| Force transmission law and load-bearing characteristics of implantable rock-socketed jacket foundation |
Zonghao YUAN1( ),Yunlong YAO1,Ben HE2,Yuwang LIANG1 |
1. College of Civil Engineering, Zhejiang University of Technology, Hangzhou 310023, China
2. PowerChina Huadong Engineering Co. Ltd, Hangzhou 311122, China |
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Abstract A finite element model validated by experimental and theoretical verification was established based on prototype data and geological survey information, with reference to an offshore wind power project in Guangxi, to systematically reveal the force transmission mechanism and bearing characteristics of the implantable rock-socketed jacket with double grouting layers on the inner and outer sides. The vertical force transmission contributions of shear keys and the evolution of shear force and bending moment in the pile under different loading conditions were investigated, clarifying the influence mechanism of formation characteristics on the bearing performance of the three-pile jacket. The results indicated that the shear keys bore over 90% of the vertical load transfer. Specifically, the end shear keys made a major contribution during the bearing phase, while the top shear keys played a significant role in the load transfer phase and under tensile conditions. When the formation strength reached a certain value, the bearing capacity of the jacket foundation became primarily governed by its own characteristics. Under rock-socketed conditions, the failure mode shifted from “sliding failure” to “stress failure”. Additionally, in high elastic modulus foundations, the pile shear force rapidly transitioned to negative values near the rock-socketed section, coinciding with the peak bending moment location. In low modulus foundations, shear force and bending moment reversal occurred at the end of the grouted connection segment. The greater the elastic modulus of the foundation, the shallower the burial depth required for the pile shear force and bending moment to approach zero. The research findings can provide a theoretical basis and reference for the design of implantable rock-socketed jacket foundations in similar projects.
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Received: 07 April 2025
Published: 19 March 2026
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| Fund: 浙江省科技计划项目“尖兵领雁+X”研发攻关计划(2024C03031);国家自然科学基金资助项目(52378376,52271294);浙江省属高校基本科研业务费项目-科技类(RF-B2023007);国家资助博士后研究人员计划(GZC20252134);浙江省自然科学基金资助项目(LQN26E080026). |
植入式嵌岩导管架基础传力规律与承载特性
为了系统揭示内外侧双灌浆层植入式嵌岩导管架的传力机制与承载特性,以广西海上风电项目为背景,基于项目原型数据与地勘资料,构建经试验与理论验证的有限元模型,研究不同荷载条件下剪力键竖向传力贡献度及桩身剪力弯矩演化规律,并阐明地层特性对三桩导管架承载性能的影响机制. 结果表明:剪力键承担了90%以上的竖向荷载传递,末端剪力键在承荷阶段贡献大,而顶端剪力键在传荷阶段和受拉时作用显著;当地层强度达到一定值后,导管架基础承载能力主要由导管架基础本身特性决定;嵌岩条件下破坏模式由“滑移破坏”转变为“应力破坏”. 此外,高弹性模量地基中桩身剪力在嵌岩段附近迅速转为负值,转变位置与弯矩峰值位置一致;低模量地基中剪力和弯矩反转发生于灌浆连接段末端;地基弹性模量越大,桩身剪力与弯矩趋零所需埋深越浅. 研究成果可为类似工程中植入式嵌岩导管架基础设计提供理论依据与参考.
关键词:
导管架基础,
破坏模式,
植入式嵌岩桩,
剪力键,
传力规律
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