Dynamic response of deep tunnel subjected to contour blasting-unloading considering internal free surface radius

Siyu Peng; Xibing Li; Lisha Liang; Jingyao Gao

doi:10.1016/j.undsp.2025.09.005

Underground Space ›› 2026, Vol. 26 ›› Issue (1) :387 -411. DOI: 10.1016/j.undsp.2025.09.005

Research article

research-article

Dynamic response of deep tunnel subjected to contour blasting-unloading considering internal free surface radius

Author information +

History +

PDF (12811KB)

Abstract

The dynamic stress response of the surrounding rock in deep tunnels during contour blasting is first derived using elastic statics and dynamics theory alongside Fourier transform methods. This solution uniquely accounts for the effects of lateral stress coefficient, blasting loading, two-dimensional unloading, and the redistribution of static stress fields induced by internal free surfaces. Discrete element numerical simulations are also performed and cross-validated with the theoretical model. The study analyzes and discusses the effects of in-situ stress levels, lateral stress coefficients $k$, and internal radius ratio $\tilde{r} _0$ (ratio of internal free surface radius to tunnel radius) on the failure characteristics and mechanisms of surrounding rocks. The results indicate that increasing $\tilde{r} _0$ can reduce the unloading amplitude, thereby decreasing the dynamic circumferential compressive stress and circumferential cracking induced by unloading, especially under high in-situ stress. Under low stress levels, the maximum dynamic radial compressive stress during blasting decreases, reducing radial compression-shear failure. Simultaneously, the dynamic circumferential tensile stress is also reduced, thereby minimizing blasting-induced radial fractures. However, under extreme lateral stress conditions (k < 0.2), adjusting $\tilde{r} _0$ cannot cause the circumferential stress to exceed the radial stress at the tunnel contour along the maximum principal stress direction. As a result, an ideal contour blasting effect cannot be achieved, and failure continues to propagate radially. In conclusion, the derived dynamic blasting-unloading stress response, in relation to the internal radius ratio, provides theoretical analysis tools for understanding the failure characteristics and mechanisms of surrounding rock during contour blasting, serving as a foundation for optimizing blasting and support design.

Keywords

Dynamic response / Contour blasting / Transient unloading / In-situ stress / P-wave and S-wave / Internal radius ratio

Cite this article

Download citation ▾

Siyu Peng, Xibing Li, Lisha Liang, Jingyao Gao. Dynamic response of deep tunnel subjected to contour blasting-unloading considering internal free surface radius. Underground Space, 2026, 26(1): 387-411 DOI:10.1016/j.undsp.2025.09.005

登录浏览全文

4963

注册一个新账户忘记密码

Data availability

The data that support the findings of this study are available from the corresponding author upon reasonable request.

CRediT authorship contribution statement

Siyu Peng: Writing - original draft, Visualization, Validation, Software, Methodology, Formal analysis, Conceptualization. Xibing Li: Supervision, Project administration, Funding acquisition. Lisha Liang: Software, Conceptualization. Jingyao Gao: Writing - review & editing.

Declaration of competing interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Acknowledgement

The research was supported by the National Natural Science Foundation of China (Grant Nos. 51927808 and 52434006) and the Postgraduate Innovation Fund Project of Hunan Province (Grant No. CX20200242). The financial supports are gratefully acknowledged.

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Bhandari, S. (1997). Engineering rock blasting operations. A. A. Balkema.

[2]	Boresi, A., Chong, K., & Lee, J. (2010). Elasticity in Engineering Mechanics. Wiley https://books.google.co.jp/books?id=NEhdMVEX17oC.

[3]	Cao, W., & Younis, R. M. (2024). Empirical scaling of formation fracturing by high-energy impulsive mechanical loads. International Journal of Rock Mechanics and Mining Sciences, 173, 105613.

[4]	Carter, J. P., & Booker, J. R. (1990). Sudden excavation of a long circular tunnel in elastic ground. International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts, 27 (2), 129-132.

[5]	Feng, X. T., Xu, H., Qiu, S. L., Li, S. J., Yang, C. X., Guo, H. S., Cheng, Y., & Gao, Y. H. (2018). In situ observation of rock spalling in the deep tunnels of the China Jinping underground laboratory (2400 m depth). Rock Mechanics and Rock Engineering, 51 (4), 1193-1213.

[6]	Goodman, R. E. (1991). Introduction to Rock Mechanics. Wiley https://books.google.co.jp/books?id=9lK5EAAAQBAJ.

[7]	Hustrulid, W. A. (1999). Blasting principles for open pit mining. CRC Press.

[8]	Jiang, Q., Feng, X. T., Chen, J., Huang, K., & Jiang, Y. (2013). Estimating in-situ rock stress from spalling veins: A case study. Engineering Geology, 152 (1), 38-47.

[9]	Kirsch, C. (1898). Die theorie der elastizitat und die bedurfnisse der festigkeitslehre. Zeitschrift des Vereines Deutscher Ingenieure, 42, 797-807.

[10]	Li, C. J., & Li, X. B. (2018). Influence of wavelength-to-tunnel-diameter ratio on dynamic response of underground tunnels subjected to blasting loads. International Journal of Rock Mechanics and Mining Sciences, 112, 323-338.

[11]	Li, C. J., Li, X. B., & Liang, L. S. (2020). Dynamic response of existing tunnel under cylindrical unloading wave. International Journal of Rock Mechanics and Mining Sciences, 131, 104342.

[12]	Li, S. J., Feng, X. T., Li, Z. H., Chen, B. R., Zhang, C. Q., & Zhou, H. (2012). In situ monitoring of rockburst nucleation and evolution in the deeply buried tunnels of Jinping II hydropower station. Engineering Geology, 137-138, 85-96.

[13]	Li, S. C., Wang, H. P., Qian, Q. H., Li, S. C., Fan, Q. Z., Yuan, L., Xue, J. H., & Zhang, Q. S. (2008). In-situ monitoring research on zonal disintegration of surrounding rock mass in deep mine roadways. Chinese Journal of Rock Mechanics and Engineering, 27 (8), 1545-1553 (in Chinese).

[14]	Li, X. B., Cao, W. Z., Zhou, Z. L., & Zou, Y. (2014). Influence of stress path on excavation unloading response. Tunnelling and Underground Space Technology, 42, 237-246.

[15]

Li, X. B., Chen, J. Z., Ma, C. D., Huang, L. Q., Li, C. J., Zhang, J., & Zhao, Y. Z. (2022). A novel in-situ stress measurement method incorporating non-oriented core ground re-orientation and acoustic emission: A case study of a deep borehole. International Journal of Rock Mechanics and Mining Sciences, 152, 105079.

[16]	Li, X. B., Gong, F. Q., Tao, M., Dong, L. J., Du, K., Ma, C. D., Zhou, Z. L., & Yin, T. B. (2017). Failure mechanism and coupled static-dynamic loading theory in deep hard rock mining: A review. Journal of Rock Mechanics and Geotechnical Engineering, 9 (4), 767-782.

[17]	Li, X. D., Liu, K. W., Sha, Y. Y., Yang, J. C., & Hong, Z. X. (2024a). Experimental and numerical investigation on rock fracturing in tunnel contour blasting under initial stress. International Journal of Impact Engineering, 185, 104844.

[18]	Li, X. D., Liu, K. W., Zhao, X. R., Sha, Y. Y., Yang, J. C., Ma, S. Z., & Hong, Z. X. (2024b). Study on rock fracturing in smooth blasting under initial stress. Engineering Fracture Mechanics, 296, 109865.

[19]	Li, X. H., Zhu, Z. M., Wang, M., Wan, D. Y., Zhou, L., & Liu, R. F. (2021). Numerical study on the behavior of blasting in deep rock masses. Tunnelling and Underground Space Technology, 113, 103968.

[20]	Liang, L. S., Li, X. B., Liu, Z. X., & Peng, S. Y. (2024a). Dynamic responses of U-shaped caverns under transient stress waves in deep rock engineering. Mathematics, 12 (12), 1836.

[21]	Liang, L. S., Li, X. B., Zhu, Q. Q., Peng, S. Y., & Si, X. F. (2024b). Stress distribution and failure characteristics around U-shaped caverns with different height-to-width ratios under biaxial compression. Engineering Failure Analysis, 156, 107800.

[22]	Lin, P., Liu, H. Y., & Zhou, W. Y. (2015). Experimental study on failure behaviour of deep tunnels under high in-situ stresses. Tunnelling and Underground Space Technology, 46, 28-45.

[23]	Liu, H. L., Huang, L. Q., Wang, Z. W., Wu, Y. C., & Li, X. B. (2024). Experimental study on dynamic response of hard rock blasting under in-situ stress. International Journal of Rock Mechanics and Mining Sciences, 182, 105860.

[24]	Lu, W. B., Yang, J. H., Yan, P., Chen, M., Zhou, C. B., Luo, Y., & Jin, L. (2012). Dynamic response of rock mass induced by the transient release of in-situ stress. International Journal of Rock Mechanics and Mining Sciences, 53, 129-141.

[25]	Miklowitz, J. (1978). The theory of elastic waves and waveguides. North Holland Publishing Company.

[26]	Peng, S. Y., Li, X. B., Gao, J. Y., & Liang, L. S. (2024a). Energy evolution and failure mechanism of tunnel dynamic unloading in deep rock mass abounding in closable minor joints. Tunnelling and Underground Space Technology, 154, 106132.

[27]	Peng, S. Y., Li, X. B., Li, C. J., Liang, L. S., & Huang, L. Q. (2024b). Crack-closure behavior and stress-sensitive wave velocity of hard rock based on flat-joint model in particle-flow-code (PFC) modeling. Computers and Geotechnics, 170, 106320.

[28]	Peng, S. Y., Li, X. B., Mitani, Y., & Gao, J. Y. (2025). Multiple-stage dynamic responses and failure behaviors of surrounding rocks subjected to development blasting: Exponential and triangular paths. Journal of Rock Mechanics and Geotechnical Engineering, 17 (6), 3773-3789.

[29]	Persson, P. A., Holmberg, R., & Lee, J. (1994). Rock blasting and explosives engineering. CRC Press.

[30]	Read, R. S., Chandler, N. A., & Dzik, E. J. (1998). In situ strength criteria for tunnel design in highly-stressed rock masses. International Journal of Rock Mechanics and Mining Sciences, 35 (3), 261-278.

[31]	Si, X. F., Li, X. B., Gong, F. Q., Huang, L. Q., & Liu, X. L. (2022). Experimental investigation of failure process and characteristics in circular tunnels under different stress states and internal unloading conditions. International Journal of Rock Mechanics and Mining Sciences, 154, 105116.

[32]	Su, G. S., Chen, Y. X., Jiang, Q., Li, C. J., & Cai, W. (2023). Spalling failure of deep hard rock caverns. Journal of Rock Mechanics and Geotechnical Engineering, 15 (8), 2083-2104.

[33]	Svanholm, B. O., Persson, P. A., & Larsson, B. (1978). Smooth blasting for reliable underground openings. In Proceedings of the First International Symposium (pp.573-579 ).

[34]	Tao, J., Yang, X. G., Li, H. T., Zhou, J. W., Fan, G., & Lu, G. D. (2020). Effects of in-situ stresses on dynamic rock responses under blast loading. Mechanics of Materials, 145, 103374.

[35]	Yang, J. P., Chen, W. Z., Zhao, W. S., Tan, X. J., Tian, H. M., Yang, D. S., & Ma, C. S. (2017a). Geohazards of tunnel excavation in interbedded layers under high in situ stress. Engineering Geology, 230, 11-22.

[36]	Yang, J. H., Jiang, Q. H., Zhang, Q. B., & Zhao, J. (2018). Dynamic stress adjustment and rock damage during blasting excavation in a deep-buried circular tunnel. Tunnelling and Underground Space Technology, 71, 591-604.

[37]	Yang, J. H., Yao, C., Jiang, Q. H., Lu, W. B., & Jiang, S. H. (2017b). 2D numerical analysis of rock damage induced by dynamic in-situ stress redistribution and blast loading in underground blasting excavation. Tunnelling and Underground Space Technology, 70, 221-232.

[38]	Yi, C. P., Johansson, D., & Greberg, J. (2018). Effects of in-situ stresses on the fracturing of rock by blasting. Computers and Geotechnics, 104, 321-330.

[39]	Yilmaz, O., & Unlu, T. (2013). Three-dimensional numerical rock damage analysis under blasting load. Tunnelling and Underground Space Technology, 38, 266-278.

[40]	Zhao, R., Tao, M., Zhao, H. T., Wu, C. Q., & Cao, W. Z. (2023). Theoretical study on dynamic stress redistribution around circular tunnel with different unloading paths. Computers and Geotechnics, 163, 105737.

[41]	Zhou, J., Zhang, Y. L., Li, C. Q., He, H. N., & Li, X. B. (2024). Rockburst prediction and prevention in underground space excavation. Underground Space, 14, 70-98.

[42]	Zhu, H. H., Yan, J. X., & Liang, W. H. (2019a). Challenges and development prospects of ultra-long and ultra-deep mountain tunnels. Engineering, 5 (3), 384-392.

[43]	Zhu, J. B., Li, Y. S., Peng, Q., Deng, X. F., Gao, M. Z., & Zhang, J. G. (2021). Stress wave propagation across jointed rock mass under dynamic extension and its effect on dynamic response and supporting of underground opening. Tunnelling and Underground Space Technology, 108, 103648.

[44]	Zhu, Q. Q., Li, C. J., Li, X. B., Li, D. Y., Wang, W. H., & Chen, J. Z. (2022). Fracture mechanism and energy evolution of sandstone with a circular inclusion. International Journal of Rock Mechanics and Mining Sciences, 155, 105139.

[45]	Zhu, Q. Q., Li, D. Y., Han, Z. Y., Li, X. B., & Zhou, Z. L. (2019b). Mechanical properties and fracture evolution of sandstone specimens containing different inclusions under uniaxial compression. International Journal of Rock Mechanics and Mining Sciences, 115, 33-47.

[46]	Zhu, W. C., Wei, J., Zhao, J., & Niu, L. L. (2014). 2D numerical simulation on excavation damaged zone induced by dynamic stress redistribution. Tunnelling and Underground Space Technology, 43, 315-326.