Influence Mechanism of High Temperature on Drilling Rate and Hardness of Sandstone
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Brotóns, V., Tomás, R., Ivorra, S., & Alarcón, J. C. (2013). Temperature influence on the physical and mechanical properties of a porous rock: San Julian’s calcarenite. Engineering Geology, 167, 117–127.
Corkum, A. G., Asiri, Y., Naggar, H. E. I., & Kinakin, D. (2018). The Leeb hardness test for rock: An updated methodology and UCS correlation. Rock Mechanics and Rock Engineering, 51, 665–675.
Frueh, P., Heine, A., Weber, K. E., & Wickert, M. (2016). Effective depth-of-penetration range due to hardness variation for different lots of nominally identical target material. Defence Technology, 12, 171–176.
Garrido, M. E., Petnga, F. B., Martinez-Ibanez, V., Seron, J. B., Hidalgo-Signes, C., & Tomas, R. (2022). Predicting the uniaxial compressive strength of a limestone exposed to high temperatures by point load and Leeb rebound hardness testing. Rock Mechanics and Rock Engineering, 55, 1–17.
Gaurav, K. S., & Murthy, V. M. S. R. (2021). Drillability prediction in some metamorphic rocks using composite penetration rate index (CPRI): An approach. International Journal of Mining Science and Technology. https://doi.org/10.1016/j.ijmst.2021.05.010
Gautam, P. K., Verma, A. K., Singh, T. N., Hu, W., & Singh, K. H. (2019). Experimental investigations on the thermal properties of Jalore granite rocks for nuclear waste repository. Thermochimica Acta, 681, 178381.
Gustin, A. Z., Zuzek, B., & Podgornik, B. (2021). Hardness measurement of thin strips. Measurement, 182, 109633.
Jamali, S., Wittig, V., Börner, J., Bracke, R., & Ostendorf, A. (2019). Application of high powered Laser Technology to alter hard rock properties towards lower strength materials for more efficient drilling, mining, and Geothermal Energy production. Geomechanics for Energy and the Environment, 20, 100112.
Lakshminarayana, P. V. S., Gautam, J. P., Mastanaiah, P., Madhusudan, R. G., & Bhanu Sankara Rao, K. (2018). Influence of beam power and traverse speed in fibre laser welding of dual phase steel on depth of weld zone penetration, microstructure and hardness. Materials Today: Proceedings, 5, 17132–17138.
Li, X. S. (2018). Experimental study on mechanical properties of grit stone after high temperature. Jiaozuo: Master’s thesis of Henan Polytechnic University. (in Chinese)
Li, M. B., Liu, G. H., Li, J., Zhang, T., & He, M. (2015). Thermal performance analysis of drilling horizontal wells in high temperature formations. Applied Thermal Engineering, 78, 217–227.
Li, Y. H., Lu, G. M., Feng, X. T., & Zhang, X. W. (2017). The influence of heating path on the effect of hard rock fragmentation using microwave assisted method. Chinese Journal of Rock Mechanics and Engineering, 36(6), 1460–1468. (in Chinese).
Liu, X. P., Guo, G. L., & Li, H. Z. (2019). Study on the propagation law of temperature field in surrounding rock of underground coal gasification (UCG) combustion cavity based on dynamic thermal parameters. Results in Physics, 12, 1956–1963.
Martínez-Ibáñez, V., Garrido, M. E., Hidalgo Signes, C., Basco, A., Miranda, T., & Tomás, R. (2021). Thermal effects on the drilling performance of a limestone: Relationships with physical and mechanical properties. Applied Sciences, 11(7), 3286.
Meng, T., Xue, Y. B., Ma, J. W., Yue, Y., Liu, W., Zhang, J., & Li, E. B. (2021). Evolution of permeability and microscopic pore structure of sandstone and its weakening mechanism under coupled thermo-hydro-mechanical environment subjected to real-time high temperature. Engineering Geology, 280, 105955.
Park, J. W., Rutqvist, J., Ryu, D., Park, E. S., & Synn, J. H. (2016). Coupled thermal-hydrological-mechanical behavior of rock mass surrounding a high-temperature thermal energy storage cavern at shallow depth. International Journal of Rock Mechanics and Mining Sciences, 83, 149–161.
Qin, N., Ge, Q., Liang, Z. H., Sun, J. B., & Wang, Y. Y. (2021). Experimental study on macro/micro damage of sandstone caused by high temperature and prediction of uniaxial strength by BP neural network. Journal of Experiment Mechanics, 36(1), 105–113. (in Chinese).
Rossi, E., Jamali, S., Saar, M. O., & Rudolf von Rohr, P. (2020a). Field test of a combined thermo-mechanical drilling technology. Model I: Thermal spallation drilling. Journal of Petroleum Science and Engineering, 190, 107005.
Rossi, E., Jamali, S., Schwarz, D., Saar, M. O., & Rudolf von Rohr, P. (2020b). Field test of a combined thermo-mechanical drilling technology. Mode II: Flame-assisted rotary drilling. Journal of Petroleum Science and Engineering, 190, 106880.
Rossi, E., Jamali, S., Wittig, V., Saar, M. O., & Rudolf von Rohr, P. (2020d). A combined thermo-mechanical drilling technology for deep geothermal and hard rock reservoirs. Geothermics, 85, 101771.
Rossi, E., Saar, M. O., & Rudolf von Rohr, P. (2020c). The influence of thermal treatment on rock-bit interaction: A study of a combined thermo-mechanical drilling (CTMD) concept. Geothermal Energy, 8, 16.
Sarro, R., Pérez-Rey, I., Tomás, R., Alejano, L. R., Hernández-Gutiérrez, L. E., & Mateos, R. M. (2021). Effects of wildfire on rockfall occurrence: A review through actual cases in Spain. Applied Sciences, 11, 2545.
Su, C. D., Wei, S. J., Qin, B. D., & Yang, Y. S. (2018). Research on physical parameters of three kinds of sandstone after high temperature. Chinese Journal of Underground Space and Engineering, 14(2), 341–348. (in Chinese).
Sun, Q., & Zhang, Y. L. (2019). Combined effects of salt, cyclic wetting and drying cycles on the physical and mechanical properties of sandstone. Engineering Geology, 248, 70–79.
Tsybenko, H., Farzam, F., Dehm, G., & Brinckmann, S. (2021). Scratch hardness at a small scale: Experimental methods and correlation to nanoindentation hardness. Tribology International, 163, 107168.
Tuck, J. R., Korsunsky, A. M., Bhat, D. G., & Bull, S. J. (2001). On the application of the work-ofindentation approach to depth-sensing indentation experiments in coated systems. Surface & Coating Technology, 137, 217–224.
Wang, Y. J., Jiang, J. Y., Darkwa, J., Xu, Z. Y., & Zheng, X. F. (2020). Experimental study of thermal fracturing of Hot Dry Rock irradiated by moving laser beam: Temperature, efficiency and porosity. Renewable Energy, 160, 803–816.
Xu, T. H., Wang, M. Y., & Li, J. (2020). Dynamic hardness of rock materials under strong impact loading. International Journal of Impact Engineering, 140, 103555.
Yao, J. H., Tao, M., Zhao, R., Hashemi, S. S., & Wang, Y. Q. (2021). Effect of microwave treatment on thermal properties and structural degradation of red sandstone in rock excavation. Minerals Engineering, 162, 106730.
Yu, Y., Xu, D., Dou, B., Tian, H., Zhang, Y., Zhao, L., Wang, B. H., & Zong, X. (2019). Experimental study on drillability of high temperature granite after water cooling. Geological Science and Technology Information, 38(4), 287–292. (in Chinese).
Zhang, H. M., & Xie, Q. P. (1998). Correction of the indentation hardness-estimating the rock destruction specific energy based on the hardness and plastic co-efficients. Exploration Engineering Media, 3, 49–51.
Zhang, W. Q., & Sun, Q. (2018). Identification of primary mineral elements and macroscopic parameters in the thermal damage process of limestone with canonical correlation analysis. Rock Mechanics and Rock Engineering, 51, 1287–1292.
Zhang, W. Q., Sun, Q., Hao, S. Q., Geng, J. S., & 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.