上海地区基坑前撑式注浆钢管优化设计研究

张宁

doi:10.20265/j.cnki.issn.1007-2993.2025-0002

上海地区基坑前撑式注浆钢管优化设计研究

doi: 10.20265/j.cnki.issn.1007-2993.2025-0002

张宁

上海山南勘测设计有限公司，上海　201206

详细信息

作者简介:
张　宁，男，1989年生，硕士，高级工程师，主要从事软土地区基坑围护设计及研究。E-mail：814895935@qq.com

中图分类号: TU473
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- 文章访问数: 65
- HTML全文浏览量: 21
- PDF下载量: 17
- 被引次数: 0
出版历程
- 收稿日期: 2025-01-02
- 修回日期: 2025-06-18
- 录用日期: 2025-08-25
- 网络出版日期: 2026-06-08
- 刊出日期: 2026-06-08

Optimum design of front-braced grouting steel pipe system in the foundation pit engineering in Shanghai

ZHANG Ning

Shanghai Shannan Investigation and Design Co., Ltd., Shanghai 201206, China

摘要

摘要: 通过对比分析上海地区不同地质条件下前撑式注浆钢管围护体系的规范计算和实测变形特性，提出了提高承载力和围护桩变形控制的优化设计方法及措施，并通过数值模拟进行了验证。研究结果表明：（1）对于基坑底和前撑桩底土质均不佳的基坑工程，围护体系实测变形显著大于规范计算值，前撑桩最优水平夹角为45°，施工过程中采用分区挖土，增设预制垫层等方式，可以减小围护桩10%左右的总变形，通过减小单次开挖面积可以进一步控制围护桩变形；（2）对于基坑坑底土质不佳，前撑桩底土质较好的基坑工程，围护桩实测变形稍大于规范计算值，可以加大前撑桩的水平夹角至50°～55°，在水平承载力不变的前提下可减短前撑桩桩长，提升经济性，并通过分区挖土及设置垫层的方式控制变形，同时需关注围护桩与围檩间的抗剪设计；（3）对于基坑坑底及前撑桩底土质均较好的基坑工程，围护桩实测变形与规范计算值较为接近，可以减小前撑桩水平夹角至30°～35°，在水平承载力不变的前提下减短前撑桩长度，控制围护桩桩顶变形，同时提升经济性。
- 上海地区 /
- 前撑式注浆钢管 /
- 基坑工程 /
- 优化设计
Abstract: Through comparative analysis of the code-calculated and measured deformation characteristics of the front-braced grouting steel pipe system under different geological conditions in Shanghai, optimized design methods and measures for improving bearing capacity and controlling the deformation of retaining piles are proposed and verified by numerical simulation. The results show that: (1) For foundation pits with poor soil conditions at both the pit bottom and the front-braced pile bottom, the measured deformation of the retaining system is significantly larger than the code-calculated value. The optimal horizontal angle of the front-braced piles is 45°. Zoned excavation and the addition of precast cushions during construction can reduce the total deformation of retaining piles by approximately 10%. Further deformation control can be achieved by reducing the single excavation area. (2) For foundation pits with poor soil at the pit bottom but good soil at the front-braced pile bottom, the measured deformation of retaining piles is slightly larger than the code-calculated value. The horizontal angle of front-braced piles can be increased to 50°~55°, which shortens the pile length while maintaining the same horizontal bearing capacity, thus improving economic efficiency. Deformation can be controlled via zoned excavation and cushion installation, and attention should be paid to the shear design between retaining piles and wales. (3) For foundation pits with good soil at both the pit bottom and the front-braced pile bottom, the measured deformation of retaining piles is close to the code-calculated value. The horizontal angle of front-braced piles can be reduced to 30°~35°, which shortens the pile length under constant horizontal bearing capacity, controls the deformation of the pile top, and also improves economic efficiency.
- Shanghai district /
- front-braced grouting steel pipe /
- foundation pit /
- optimum design

HTML全文

图 1 前撑式注浆钢管围护体系剖面示意图

Figure 1. Generalized section of prestressed grouting steel pipe system

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图 2 规范计算与实测围护桩侧向位移对比曲线

Figure 2. Correlation curve of standard calculation and measured lateral displacement of retaining pile

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图 3 工程一前撑桩承载力优化对比图

Figure 3. Comparison diagram of optimization bearing capacity for the prestressed grouting steel pipe system in Project One

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图 4 工程二前撑桩承载力优化对比图

Figure 4. Comparison diagram of optimization bearing capacity for the prestressed grouting steel pipe system in Project Two

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图 5 工程三前撑桩承载力优化对比图

Figure 5. Comparison diagram of optimization bearing capacity for the prestressed grouting steel pipe system in Project Three

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图 6 围护体变形控制优化措施示意图

Figure 6. Schematic diagram of the deformation controlling measures of the foundation pit retaining pile

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图 7 模拟过程工况图

Figure 7. Simulation process condition diagram

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图 8 数值计算结果对比图

Figure 8. Comparison diagram of simulation results

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表 1 工程概况及土层物理力学性质指标

Table 1. Project profile and physical and mechanical properties index of soil

工程概况	土层序号	土层名称	天然重度 γ/ （kN·m⁻³）	黏聚力 c_cq/kPa	内摩擦角 φ_cq/（°）	平均层厚/m	比贯入阻力P_s/MPa	桩侧极限摩阻力标准值 f_s/kPa	桩端极限端阻力标准值 f_p/kPa
工程一：面积50122 m²，挖深6.65 m，围护结构：SMW工法桩（ϕ850@600 mm三轴搅拌桩内插H700×300 mm型钢）+前撑式注浆钢管（ϕ377×10 mm，倾角45°，L=26 m@3600 mm，端部9 m注浆）	①	填土	18	10	10.0	1.82
	②	粉质黏土	18.9	22	21.5	1.73	0.73	15
	③（坑底）	淤泥质粉质黏土	17.8	16	16.0	4.10	0.47	15
	③_夹	砂质粉土	18.5	6	29.5	1.96	1.30	15
	④	淤泥质黏土	16.9	13	12.0	8.94	0.60	20
	⑤₁（桩底）	黏土	17.5	17	15.0	9.18	0.93	35	400
工程二：面积29217 m²，挖深5.75 m，围护结构：SMW工法（2ϕ700@1000 mm双轴搅拌桩内插H500×300 mm型钢）+前撑式注浆钢管（ϕ377×10 mm，倾角45°，L=27 m@4000 mm，端部9 m注浆）	①	填土	18	10	10.0	4.53
	③₂（坑底）	砂质粉土	18.5	2	30.5	2.19	1.87	15
	③₃	淤泥质粉质黏土	17.6	12	16.5	3.49	0.48	15
	④	淤泥质黏土	16.8	11	11.0	6.03	0.60	25
	⑤₁	黏土	17.5	16	13.0	2.93	0.76	30
	⑤_2-1（桩底）	粉砂	18.9	4	33.0	3.70	4.91	55	1250
工程三：面积21648 m²，挖深4.75 m，围护结构：SMW工法（ϕ650@450 mm三轴搅拌桩内插H500×300 mm型钢）+前撑式注浆钢管（ϕ377×10 mm，倾角45°，L=28 m@4500 mm，全长注浆）	①₁	填土	18	10	10.0	1.99
	①₂	淤泥	18	10	10.0	1.28
	③（坑底）	淤泥质粉质黏土	17.3	12	11.5	1.83	0.43	15
	⑥₁	粉质黏土	19.3	38	15.5	4.20	2.42	40	750
	⑥_3-1（桩底）	粉质黏土	18.5	27	15.0	10.34	4.04	35	500

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表 2 模拟工况

Table 2. Simulated conditions

工程类别	模拟方案	方案内容
工程一	方案一	钢管26 m，倾角45°，原岛式开挖
工程一	方案二	钢管26 m，倾角45°，优化后开挖
工程二	方案一	钢管26 m，倾角45°，原岛式开挖
	方案二	钢管25 m，倾角52°，原岛式开挖
	方案三	钢管25 m，倾角52°，优化后开挖
工程三	方案一	钢管26 m，倾角45°，原岛式开挖
	方案二	钢管23 m，倾角35°，原岛式开挖
	方案三	钢管23 m，倾角35°，优化后开挖
注：基坑挖深6.65 m，围护结构为SMW工法桩（ϕ850@600 mm三轴搅拌桩内插H700×300 mm型钢）+前撑式注浆钢管（ϕ377 × 10 mm，间距3.6 m）。方案二和方案三前撑桩角度和长度调整后与方案一承载力水平分力基本一致。

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表 3 优化措施模拟结果对比表

Table 3. Comparison table of simulation results of optimization measures

工程类别	模拟方案	围护体侧向最大位移/mm	结论
工程一	方案一	56.9
工程一	方案二	51.2	与方案一相比，造价相当，变形减小10%
工程二	方案一	49.7
	方案二	51.2	与方案一相比，造价节约4%，变形增大3%
	方案三	47.1	与方案一相比，造价节约4%，变形减小5%
工程三	方案一	8.9
	方案二	6.9	与方案一相比，造价节约11.5%，变形减小22.5%
	方案三	6.4	与方案一相比，造价节约11.5%，变形减小28%

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