2018年 第4卷 第3期
《工程(英文)》 >> 2018年 第4卷 第3期 doi: 10.1016/j.eng.2018.05.017
天然气水合物浆液流变学研究综述
a Center for Hydrate Research, Chemical and Biological Engineering, Colorado School of Mines, Golden, CO 80401, USA
b Faculty of Chemical and Natural Resources Engineering, Universiti Malaysia Pahang, Pekan 26600, Malaysia
c Department of Chemistry, Colorado School of Mines, Golden, CO 80401, USA
下一篇 上一篇
摘要
天然气水合物是固体包裹化合物,由三维的氢键网络组成,可以用来捕获气体小分子,比如甲烷和二氧化碳。了解溶液中天然气水合物晶体的流变性能对于许多能源方面的应用至关重要,包括天然气在海底和陆地上的运输,以及气体分离、脱盐或封存等方面的技术应用。人们已经对水合物浆体流变学进行了多次实验和模型模拟;然而,理论与实验之间的联系并不明确。本文讲述了对高、低压流变仪的研究以及在高压流动环境下,一系列不同的过冷度(ΔTsub = Tequil – Texp)和流体条件的水合物浆体黏度测量技术的现状(包括水和油的连续系统)。本文介绍了天然气水合物泥浆相对黏度的理论模型,还讨论了实验和理论之间的联系。
图片
图1
图2
图3
图4
图5
图6
图7
图8
参考文献
[ 1 ] Sloan ED, Koh CA. Clathrate hydrates of natural gases. 3rd ed. Boca Raton: CRC Press; 2007. 链接1
[ 2 ] Majid AAA, Lee W, Srivastava V, Chen L, Warrier P, Grasso GA, et al. Experimental investigation of gas-hydrate formation and particle transportability in fully and partially dispersed multiphase-flow systems using a high-pressure flow loop. SPE J 2017; pre-print. 链接1
[ 3 ] Gilmer MW. Hydrates on suspended bubbles: development of a high pressure counter-flow system and initial measurements [dissertation]. Golden: Colorado School of Mines; 2013. 链接1
[ 4 ] Zylyftari G, Lee JW, Morris JF. Salt effects on thermodynamic and rheological properties of hydrate forming emulsions. Chem Eng Sci 2013;95:148–60. 链接1
[ 5 ] Peixinho J, Karanjkar PU, Lee JW, Morris JF. Rheology of hydrate forming emulsions. Langmuir 2010;26(14):11699–704. 链接1
[ 6 ] Karanjkar PU, Ahuja A, Zylyftari G, Lee JW, Morris JF. Rheology of cyclopentane hydrate slurry in a model oil-continuous emulsion. Rheol Acta 2016;55(3): 235–43. 链接1
[ 7 ] Karanjkar PU. Evolving morphology and rheological properties of an emulsion undergoing clathrate hydrate formation [dissertation]. New York: City College of the City University of New York; 2012. 链接1
[ 8 ] Zylyftari G. Hydrate forming emulsion: a rheological, thermodynamic and morphological study [dissertation]. New York: City College of the City University of New York; 2014. 链接1
[ 9 ] Leopércio BC, de Souza Mendes PR, Fuller GG. Growth kinetics and mechanics of hydrate films by interfacial rheology. Langmuir 2016;32(17):4203–9. 链接1
[10] Webb RB, Koh CA, Liberatore MW. High pressure rheology of hydrate slurries formed from water-in-mineral oil emulsions. Ind Eng Chem Res 2014;53(17):6998–7007. 链接1
[11] Webb EB, Rensing PJ, Koh CA, Sloan ED, Sum AK, Liberatore MW. High-pressure rheology of hydrate slurries formed from water-in-oil emulsions. Energy Fuel 2012;26(6):3504–9. 链接1
[12] Webb EB, Koh CA, Liberatore MW. Rheological properties of methane hydrate slurries formed from AOT + water + oil microemulsions. Langmuir 2013;29(35):10997–1004. 链接1
[13] Sinquin A, Palermo T, Peysson Y. Rheological and flow properties of gas hydrate suspensions. Oil Gas Sci Technol 2004;59(1):41–57. 链接1
[14] Clain P, Delahaye A, Fournaison L, Mayoufi N, Dalmazzone D, Fürst W. Rheological properties of tetra-n-butylphosphonium bromide hydrate slurry flow. Chem Eng J 2012;193–194:112–22. 链接1
[15] Darbouret M, Cournil M, Herri JM. Rheological study of TBAB hydrate slurries as secondary two-phase refrigerants. Int J Refrig 2005;28(5):663–71. 链接1
[16] Delahaye A, Fournaison L, Marinhas S, Martínez MC. Rheological study of CO2 hydrate slurry in a dynamic loop applied to secondary refrigeration. Chem Eng Sci 2008;63(13):3551–9. 链接1
[17] Gaillard C, Monfort JP, Peytavy JL. Investigation of methane hydrate formation in a recirculating flow loop: modeling of the kinetics and tests of efficiency of chemical additives on hydrate inhibition. Oil Gas Sci Technol Rev IFP 1999;54(3):365–74. 链接1
[18] Lv X, Shi B, Wang Y, Gong J. Study on gas hydrate formation and hydrate slurry flow in a multiphase transportation system. Energ Fuel 2013;27(12): 7294–302. 链接1
[19] Camargo R, Palermo T. Rheological properties of hydrate suspensions in an asphaltenic crude oil. In: Proceedings of the 4th International Conference on Gas Hydrates; 2002 May 19–23; Yokohama, Japan; 2002. p. 19–23. 链接1
[20] Qin Y, Aman ZM, Pickering PF, Johns ML, May EF. High pressure rheological measurements of gas hydrate-in-oil slurries. J Non-Newton Fluid Mech 2017;248:40–9. 链接1
[21] Jeffrey DJ, Acrivos A. The rheological properties of suspensions of rigid particles. AIChE J 1976;22(3):417–32. 链接1
[22] Mcgeary RK. Mechanical packing of spherical particles. J Am Ceram Soc 1961;44(10):513–22. 链接1
[23] Majid AAA, Wu DT, Koh CA. New in situ measurements of the viscosity of gasclathrate hydrate slurries formed from model water-in-oil emulsions. Langmuir 2017;33(42):11436–45. 链接1
[24] Rutgers IR. Relative viscosity and concentration. Rheol Acta 1962;2(4):305–48. 链接1
[25] Rutgers IR. Relative viscosity of suspensions of rigid spheres in Newtonian liquids. Rheol Acta 1962;2(3):202–10. 链接1
[26] Mueller S, Llewellin EW, Mader HM. The rheology of suspensions of solid particles. Proc R Soc A Math Phys Eng Sci 2010;466(2116):1201–28. 链接1
[27] Mooney M. The viscosity of a concentrated suspension of spherical particles. J Colloid Sci 1951;6(2):162–70. 链接1
[28] Andersson V, Gudmundsson JS. Flow properties of hydrate-in-water slurries. Ann N Y Acad Sci 2000;912(1):322–9. 链接1
[29] Cameirao A, Fezoua A, Ouabbas Y, Herri J, Darbouret M, Sinquin A, et al. Agglomeration of gas hydrate in a water-in-oil emulsion. In: Proceedings of the 7th International Conference on Gas Hydrates; 2011 Jul 17–21; Edimbourg, UK; 2011. 链接1
[30] Darbouret M, Cournil M, Herri JM. Rheological study of a hydrate slurry for air conditioning application. In: Proceedings of the 5th International Conference on Gas Hydrates; 2005 Jun 13–16; Trondheim, Norway; 2005. 链接1
[31] Fidel-Dufour A, Gruy F, Herri J. Rheology of methane hydrate slurries during their crystallization in a water in dodecane emulsion under flowing. Chem Eng Sci 2006;61(2):505–15. 链接1
[32] Gainville M, Darbouret M, Sinquin A. Hydrate slurry characterisation for laminar and turbulent flows in pipelines. In: Proceedings of the 7th International Conference on Gas Hydrates; 2011 Jul 17–21; Edimbourg, UK; 2011. 链接1
[33] Hashimoto S, Kawamura K, Ito H, Ohgaki K, Inoue Y, Nobeoka M. Rheological study on tetra-n-butyl ammonium salt semi-clathrate hydrate slurries. In: Proceedings of the 7th International Conference on Gas Hydrates; 2011 Jul 17– 21; Edimbourg, UK; 2011.
[34] Jerbi S, Delahaye A, Oignet J, Fournaison L, Haberschill P. Rheological properties of CO2 hydrate slurry produced in a stirred tank reactor and a secondary refrigeration loop. Int J Refrig 2013;36(4):1294–301. 链接1
[35] Ma Z, Zhang P, Wang RZ, Furui S, Xi GN. Forced flow and convective melting heat transfer of clathrate hydrate slurry in tubes. Int J Heat Mass Transfer 2010;53(19–20):3745–57. 链接1
[36] Peng B, Chen J, Sun CY, Dandekar A, Guo S, Liu B, et al. Flow characteristics and morphology of hydrate slurry formed from (natural gas + diesel oil/condensate oil + water) system containing anti-agglomerant. Chem Eng Sci 2012;84: 333–44. 链接1
[37] Rensing PJ, Liberatore MW, Sum AK, Koh C, Dendy Sloan E. Viscosity and yield stresses of ice slurries formed in water-in-oil emulsions. J Non-Newton Fluid Mech 2011;166(14–15):859–66. 链接1
[38] Vijayamohan P, Majid A, Chaudhari P, Sloan E, Sum A, Koh C, et al. Hydrate modeling and flow loop experiments for water continuous and partially dispersed systems. In: Proceedings of Offshore Technology Conference 2014; 2014 May 5–8; Houston, TX, USA; 2014. 链接1
[39] Vijayamohan P, Majid A, Chaudhari P, Sum AK, Dellacase E, Volk M, et al. Selected projects progress: understanding gas hydrate growth in partially dispersed and water continuous systems from flowloop tests. In: Proceedings of Offshore Technology Conference 2015; 2015 May 4–7: Houston, TX, USA; 2015.
[40] Boxall JA, Koh CA, Sloan ED, Sum AK, Wu DT. Droplet size scaling of water-in- oil emulsions under turbulent flow. Langmuir 2012;28(1):104–10. 链接1
京公网安备 11010502051620号
