承台板下桩串行多点拾振检测技术及其理论研究

doi:10.3785/j.issn.1008-973X.2026.04.016

浙江大学学报(工学版)

2026, Vol. 60

Issue (4): 844-854 DOI: 10.3785/j.issn.1008-973X.2026.04.016

土木工程、交通工程

承台板下桩串行多点拾振检测技术及其理论研究

贾俊杰1,2(

),吴君涛1,2,*(

),付鹏程1,2,王奎华1,2,朱旭峰3,汤旅军4

1. 浙江大学建筑工程学院，浙江杭州 310058
2. 浙江省城市地下空间开发工程技术研究中心，浙江杭州 310058
3. 杭州西南检测技术股份有限公司，浙江杭州 310015
4. 浙江水利水电学院建筑工程学院，浙江杭州 310018

Serial multi-point vibration acquisition testing method for piles under bearing slabs and its theoretical study

Junjie JIA1,2(

),Juntao WU1,2,*(

),Pengcheng FU1,2,Kuihua WANG1,2,Xufeng ZHU3,Lvjun TANG4

1. College of Civil Engineering and Architecture, Zhejiang University, Hangzhou 310058, China
2. Engineering Research Center of Urban Underground Development of Zhejiang Province, Hangzhou 310058, China
3. Hangzhou Southwest Testing Technology Co. Ltd, Hangzhou 310015, China
4. College of Civil Engineering, Zhejiang University of Water Resources and Electric Power, Hangzhou 310018, China

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摘要：

为了克服传统低应变反射波法对于承台板下桩完整性及桩长检测方面的局限，开展串行多点拾振检测技术的应用研究. 针对行波在桩基传播过程中存在的能量耗散现象，对既有串行多点拾振检测理论进行修正，引入行波在相邻传感器间传播时的能量耗散，提出考虑行波衰减的串行多点拾振检测信号重构理论. 在此基础上，通过数值分析及现场测试对该技术的适用性和有效性进行验证，并分析桩身信息、传感器布置、激励方式等关键技术指标对重构速度响应曲线的影响. 研究结果表明，对相邻传感器采集到的原始信号进行行波分解以分离出下行波和上行波，并在频域内将上行波与下行波相除定义一个泛频响函数，可有效消除复杂的上部结构振动干扰，同时完整保留中间传感器下方桩基础的全部特征信息. 本研究提出的检测技术能够较为清晰地识别桩底及缺陷反射信号，且预估桩长与实际桩长几乎一致，证明其可有效应用于承台板下桩的完整性检测.

关键词： 承台板下桩; 低应变; 泛频响函数; 虚拟激励; 串行多点拾振

Abstract:

Applied research on the serial multi-point vibration acquisition testing method was conducted to overcome the limitations of the traditional low-strain reflected wave method in detecting the integrity and pile length of piles under bearing slabs. Aiming at the energy dissipation phenomenon of traveling waves during their propagation in piles, the existing serial multi-point vibration acquisition testing theory was revised. The serial multi-point vibration acquisition testing signal reconstruction theory considering traveling wave attenuation was proposed by incorporating the energy dissipation of traveling waves propagating between adjacent sensors. On this basis, the applicability and effectiveness of this method were verified through numerical analysis and field tests. Meanwhile, the influence of key technical indexes such as pile body information, sensor arrangement and excitation mode on the reconstructed velocity response curves was analyzed. The results demonstrated that decomposing the original signals collected by adjacent sensors to separate downward and upward traveling waves, and then defining a generalized frequency response function by dividing the upward traveling waves by the downward traveling waves in the frequency domain, could effectively eliminate the interference from complex vibrations of the superstructure while fully retaining all characteristic information of the pile below the intermediate sensor. The testing method proposed in this study could clearly identify the reflected signals from the pile bottom and defects, and the estimated pile length was almost consistent with the actual pile length, which proved that it could be effectively applied to the integrity detection of piles under bearing slabs.

Key words: piles under bearing slabs low strain generalized frequency response function fictitious excitation serial multi-point vibration acquisition

收稿日期: 2025-05-21 出版日期: 2026-03-19

CLC:

TU 473

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

通讯作者: 吴君涛 E-mail: jiajunjiezju@163.com;wujuntao31@126.com

作者简介: 贾俊杰（2001—），男，硕士生，从事桩基动力理论研究及测试技术开发工作. orcid.org/0009-0000-6262-3594. E-mail：jiajunjiezju@163.com

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引用本文:

贾俊杰,吴君涛,付鹏程,王奎华,朱旭峰,汤旅军. 承台板下桩串行多点拾振检测技术及其理论研究[J]. 浙江大学学报(工学版), 2026, 60(4): 844-854.

Junjie JIA,Juntao WU,Pengcheng FU,Kuihua WANG,Xufeng ZHU,Lvjun TANG. Serial multi-point vibration acquisition testing method for piles under bearing slabs and its theoretical study. Journal of ZheJiang University (Engineering Science), 2026, 60(4): 844-854.

链接本文:

https://www.zjujournals.com/eng/CN/10.3785/j.issn.1008-973X.2026.04.016 或 https://www.zjujournals.com/eng/CN/Y2026/V60/I4/844

图 1 串行多点拾振检测技术传感器布置示意图

图 2 中间传感器下方桩身结构的泛频响函数示意图

表 1 有限元模型材料参数

图 3 承台板下桩有限元模型

图 4 半正弦荷载形式

图 5 传感器原始时变速度信号

图 6 数值分析下的重构速度响应曲线

图 7 浙江大学桩基实训基地桩基础平面布置图

图 8 桩基实训基地支墩方桩结构体系

图 9 串行多点拾振检测技术测试设备

图 10 现场测试下的重构速度响应曲线

图 11 不同瑞利阻尼系数α下的重构速度响应曲线

图 12 不同瑞利阻尼系数β下的重构速度响应曲线

图 13 不同传感器间距下的重构速度响应曲线

图 14 不同中间传感器布设高度下的重构速度响应曲线

图 15 不同激励脉冲宽度下的重构速度响应曲线

图 16 不同激励脉冲幅值下的重构速度响应曲线

图 17 不同激励函数形式下的重构速度响应曲线

图 18 不同缺陷位置下的重构速度响应曲线

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