Effect of hydrophilic silica nanoparticles on hydrate formation during methane gas migration in a simulated wellbore

Meng Xu , Xiangyu Fang , Fulong Ning , Wenjia Ou , Ling Zhang , Dongdong Wang

Petroleum ›› 2021, Vol. 7 ›› Issue (4) : 485 -495.

PDF
Petroleum ›› 2021, Vol. 7 ›› Issue (4) :485 -495. DOI: 10.1016/j.petlm.2021.11.004
research-article
Effect of hydrophilic silica nanoparticles on hydrate formation during methane gas migration in a simulated wellbore
Author information +
History +
PDF

Abstract

Natural gas hydrates are mostly formed in low-permeability and fractured muddy sedimentary formations. Adding suitable nanoparticles to the drilling fluid system can improve its filtrate resistance and fracture plugging, and effectively weaken the invasion of drilling fluid into the reservoir. However, it is likely that nanoparticles promote hydrate formation and accumulation in wellbores which will induce accidents. Therefore, this study investigated the effect of hydrophilic silica nanoparticles with particle sizes of 30 nm, 60 nm, and 80 nm and concentrations of 0.5-4.0 wt% on hydrate formation during upward migration of methane gas using a dynamic simulation system for hydrate formation in a wellbore. The experimental results show that under the condition of methane gas migration, hydrophilic silica nanoparticles inhibit hydrate formation. The inhibition effect increased with the growth in the particle size under a constant concentration, whereas it first increased and then decreased with increasing nanoparticle concentration under a constant particle size. The strongest inhibition effect was observed at a hydrophilic silica nanoparticle concentration of 2.0 wt%. The influence of hydrophilic silica nanoparticles on hydrate formation may be mainly determined by their hydrophilic properties, heat and mass transfer, and gas migration in the wellbore. Our research indicates that hydrophilic silica nanoparticles can be added to hydrate drilling fluid systems if their concentration can be properly controlled.

Keywords

Natural gas hydrate / Drilling fluid / Hydrophilic silica nanoparticles / Methane gas migration

Cite this article

Download citation ▾
Meng Xu, Xiangyu Fang, Fulong Ning, Wenjia Ou, Ling Zhang, Dongdong Wang. Effect of hydrophilic silica nanoparticles on hydrate formation during methane gas migration in a simulated wellbore. Petroleum, 2021, 7(4): 485-495 DOI:10.1016/j.petlm.2021.11.004

登录浏览全文

4963

注册一个新账户 忘记密码

Declaration of competing interest

The manuscript is approved by all authors for publication. We authors confirm that no conflict of interest exits in the submission of this manuscript. The original work has not been published previously and is not under consideration for publication elsewhere, in whole or in part.

Acknowledgements

This work was supported by the National Natural Science Foundation of China (Grant No. 41672367, 51704266, and 51874263) and was partly supported by the National Key Research and Development Program of China (No. 2018YFE0126400), and the Special Project for Marine Economic Development (Six Major Marine Industries) of Department of Natural Resources of Guangdong Province (GDNRC [2020]047), and the Fundamental Research Funds for National Universities, China University of Geosciences (Wuhan) (Grant No. CUGGC09).

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

E.D. Sloan, C. Koh, Clathrate Hydrates of Natural gases[M], CRC Press, 2007.
[2]

Jianzhong Li, Min Zheng, Xiaoming Chen, et al., Connotation analyses, sourcereservoir potential of unconventional assemblage types and development hydrocarbon in China[J], Acta Pet. Sin. 36 (5) (2015) 521-532.
[3]

H.P. Veluswamy, A. Kumar, R. Kumar, et al., An innovative approach to enhance methane hydrate formation kinetics with leucine for energy storage application[J], Appl. Energy 188 (2017) 190-199.
[4]

J. Javanmardi, M. Moshfeghian, Energy consumption and economic evaluation of water desalination by hydrate phenomenon[J], Appl. Therm. Eng. 23 (7) (2003) 845-857.
[5]

K.N. Park, Y.H. Sang, W.L. Jin, et al., A new apparatus for seawater desalination by gas hydrate process and removal characteristics of dissolved minerals (Na +, Mg 2+, Ca 2+, K +, B 3+ )[J], Desalination 274 (1) (2011) 91-96.
[6]

P. Linga, R. Kumar, D.L. Ju, et al., A new apparatus to enhance the rate of gas hydrate formation: application to capture of carbon dioxide[J], Int. J. Greenh. Gas. Control. 4 (4) (2010) 630-637.
[7]

Z.W. Ma, P. Zhang, H.S. Bao, et al., Review of fundamental properties of CO2, hydrates and CO2, capture and separation using hydration method[J], Renew. Sustain. Energy Rev. 53 (2016) 1273-1302.
[8]

Fulong Ning, Guosheng Jiang, Ling Zhang, et al., Analysis of key factors affecting borehole stability of NGH formation[J], Petrol. Drill. Tech. 36 (3) (2008) 59-61.
[9]

D.R. Mcconnell, Z. Zhang, R. Boswell, Review of progress in evaluating gas hydrate drilling hazards[J], Mar. Petrol. Geol. 34 (1) (2012) 209-223.
[10]

F. Ning, K. Zhang, N. Wu, et al., Invasion of drilling mud into gas-hydratebearing sediments. Part I: effect of drilling mud properties[J], Geophys. J. Int. 193 (3) (2013) 1370-1384.
[11]

F. Ning, N. Wu, Y. Yu, et al., Invasion of drilling mud into gas-hydrate-bearing sediments. Part II: effects of geophysical properties of sediments[J], Geophys. J. Int. 193 (3) (2013) 1385-1398.
[12]

J. Sun, F. Ning, N. Wu, et al., The effect of drilling mud properties on shallow lateral resistivity logging of gas hydrate bearing sediments[J], J. Petrol. Sci. Eng. 127 (2015) 259-269.
[13]

J. Cai, M.E. Chenevert, M.M. Sharma, et al., Decreasing water invasion into Atoka shale using nonmodified silica nanoparticles[J], SPE Drill. Complet. 27 (1) (2012) 103-112.
[14]

M. Zakaria, M.M. Husein, G. Harland, Novel Nanoparticle-Based Drilling Fluid with Improved Characteristics[M], Society of Petroleum Engineering, 2012.
[15]

Ye Yuan, Jihua Cai, Jijun Wang, et al., Experimental study on improving filtration properties of drilling fluid using silica nano-particles, Oil. Drill. Prod. Technol. 35 (3) (2013) 30-33.
[16]

H. Mao, Z. Qiu, Z. Shen, et al., Hydrophobic associated polymer based silica nanoparticles composite with coreeshell structure as a filtrate reducer for drilling fluid at utra-high temperature[J], J. Petrol. Sci. Eng. 129 (2015) 1-14.
[17]

Mina Luo, Jiawei Ai, C.H.E.N. Fu, et al., Evaluation of sealing characteristics of nano materials CQ-NZC in oil based drilling fluids[J], Chem. Ind. Eng. Prog. 34 (2015) 1395-1400, 05.
[18]

Lin Xu, Mingyi Deng, Yongjun Guo, et al., Research on application of nanoplugging agent in drilling fluid[J], Appl. Chem. Ind. 45 (4) (2016) 742-746.
[19]

J. Li, D. Liang, K. Guo, et al., Formation and dissociation of HFC134a gas hydrate in nano-copper suspension[J], Energy Convers. Manag. 47 (2) (2006) 201-210.
[20]

Jinping Li, Wu Jiang, Deqing Liang, et al., Experimental study on formation process of gas hydrate in nanofluids[J], J. Xi'an Jiaot. Univ. 40 (3) (2006) 365-368.
[21]

S.S. Park, E.J. An, S.B. Lee, et al., Characteristics of methane hydrate formation in carbon nanofluids[J], J. Ind. Eng. Chem. 18 (1) (2012) 443-448.
[22]

S. Arjang, M. Manteghian, A. Mohammadi, Effect of synthesized silver nanoparticles in promoting methane hydrate formation at 4.7MPa and 5.7MPa[J], Chem. Eng. Res. Des. 91 (6) (2013) 1050-1054.
[23]

A. Mohammadi, M. Manteghian, A. Haghtalab, et al., Kinetic study of carbon dioxide hydrate formation in presence of silver nanoparticles and SDS[J], Chem. Eng. J. 237 (2014) 387-395.
[24]

S.W. Lee, S.D. Park, S. Kang, et al., Investigation of viscosity and thermal conductivity of SiC nanofluids for heat transfer applications[J], Int. J. Heat Mass Tran. 54 (1) (2011) 433-438.
[25]

M.K. Moraveji, M. Golkaram, R. Davarnejad, et al., Biosynthesized silver nanofluid effect on methane dissolution in water[J], J. Mol. Liq. 184 (184) (2013) 1-3.
[26]

S. Zhou, Y. Yu, M. Zhao, et al., Effect of graphite nanoparticles on promoting CO2 hydrate formation[J], Energy Fuels 28 (7) (2014) 4694-4698.
[27]

M. Aliabadi, A. Rasoolzadeh, F. Esmaeilzadeh, et al., Experimental study of using CuO nanoparticles as a methane hydrate promoter[J], J. Nat. Gas Sci. Eng. 27 (2015) 1518-1522.
[28]

Liu Ni, Yanan Zhang, Xiuting Liu, et al., Experimental study on characteristics of CO2 hydrate formation in nanofluids[J], Journal of Refrigeration (2) (2015) 41-45.
[29]

A.N. Nesterov, A.M. Reshetnikov, A.Y. Manakov, et al., Promotion and inhibition of gas hydrate formation by oxide powders[J], J. Mol. Liq. 204 (Complete) (2015) 118-125.
[30]

Chari V D, Sharma D V, Prasad P S, et al. Methane hydrates formation and dissociation in nano silica suspension[J]. J. Nat. Gas Sci. Eng., 2103(11): 7-11.
[31]

F. Farhang, A.V. Nguyen, K.B. Sewell, A fundamental investigation of the effects of hydrophobic fumed silica on the formation of carbon dioxide gas hydrates[J], Energy Fuels 28 (11) (2014) 7025-7037.
[32]

Ren Wang, Effect of Nano-SiO2 and Hydrate Inhibitor on Hydrate Formation in Drilling fluid[D], China University of Geosciences, 2018.
[33]

Huicui Sun, Ren Wang, Xianguang Xu, et al., Effect of hydrophilic nano-SiO2 on CH4 hydrate formation[J], J. Univ. Pet., China (Ed. Nat. Sci.) 42 (3) (2018)
[34]

R. Wang, T. Liu, F. Ning, et al., Effect of hydrophilic silica nanoparticles on hydrate formation: insight from the experimental study[J], J. Energy Chem. 30 (2019) 98-108, 03.
[35]

B.X. Wu, H.Y. Lei, Y. Duan, et al., Experimental simulation on equilibrium temperature and pressure of methane hydrate in sediment systems[J], Petrol. Explor. Dev. 31 (4) (2004) 17-22.
[36]

V. Natarajan, P.R. Bishnoi, N. Kalogerakis, Induction phenomena in gas hydrate nucleation[J], Chem. Eng. Sci. 49 (13) (1994) 2075-2087.
[37]

D. Kashchiev, A. Firoozabadi, Nucleation of gas hydrates[J], J. Cryst. Growth 250 (3-4) (2002) 499-515.
[38]

P. Skovborg, H.J. Ng, P. Rasmussen, et al., Measurement of induction times for the formation of methane and ethane gas hydrates[J], Chem. Eng. Sci. 48 (3) (1993) 445-453.
[39]

Zhenhua Li, Lingmei Miao, Application of the compression factors of real gases[J], Shanghai. Chem. Inductry 39 (3) (2014) 7-10.
[40]

Hongsheng Han, Evaluation of calculation method of natural gas compression factor[J], Oil Gas Storage Transp. 13 (1) (1994) 13-18.
[41]

T.H. Ahmed, Hydrocarbon Phase behavior[M], Gulf Pub. Co., Huston, 1989.
[42]

Nasheda, Omar, Partoon, et al., Review the impact of nanoparticles on the thermodynamics and kinetics of gas hydrate formation[J], J. Nat. Gas Sci. Eng. 55 (2018) 452-465.
[43]

R.W. Hawtin, D. Quigley, P.M. Rodger, Gas hydrate nucleation and cage formation at a water/methane interface[J], Phys. Chem. Chem. Phys. 10 (32) (2008) 4853-4864.
[44]

J. Sato, T. Iida, F. Kiyono, et al., Cohesion force measurement of methane hydrate and numerical simulation of rising bubbles covered with a hydrate membrane within a contracting pipe[J], Energy Fuels 30 (9) (2016) 7100-7107.
[45]

Z.M. Aman, E.P. Brown, E.D. Sloan, et al., Interfacial mechanisms governing cyclopentane clathrate hydrate adhesion/cohesion[J], Phys. Chem. Chem. Phys. 13 (44) (2011) 19796-19806.
[46]

C.J. Taylor, L.E. Dieker, K.T. Miller, et al., Micromechanical adhesion force measurements between tetrahydrofuran hydrate particles[J], J. Colloid Interface Sci. 306 (2) (2008) 255-261.
[47]

Dongdong Guo, Fulong Ning, Wenjia Ou, et al., Research progress of nanoparticles and hydrate formation[J], Bull. Geol. Sci. Technol. 38 (6) (2019) 96-112.
[48]

H. Shokohmand, M. Kazemi, A.R. Sajadi, Investigation of turbulent convective heat transfer of TiO2/water nanofluid in circular tube, Int. Commun. Heat Mass Tran. 38 (10) (2011) 1474-1478.
[49]

N.N. Nguyen, A.V. Nguyen, K.M. Steel, et al., Interfacial gas enrichment at hydrophobic surfaces and the origin of promotion of gas hydrate formation by hydrophobic solid particles[J], J. Phys. Chem. C 121 (7) (2017) 3830-3840.
PDF

0

Accesses

0

Citation

Detail
Sections
Recommended

/