隔热涂层对高温隧洞支护结构温度应力的影响

doi:10.11988/ckyyb.20240730

raybet体育在线院报 ›› 2025, Vol. 42 ›› Issue (9): 185-191.DOI: 10.11988/ckyyb.20240730

隔热涂层对高温隧洞支护结构温度应力的影响

黄灵芝¹^,²(), 张朝森³, 杨砾⁴, 付登辉⁴, 司政¹^,²

¹ 西安理工大学西北旱区生态水利工程国家重点实验室,西安 710048
² 西安理工大学水利水电学院,西安 710048
³ 中国电力工程顾问集团西北电力设计院有限公司,西安 710075
⁴ 陕西省水利电力勘测设计研究院,西安 710001

收稿日期:2024-07-10 修回日期:2024-10-22 出版日期:2025-09-01 发布日期:2025-09-01
作者简介:
黄灵芝(1982-),女,湖北松滋人,副教授,博士,主要从事水工结构安全评价等方面的研究。E-mail:hlzsz@126.com
基金资助:
国家自然科学基金项目(51879217)

Influence of Thermal Insulation Coating on Temperature Stress in Support Structures of High-Temperature Tunnels

HUANG Ling-zhi¹^,²(), ZHANG Chao-sen³, YANG Li⁴, FU Deng-hui⁴, SI Zheng¹^,²

¹ State Key Laboratory of Eco-Hydraulics in Northwest Arid Regions of China, Xi’an University of Technology,Xi’an 710048, China
² School of Water Resources and Hydro-electric Engineering, Xi’an University of Technology, Xi’an 710048, China
³ China Power Engineering Consulting Group Northwest Electric Power Design Institute Co., Ltd., Xi’an 710075, China
⁴ Shaanxi Provincial Water Resources and Electric Power Survey and Design Institute, Xi’an 710001, China

Received:2024-07-10 Revised:2024-10-22 Published:2025-09-01 Online:2025-09-01

摘要/Abstract

摘要：

为解决高地温引水隧洞支护结构在运行过程中因拉应力过大导致的开裂问题,以某高地温引水隧洞为例,采用三维有限元仿真技术,模拟了不同隔热涂层厚度条件下隧洞全生命周期的温度与应力变化,并评估了其对抗裂安全性的提升作用。研究发现,随着隔热涂层厚度的增加,二次衬砌内外温差显著减小,同时,在过水前施加隔热涂层能够有效降低运行期二次衬砌所受拉应力,且涂层厚度与拉应力降幅之间呈正相关关系,不满足抗裂安全标准的区域面积也相应减少。当隔热涂层厚度为2 mm时,二次衬砌各部位拉应力均保持在材料极限抗拉强度之下,且大部分部位能满足抗裂安全度≥1.6的要求。研究成果可为类似高地温隧洞支护结构温控防裂提供参考。

关键词: 高地温引水隧洞, 有限元仿真, 温度场, 应力场, 抗裂安全度

Abstract:

[Objective] This study focuses on the issue of cracking in the support structures of high-temperature water diversion tunnels during the operation period caused by excessive tensile stress. An active thermal control strategy involving the application of thermal insulation coatings with specific thicknesses before water flow in the tunnel is proposed and systematically quantified. This study evaluates the regulatory effect of this strategy on the temperature and stress fields throughout the life cycle of the tunnel (from construction to operation) and its role in improving crack resistance safety. [Methods] Based on a three-dimensional thermo-mechanical coupled finite element method, a typical high-temperature water diversion tunnel was used as the engineering background. The temperature evolution and stress response of the structure under different thermal insulation coating thicknesses were precisely simulated. [Results] The thermal insulation coating significantly improved the temperature gradient of the secondary lining. As the coating thickness increased, the temperature difference between the inner and outer sides notably decreased. The application of thermal insulation coating before water flow in the tunnel effectively suppressed the temperature difference between the inner and outer sides of the secondary lining and the resulting tensile stresses. The coating thickness was positively correlated with the reduction in tensile stress, leading to a corresponding decrease in the area of zones that did not meet crack resistance safety criteria. In particular, when the coating thickness was 2 mm, the peak tensile stresses at all key locations of the secondary lining were below the ultimate tensile strength of the material. Except for localized high-stress zones, the crack resistance safety factor in the majority of the zones remained stable above 1.6, significantly outperforming the no-coating or thin-coating schemes. [Conclusion] Pre-applying a thermal insulation coating of appropriate thickness (such as 2 mm) before water flow in the tunnel is a highly efficient and innovative thermal control and cracking prevention strategy. This source-intervention approach significantly reduces the tensile stresses induced by temperature loads, fundamentally enhancing the structural safety and durability of high-temperature tunnels during long-term operation. The research findings provide direct quantitative design guidance and key technical support for similar engineering projects.

Key words: high-temperature water diversion tunnel, finite element simulation, temperature field, stress field, crack resistance safety degree

中图分类号:

TV672.1

黄灵芝, 张朝森, 杨砾, 付登辉, 司政. 隔热涂层对高温隧洞支护结构温度应力的影响[J]. raybet体育在线院报, 2025, 42(9): 185-191.

HUANG Ling-zhi, ZHANG Chao-sen, YANG Li, FU Deng-hui, SI Zheng. Influence of Thermal Insulation Coating on Temperature Stress in Support Structures of High-Temperature Tunnels[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(9): 185-191.

图/表 8

图1 有限元计算模型

Fig.1 Finite element calculation models

表1 围岩及支护混凝土热力学参数

Table 1 Thermo-mechanical parameters of surrounding rock and supporting concrete

材料	密度/ (kg·m^-3)	弹性模量/ GPa	泊松比	线膨胀系数/ (10^-6 ℃)	导热系数/ (W·(m·℃)^-1)	比热/ (J·(kg·K)^-1)	对流换热系数/(W·(m²·℃)^-1)
材料	密度/ (kg·m^-3)	弹性模量/ GPa	泊松比	线膨胀系数/ (10^-6 ℃)	导热系数/ (W·(m·℃)^-1)	比热/ (J·(kg·K)^-1)	空气	水
围岩	2 653	7.5	0.250	5	20	1 000	35	—
一次衬砌	2 347	23.0	0.167	5	11	950	30	—
二次衬砌	2 347	28.0	0.167	8	8	950	30	100

表2 各方案对应的等效对流换热系数

Table 2 Equivalent convective heat transfer coefficients for each scheme

方案	隔热涂层厚度/mm	等效对流换热系数/(W·(m²·℃)^-1)
方案	隔热涂层厚度/mm	与空气接触	与水接触
1	0	30.00	100.00
2	0.5	13.33	40.00
3	1.0	11.43	26.67
4	1.5	10.00	20.00
5	2.0	8.89	16.00

图2 二次衬砌内、外侧温度及内外侧温度差时程曲线

Fig.2 Time-history curves of inner-side and outer-side temperatures and temperature differences of secondary lining

表3 运行期末不同隔热涂层厚度下二次衬砌各关键点温度

Table 3 Temperatures at key points of secondary lining under different thermal insulation coating thicknesses at the end of operation period

关键点	不同隔热涂层厚度下温度/℃
关键点	0 mm	0.5 mm	1.0 mm	1.5 mm	2.0 mm
点1	8.464	13.100	16.527	19.622	22.429
点2	16.591	20.701	23.739	26.483	28.970
点3	23.813	27.455	30.147	32.578	34.782

图3 二次衬砌内侧最大主应力时程曲线

Fig.3 Time history curves of maximum principal stress inner-side of secondary lininy

表4 运行期末不同隔热涂层厚度下二次衬砌应力

Table 4 Stresses of secondary lining under different thermal insulation coating thicknesses at the end of operation period

隔热涂层厚度/mm	最大主应力/MPa
	拱顶			拱腰			拱底
	点1	点2	点3	点4	点5	点6	点7	点8	点9
0	4.308	1.643	1.126	2.546	0.728	0.682	4.280	1.649	1.154
0.5	3.353	0.949	0.632	1.421	-0.128	-0.196	3.334	0.958	0.659
1.0	2.648	0.437	0.266	0.588	-0.254	-0.303	2.635	0.448	0.294
1.5	2.011	0.043	-0.064	0.014	-0.300	-0.378	2.003	0.032	-0.036
2.0	1.434	-0.198	-0.302	-0.294	-0.342	-0.444	1.431	-0.217	-0.326

图4 二次衬砌在不同隔热涂层厚度下运行期末的抗裂安全度

Fig.4 Safety degree of crack resistance of secondary lining under different thermal insulation coating thicknesses at the end of operation

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隔热涂层对高温隧洞支护结构温度应力的影响

Influence of Thermal Insulation Coating on Temperature Stress in Support Structures of High-Temperature Tunnels

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