Abstract
To reveal the damage characteristics of high-temperature granite caused by liquid nitrogen (LN) treatment, ultrasonic, Brazilian splitting, and acoustic emission (AE) tests were performed on high-temperature granite before and after LN treatment. Changes in ultrasonic velocity, tensile strength, energy evolution laws, and AE parameters induced by heating, LN cooling, and LN-induced cryogenic conditions were evaluated and compared. The results showed that LN cooling can create additional cryogenic damage to high-temperature granite, thereby increasing the damage degree. With heating temperature rising, the preliminary damage of high-temperature granite increased significantly. For heating temperatures of < 300 °C, the damage degree induced by LN cooling increased with increase in heating temperature. However, with the preliminary damage of high-temperature granite increasing, the damage induced by LN cooling was weakened. For example, when temperature was > 300 °C, the decreasing amplitudes of ultrasonic velocity, tensile strength, and ultimate elastic and absorbed energies induced by LN cooling decreased with increased heating temperature and were much lower than those induced by heating. Especially, when heating temperature was > 300 °C, the deformation resistance and total shrinkage of high-temperature granite were greatly improved by LN-induced cryogenic conditions. In this case, the tensile strength, ultimate absorbed and elastic energies, and the proportion of elastic energy of LN-frozen samples were larger than the heated samples. This study provides theoretical guidance for hot dry rock fracturing with LN.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Amadei, B., Rogers, J. D., & Goodman, R. E. (1983). Elastic constants and tensile strength of anisotropic rocks. Presented at the 5th ISRM Congress, International Society for Rock Mechanics and Rock Engineering.
Breede, K., Dzebisashvili, K., Liu, X., & Falcone, G. (2013). A systematic review of enhanced (or engineered) geothermal systems: Past, present and future. Geothermal Energy, 1(1), 1–27.
Brown, D. W., & Duchane, D. V. (1999). Scientific progress on the Fenton Hill HDR project since 1983. Geothermics, 28(4–5), 591–601.
Cai, C., Gao, F., Li, G., Huang, Z., & Hou, P. (2016). Evaluation of coal damage and cracking characteristics due to liquid nitrogen cooling on the basis of the energy evolution laws. Journal of Natural Gas Science and Engineering, 29, 30–36.
Cai, C., Li, G., Huang, Z., Shen, Z., Tian, S., & Wei, J. (2014). Experimental study of the effect of liquid nitrogen cooling on rock pore structure. Journal of Natural Gas Science and Engineering, 21, 507–517.
Cai, C., Li, G., Huang, Z., Tian, S., Shen, Z., & Fu, X. (2015). Experiment of coal damage due to super-cooling with liquid nitrogen. Journal of Natural Gas Science and Engineering, 22, 42–48.
Cai, C., Ren, K., & Li, Q. (2019). Numerical simulation of the flow field structure of liquid nitrogen jet. Thermal Science, 23(3 Part A), 1337–1343.
Cai, C., Yang, Y., Liu, J., Gao, F., Gao, Y., & Zhang, Z. (2018). Downhole transient flow field and heat transfer characteristics during drilling with liquid nitrogen jet. Journal of Energy Resources Technology-Transactions of The ASME, 140(12), 122902.
Cha, M., Alqahtani, N. B., Yin, X., Kneafsey, T. J., Yao, B., & Wu, Y. (2017). Laboratory system for studying cryogenic thermal rock fracturing for well stimulation. Journal of Petroleum Science and Engineering, 156, 780–789.
Cha, M., Yin, X., Kneafsey, T., Johanson, B., Alqahtani, N., Miskimins, J., Patterson, T., & Wu, Y. (2014). Cryogenic fracturing for reservoir stimulation–laboratory studies. Journal of Petroleum Science and Engineering, 124, 436–450.
Cheng, Y., Zhang, Y., Yu, Z., & Hu, Z. (2021). Investigation on reservoir stimulation characteristics in hot dry rock geothermal formations of China during hydraulic fracturing. Rock Mechanics and Rock Engineering, 54(8), 3817–3845.
Cooper, H. W., & Simmons, G. (1977). The effect of cracks on the thermal expansion of rocks. Earth and Planetary Science Letters, 36(3), 404–412.
Cui, G., Ren, S., Zhang, L., Wang, Y., & Zhang, P. (2018). Injection of supercritical CO2 for geothermal exploitation from single- and dual-continuum reservoirs: Heat mining performance and salt precipitation effect. Geothermics, 73, 48–59.
Dresen, G., Stanchits, S., & Rybacki, E. (2010). Borehole breakout evolution through acoustic emission location analysis. International Journal of Rock Mechanics and Mining Sciences, 47(3), 426–435.
Feng, Z., Zhao, Y., & Liu, D. (2021). Permeability evolution of thermally cracked granite with different grain sizes. Rock Mechanics and Rock Engineering, 54(4), 1953–1967.
Gao, F., Cai, C., & Yang, Y. (2018). Experimental research on rock fracture failure characteristics under liquid nitrogen cooling conditions. Results in Physics, 9, 252–262.
Hofmann, H., Babadagli, T., & Zimmermann, G. (2014). Hot water generation for oil sands processing from enhanced geothermal systems: Process simulation for different hydraulic fracturing scenarios. Applied Energy, 113, 524–547.
Huang, Z., Wen, H., Wu, X., Li, G., Yang, R., Li, R., & Zhang, C. (2019). Experimental study on cracking of high temperature granite using liquid nitrogen. Journal of China University of Petroleum (Edition of Natural Science), 43(2), 73–81.
Huang, Z., Zhang, S., Yang, R., Wu, X., Li, R., Zhang, H., & Huang, P. (2020). A review of liquid nitrogen fracturing technology. Fuel, 266, 117040.
Jiang, L., Cheng, Y., Han, Z., Gao, Q., Yan, C., Wang, H., & Fu, L. (2019). Effect of liquid nitrogen cooling on the permeability and mechanical characteristics of anisotropic shale. Journal of Petroleum Exploration and Production Technology, 9(1), 111–124.
Kim, K. M., & Kemeny, J. (2009). Effect of thermal shock and rapid unloading on mechanical rock properties. Presented at the 43rd U.S. Rock Mechanics Symposium & 4th U.S.—Canada Rock Mechanics Symposium. American Rock Mechanics Association.
Li, H., Wang, L., Niu, F., Liu, W., & Zhang, C. (2015). Study on effect of freeze-thaw cycle with liquid nitrogen on crack extension of coal at different initial temperatures. China Safety Science Journal, 25(10), 121–126.
Li, Q., Yin, T., Li, X., & Zhang, S. (2020a). Effects of rapid cooling treatment on heated sandstone: A comparison between water and liquid nitrogen cooling. Bulletin of Engineering Geology and the Environment, 79(1), 313–327.
Li, R., Yan, Y., & Huang, Z. (2020b). Thermal and mechanical analysis of LN2 jet impinging on rock surface. Applied Thermal Engineering, 178, 115581.
Liang, C., Li, X., Wang, S., Li, S., Hao, J., & Ma, C. (2012). Experimental investigations on rate-dependent stress–strain characteristics and energy mechanism of rock under uniaxial compression. Chinese Journal of Rock Mechanics and Engineering, 31(9), 1830–1838.
McDaniel, B. W., Grundmann, S. R., Kendrick, W. D., Wilson, D. R., & Jordan, S. W. (1997). Field applications of cryogenic nitrogen as a hydraulic fracturing fluid. Presented at the SPE Annual Technical Conference and Exhibition. Society of Petroleum Engineers. https://doi.org/10.2118/38623-MS
Mellor, M. (1970). Phase composition of pore water in cold rocks (Vol. 292). Corps of Engineers, US Army, Cold Regions Research and Engineering Laboratory.
Qin, L., Zhai, C., Liu, S., Xu, J., Tang, Z., & Yu, G. (2016). Failure mechanism of coal after cryogenic freezing with cyclic liquid nitrogen and its influences on coalbed methane exploitation. Energy & Fuels, 30(10), 8567–8578.
Ren, K., & Cai, C. (2021). Numerical investigation into the distributions of temperature and stress around wellbore during the injection of cryogenic liquid nitrogen into hot dry rock reservoir. Mathematical Problems in Engineering. https://doi.org/10.1155/2021/9913321
Ren, S., Fan, Z., Zhang, L., Yang, Y., Luo, J., & Che, H. (2013). Mechanisms and experimental study of thermal-shock effect on coal-rock using liquid nitrogen. Chinese Journal of Rock Mechanics and Engineering, 32(S2), 3790–3794.
Riahi, A., Pettitt, W., Damjanac, B., & Blanksma, D. (2019). Numerical modeling of discrete fractures in a field-scale FORGE EGS reservoir. Rock Mechanics and Rock Engineering, 52(12), 5245–5258.
Rong, G., Sha, S., Li, B., Chen, Z., & Zhang, Z. (2021). Experimental investigation on physical and mechanical properties of granite subjected to cyclic heating and liquid nitrogen cooling. Rock Mechanics and Rock Engineering, 54(5), 2383–2403.
Tran, D., Settari, A., & Nghiem, L. (2012). Initiation and propagation of secondary cracks in thermo-poroelastic media. Presented at the 46th US Rock Mechanics/Geomechanics Symposium. American Rock Mechanics Association.
Wang, X. Q., Schubnel, A., Fortin, J., Guéguen, Y., & Ge, H. K. (2013). Physical properties and brittle strength of thermally cracked granite under confinement. Journal of Geophysical Research: Solid Earth, 118(12), 6099–6112.
Wang, Y., Jiang, J., Darkwa, J., Xu, Z., Zheng, X., & Zhou, G. (2020). Experimental study of thermal fracturing of Hot Dry Rock irradiated by moving laser beam: Temperature, efficiency and porosity. Renewable Energy, 160, 803–816.
Wu, X., Huang, Z., Cheng, Z., Zhang, S., Song, H., & Zhao, X. (2019a). Effects of cyclic heating and LN2-cooling on the physical and mechanical properties of granite. Applied Thermal Engineering, 156, 99–110.
Wu, X., Huang, Z., Dai, X., Song, H., & Zhang, S. (2020). Thermo-coupled FSI analysis of LN2 jet impinging on hot dry rock. Applied Thermal Engineering, 165, 114621.
Wu, X., Huang, Z., Li, G., Li, R., Yan, P., Deng, X., Mu, K., & Dai, X. (2018b). Experiment on coal breaking with cryogenic nitrogen jet. Journal of Petroleum Science and Engineering, 169, 405–415.
Wu, X., Huang, Z., Li, R., Zhang, S., Wen, H., Huang, P., Dai, X., & Zhang, C. (2018a). Investigation on the damage of high-temperature shale subjected to liquid nitrogen cooling. Journal of Natural Gas Science and Engineering, 57, 284–294.
Wu, X., Huang, Z., Song, H., Zhang, S., Cheng, Z., Li, R., Wen, H., Huang, P., & Dai, X. (2019b). Variations of physical and mechanical properties of heated granite after rapid cooling with liquid nitrogen. Rock Mechanics and Rock Engineering, 52(7), 2123–2139.
Xie, H., Peng, R., Ju, Y., & Zhou, H. (2005). On energy analysis of rock failure. Chinese Journal of Rock Mechanics and Engineering, 24(15), 2603–2608.
Xu, B., Li, N., Li, Z., & Yan, N. (2013). Low-temperature LPG and LNG storage caverns and related research review of rock mechanics. Chinese Journal of Rock Mechanics and Engineering, 32(S2), 2977–2993.
Yang, R., Hong, C., Huang, Z., Wen, H., Li, X., Huang, P., Liu, W., & Chen, J. (2021a). Liquid nitrogen fracturing in boreholes under true triaxial stresses: Laboratory investigation on fractures initiation and morphology. SPE Journal, 26(01), 135–154.
Yang, R., Hong, C., Liu, W., Wu, X., Wang, T., & Huang, Z. (2021b). Non-contaminating cryogenic fluid access to high-temperature resources: Liquid nitrogen fracturing in a lab-scale Enhanced Geothermal System. Renewable Energy, 165, 125–138.
Yang, R., Huang, Z., Shi, Y., Yang, Z., & Huang, P. (2019). Laboratory investigation on cryogenic fracturing of hot dry rock under triaxial-confining stresses. Geothermics, 79, 46–60.
Yukutake, H. (1989). Fracturing process of granite inferred from measurements of spatial and temporal variations in velocity during triaxial deformations. Journal of Geophysical Research: Solid Earth, 94(B11), 15639–15651.
Zhai, C., Qin, L., Liu, S., Xu, J., Tang, Z., & Wu, S. (2016). Pore structure in coal: Pore evolution after cryogenic freezing with cyclic liquid nitrogen injection and its implication on coalbed methane extraction. Energy & Fuels, 30(7), 6009–6020.
Zhang, Z. (2013). Energy evolution mechanism during rock deformation and failure. China University of Mining and Technology.
Zhang, H., Huang, Z., Zhang, S., Yang, Z., & Mclennan, J. D. (2020). Improving heat extraction performance of an enhanced geothermal system utilizing cryogenic fracturing. Geothermics, 85, 101816.
Zhang, S., Huang, Z., Li, G., Wu, X., Peng, C., & Zhang, W. (2018). Numerical analysis of transient conjugate heat transfer and thermal stress distribution in geothermal drilling with high-pressure liquid nitrogen jet. Applied Thermal Engineering, 129, 1348–1357.
Zhang, W., Sun, Q., Hao, S., Geng, J., & Lv, C. (2016). Experimental study on the variation of physical and mechanical properties of rock after high temperature treatment. Applied Thermal Engineering, 98, 1297–1304.
Zhang, W., Wang, C., Guo, T., He, J., Zhang, L., Chen, S., & Qu, Z. (2021). Study on the cracking mechanism of hydraulic and supercritical CO2 fracturing in hot dry rock under thermal stress. Energy, 221, 119886.
Zhu, M. (2019). Study on deformation and failure mechanism of coal and rock under unloading conditions. China University of Mining and Technology.
Acknowledgments
The authors would like to thank the financial support from the National Key R&D Program of China (No. 2020YFA0711800), the National Natural Science Foundation of China (No. 51604263), the Natural Science Foundation of Jiangsu Province (No. BK20180653) and the Project funded by China Postdoctoral Science Foundation (No. 2019M650120).
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of Interest
The authors declared that there is no conflict of interest.
Rights and permissions
About this article
Cite this article
Cai, C., Ren, K., Tao, Z. et al. Experimental Investigation of the Damage Characteristics of High-Temperature Granite Subjected to Liquid Nitrogen Treatment. Nat Resour Res 31, 2603–2627 (2022). https://doi.org/10.1007/s11053-022-10091-2
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11053-022-10091-2