http://orcid.org/0000-0002-4181-5463
Reference
- Deng K, Liu W, Xia T, et al. Experimental study the collapse failure mechanism of cemented casing under non-uniform load. Eng Fail Anal. 2017;73:1–10.
- Zhang H, Shen R, Yuan G, et al. Cement sheath integrity analysis of underground gas storage well based on elastoplastic theory. J Petrol Sci Eng. 2017;159:818–829.
- Liu Y, Yan H, Yu X, et al. Negative impacts of borehole pressure change on cement sheath sealing integrity and countermeasures. Nat Gas Ind. 2014;34:95–98.
- Cheng XW, Mei K, Li Z, et al. Research on the interface structure during unidirectional corrosion for oil-well cement H2S based on computed tomography technology. Ind Eng Chem Res. 2016;55:10889–10895.
- Wang H, Ge Y, Shi L. Technologies in deep and ultra-deep well drilling: present status, challenges and future trend in the 13th Five-Year Plan period (2016–2020). Nat Gas Ind B. 2017;4:319–326.
- Li Z, Zhang K, Guo X, et al. Study of the failure mechanisms of a cement sheath based on an equivalent physical experiment. J Nat Gas Sci Eng. 2016;31:331–339.
- He L, Feng W, Wang Y, et al. Oil well perforation technology: Status and prospects. Petrol Explor Dev. 2014;41:798–804.
- Wang W, Taleghani AD. Three-dimensional analysis of cement sheath integrity around wellbores. J Petrol Sci Eng. 2014;121:38–51.
- Lv SH, Deng LJ, Yang WQ, et al. Fabrication of polycarboxylate/graphene oxide nanosheet composites by copolymerization for reinforcing and toughening cement composites. Cement Concrete Comp. 2016;66:1–9.
- Geng J, Sun Q, Zhang W, et al. Effect of high temperature on mechanical and acoustic emission properties of calcareous-aggregate concrete. Appl Therm Eng. 2016;106:1200–1208.
- Berra M, Carassiti F, Mangialardi T, et al. Effects of nanosilica addition on workability and compressive strength of Portland cement pastes. Constr Build Mater. 2012;35:666–675.
- Xi Y, Li J, Liu G, et al. A new numerical investigation of cement sheath integrity during multistage hydraulic fracturing shale gas wells. J Nat Gas Sci Eng. 2018;49:331–341.
- Cheng X, Sheng H, Guo X, et al. Crumb waste tire rubber surface modification by plasma polymerization of ethanol and its application on oil-well cement. Appl Surf Sci. 2017;409:325–342.
- Khan MZN, Hao Y, Hao H, et al. Experimental evaluation of quasi-static and dynamic compressive properties of ambient-cured high-strength plain and fiber reinforced geopolymer composites. Constr Build Mater. 2018;166:482–499.
- Liu P, Hu D, Wu Q, et al. Sensitivity and uncertainty analysis of interfacial effect in SHPB tests for concrete-like materials. Constr Build Mater. 2018;163:414–427.
- Ji-Chun MO, Yang LI. Instruments for cement stone dynamics properties and perforating channeling testing based on Hopkinon Spill Pressure Bar. Drilling Fluid Completion Fluid. 2004;21:10–13 (in Chinese).
- Wang X. A research on preventing and resisting the oil permeation in well cementation. Acta Petrolei Sinica. 1999;20:88–92.
- Bischoff PH, Perry SH. Compressive behaviour of concrete at high strain rates. Mater Struct. 1991;24:425–450.
- Liu H, Ma J, Wang Y, et al. Influence of desert sand on the mechanical properties of concrete subjected to impact loading. Acta Mech Solida Sin. 2017;30:583–595.
- Ren GM, Wu H, Fang Q, et al. Effects of steel fiber content and type on dynamic compressive mechanical properties of UHPCC. Constr Build Mater. 2018;164:29–43.
- Xie YJ, Fu Q, Zheng KR, et al. Dynamic mechanical properties of cement and asphalt mortar based on SHPB test. Constr Build Mater. 2014;70:217–225.
- ISO 10426-2, Petroleum and natural gas industries—Cements and materials for well cementing—Part 2: Testing of well cements.Thiercelin, M., Dargaud, B., Baret, J.F., and Rodriguez, W.J. 1998. Cement Design Based on Cement Mechanical Response. SPE Drilling and Completion, December 1998: 266–273.
- Simões T, Costa H, Dias-Da-Costa D, et al. Influence of fibres on the mechanical behaviour of fibre reinforced concrete matrixes. Constr Build Mater. 2017;137:548–556.
- Wang S, Le HTN, Poh LH, et al. Effect of high strain rate on compressive behavior of strain-hardening cement composite in comparison to that of ordinary fiber-reinforced concrete. Constr Build Mater. 2017;136:31–43.
- Guo YB, Gao GF, Jing L, et al. Response of high-strength concrete to dynamic compressive loading. Int J Impact Eng. 2017;108:114–135.
- Luo L, Li X, Tao M, et al. Mechanical behavior of rock-shotcrete interface under static and dynamic tensile loads. Tunn Undergr Sp Technol. 2017;65:215–224.
- Ulus H, T USN, Sahin OS, et al. Low-velocity impact behavior of carbon fiber/epoxy multiscale hybrid nanocomposites reinforced with multiwalled carbon nanotubes and boron nitride nanoplates. J Compos Mater. 2016;50:761-770.
- Fu Q, Niu D, Zhang J, et al. Dynamic compressive mechanical behaviour and modelling of basalt–polypropylene fibre-reinforced concrete. Arch Civil Mech Eng. 2018;18:914–927.
- Liu KQ, Cheng X, Zhang X, et al. Design of low-density cement optimized by cellulose-based fibre for oil and natural gas well. Powder Technol. 2018;338:506–518.
- Cheng X, Khorami M, Shi Y, et al. A new approach to improve mechanical properties and durability of low-density oil well cement composite reinforced by cellulose fibres in microstructural scale. Constr Build Mater. 2018;177:499–510.
- Feng J, Wang E, Chen X, et al. Energy dissipation rate: an indicator of coal deformation and failure under static and dynamic compressive loads. Int J Mining Sci Technol. 2017;28:397–406.
- Fu Jie, Yang D, Liu HF, et al. Influence of fly ash dosage and desert sand replacement ratio on the mechanical properties of high strength desert sand concrete. Sci Technol Eng. 2015;15:238–242.
- Lundberg B. A Split Hopkinson Bar study of energy absorption in dynamic rock fragmentation. Int J Rock Mech Min Sci Geomech. Abstr. 1976;13:187–197.
- Liu L, Katsabanis PD. Development of a continuum damage model for blasting analysis. Int J Rock Mech Min Sci. 1997;34:217–231.