考虑初支混凝土溶蚀与排水系统结晶双重效应的隧道结构安全与韧性分析

周瑜; 宋恒祥; 刘小飞; 林壮宏; 王安怀; 戴晓威

doi:10.20265/j.cnki.issn.1007-2993.2025-0058

考虑初支混凝土溶蚀与排水系统结晶双重效应的隧道结构安全与韧性分析

doi: 10.20265/j.cnki.issn.1007-2993.2025-0058

周瑜^{1, 2,},
宋恒祥^{1, 2},
刘小飞³,
林壮宏³,
王安怀⁴,
戴晓威^{1, 2,}

1.
广东华路交通科技有限公司，广东广州　510420
2.
广东省隧道工程安全与应急保障技术及装备企业重点实验室，广东广州　510420
3.
广东省南粤交通仁新高速公路管理处，广东韶关　512638
4.
广东省南粤交通投资建设有限公司，广东广州　510623

基金项目: 广东省交通集团有限公司科技项目（JT2023YB20，JT2022YB35）；广东省重点领域研发计划资助项目（2002B0101070001）

详细信息

作者简介:
周　瑜，男，1987年生，博士，高级工程师，主要从事隧道工程方向研究。E-mail：zhouyu_cug@163.com

中图分类号: U451
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- 文章访问数: 31
- HTML全文浏览量: 20
- PDF下载量: 3
- 被引次数: 0
出版历程
- 收稿日期: 2025-02-12
- 修回日期: 2025-06-23
- 录用日期: 2025-08-25
- 网络出版日期: 2026-06-08
- 刊出日期: 2026-06-08

Safety and resilience analysis of tunnel structures considering the dual effects of primary support concrete dissolution and crystallization in drainage system

ZHOU Yu^{1, 2
,},
SONG Hengxiang^{1, 2},
LIU Xiaofei³,
LIN Zhuanghong³,
WANG Anhuai⁴,
DAI Xiaowei^{1, 2
,}

1.
Guangdong Hualu Transport Technology Co., Ltd., Guangzhou 510420, Guangdong, China
2.
Guangdong Provincial Key Laboratory of Tunnel Safety Technology and Emergency Support Technology & Equipment, Guangzhou 510420, Guangdong, China
3.
Renxin Expressway Management Office in Guangdong Province Nan Yue Traffic Investment and Construction Co., Ltd., Shaoguan 512638, Guangdong, China
4.
Guangdong Province Nan Yue Traffic Investment and Construction Co., Ltd., Guangzhou 510623, Guangdong, China

摘要

摘要: 为探明初支混凝土溶蚀与排水系统结晶双重效应对隧道结构安全的影响，开展了碳酸侵蚀环境下水泥基材料的溶蚀试验，推导了双重效应作用下隧道结构受力的理论分析方法，以工程案例计算双重效应对隧道结构安全与韧性的影响规律。结果表明：（1）碳酸侵蚀环境中水泥基材料的强度表现出在一定的区间内波动式衰减的规律，拟合得到了双指数型强度衰减系数公式；（2）双重效应引发的隧道二衬结构应力增量与初支混凝土溶蚀衰减系数β呈反比，与溶蚀沉积转换系数δ呈正比，增量的主导地位主要受δ控制；（3）经预测，工程案例隧道运营10年后，其结构安全系数和韧性指标将分别下降17.3%和15.3%，趋近安全极限。因此，初支混凝土溶蚀和排水系统结晶双重效应对隧道结构的长期影响不可忽视，应在设计阶段予以充分考虑，并加强养护期的工程措施。
- 隧道工程 /
- 初支混凝土溶蚀 /
- 排水系统结晶 /
- 结构安全 /
- 韧性分析 /
- 双重效应
Abstract: To elucidate the impact of the dual effects of primary support concrete dissolution and crystallization in drainage system on the safety of tunnel structures, a series of dissolution tests on cement-based materials under carbonation conditions were conducted. A theoretical analysis method for the stresses on tunnel structures under the dual effects was derived, and the impact of these effects on the safety and resilience was calculated in a case study. The results indicate the following: (1) Under carbonation environments, the strength of cement-based materials exhibits an oscillatory attenuation pattern within a specific range. A dual-exponential formula was fitted to characterize the strength degradation coefficient. (2) The stress increment in the tunnel lining caused by the dual effects is inversely proportional to the decay coefficient β of the primary support concrete and directly proportional to the dissolution-deposition conversion coefficient δ. The dominance of the stress increment primarily are controlled by δ. (3) Analysis predicts declines of 17.3% in the structural safety factor and 15.3% in the resilience index after 10 years of tunnel operation, which is approaching safe limits. Therefore, the long-term impact of the dual effects of primary support concrete dissolution and crystallization in drainage system on tunnel structures cannot be overlooked. These effects should be given full consideration during the design and construction phases, and engineering measures during the maintenance phase should be strengthened.
- tunnel engineering /
- primary support concrete dissolution /
- crystallization in drainage systems /
- structure safety /
- resilience analysis /
- dual effect

HTML全文

图 1 广东省高速公路隧道排水系统结晶分布情况

Figure 1. Crystalline distribution in the drainage system of highways tunnels in Guangdong Province

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图 2 隧道排水系统典型结晶堵塞情况

Figure 2. Typical crystalline clogging in tunnel drainage system

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图 3 水泥砂浆抗压强度随溶蚀时间的变化规律曲线

Figure 3. Variation of cement mortar compressive strength with erosion time

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图 4 三层厚壁圆筒理论分析模型

Figure 4. Three-layer thick-walled cylinder theoretical analysis model

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图 5 不同溶蚀沉积转换系数δ条件下二次衬砌环向应力（r=r₀，β=0.8）

Figure 5. Circumferential stresses in concrete lining under different dissolution-deposition conversion coefficient δ conditions (r=r₀，β=0.8)

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图 6 不同初支混凝土强度衰减系数β条件下二次衬砌环向应力（r=r₀，δ=5×10⁻⁵）

Figure 6. Circumferential stresses in concrete lining under different decay coefficients of primary support β (r=r₀，δ=5×10⁻⁵)

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图 7 二次衬砌附加水压力变化曲线

Figure 7. Variation of water pressure behind tunnel lining

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图 8 隧道结构安全系数与运营时间变化曲线

Figure 8. Variation of safety factor of tunnel linning with operating time

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图 9 双重效应下隧道结构性能曲线示意图

Figure 9. Schematic diagram of tunnel structure performance under the dual effect

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图 10 隧道结构性能指标整年变化

Figure 10. Variations of tunnel structure performance indicator during a whole year

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图 11 隧道结构性能指标趋势项T(t)

Figure 11. The trend term of tunnel structure performance indicator

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图 12 隧道结构性能指标季节项S(t)+I(t)

Figure 12. The seasonal term and random term of tunnel structural performance indicator during a whole year

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图 13 隧道结构性能指标10年变化

Figure 13. Variations of tunnel structure performance indicator during 10 years

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图 14 隧道韧性指标变化情况

Figure 14. Variations of tunnel resilience indicators

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表 1 水泥砂浆物理力学性能指标

Table 1. Physical and mechanical properties of cement mortar

项目	比表面积/（m²·kg⁻¹）	标准稠度/%	凝结时间/min		抗压强度/MPa
项目	比表面积/（m²·kg⁻¹）	标准稠度/%	初凝	终凝	抗压强度/MPa
测值	346	25.5	157	201	38.38

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表 2 理论分析的参数

Table 2. Parameters for theoretical analysis

序号	参数	取值	单位	备注
1	r₀	5	m
2	r₁	5.3	m
3	r₂	5.5	m	围岩内径
4	r₃	25	m	5倍洞径
5	P₃	2.7	MPa	100 m埋深
6	H	50	m	50 m地下水头
7	γ	10	kN·m⁻³
8	V	0.019	m³	ϕ110 mm纵向排水管
9	m₂	1.493×10⁴	kg
10	ρ_S	2.93	kg·m⁻³
11	E₁	28	GPa	二衬弹性模量
12	E₂	28	GPa	初支弹性模量
13	E₃	35	GPa	围岩弹性模量
14	μ₁	0.2		二衬泊松比
15	μ₂	0.2		初支泊松比
16	μ₃	0.3		围岩泊松比

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表 3 计算参数

Table 3. Parameters for model calculation

参数	重度γ/(kN·m⁻³)	弹性模量E/GPa	泊松比μ	内摩擦角φ/(°)	弹性抗力系数K/(MPa·m⁻¹)
V级围岩	19.5	16	0.38	45	150
二次衬砌	23	30	0.2

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