高密度钻井液加重材料沉降问题研究进展

潘谊党; 于培志; 马京缘

doi:10.3969/j.issn.1001-5620.2019.01.001

高密度钻井液加重材料沉降问题研究进展

doi: 10.3969/j.issn.1001-5620.2019.01.001

中国地质大学(北京)工程技术学院, 北京 100083

基金项目:

国家自然科学基金面上项目“绳索取心钻杆内壁结垢机理与控制方法”（J218076）

详细信息

作者简介:
潘谊党,1993年生,中国地质大学(北京)地质工程专业硕士研究生(2017级),研究方向钻井工程。电话15510533606;E-mail:575928874@qq.com

通讯作者:
于培志,E-mail:yupz@cugb.edu.cn

中图分类号: TE254.3
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出版历程
- 收稿日期: 2018-11-12
- 刊出日期: 2019-02-28

Progresses in Research on Settling of Weighting Materials in High Density Drilling Fluids

School of Engineering and Technology, China University of Geosciences(Beijing), Beijing 100083

摘要

摘要: 钻井液的密度对于地层的压力控制至关重要，而流变性和沉降稳定性控制是高密度钻井液技术存在的主要技术难点之一。传统的加重材料，例如API重晶石在高密度钻井液中存在严重的沉降问题，对钻完井作业造成严重影响。不同粒径、形貌和比重的加重材料对改善高密度钻井液的流变性和沉降稳定性有不同的作用。综述了对API重晶石沉降问题的研究现状以及作为替代API重晶石的微粉加重材料的研究进展。国内外的室内研究与现场应用表明，高密度的微粉加重材料可有效解决高密度钻井液的沉降稳定性问题，并且具有降低摩阻、当量循环密度等优点。但是，微粉加重材料也存在固相控制、泥饼清除困难，微粉颗粒团聚的缺点，研究学者针对这些问题已展开大量研究，并提出相应解决办法。
- 高密度钻井液 /
- 加重材料 /
- 沉降稳定性 /
- 重晶石 /
- 微锰
Abstract: The density of drilling fluid plays a key role in controlling formation pressures, and the rheology and the settling stability of a high density drilling fluid, are technical difficulties always encountered in field drilling operations. Conventional weighting materials, such as API barites, tend to settle readily in high density drilling fluids, imposing serious negative effects on drilling/completion operations. Weighting materials of different particle sizes, morphology and densities play different roles in improving the rheology and settling stability of a drilling fluid. This paper summarizes the status quo of research work done to the settling of API barites and the progresses made in searching for micro powder weighting materials to replace API barites as drilling fluid weighing additives. Laboratory studies and field application both in China and abroad have demonstrated that micro powder weighting materials of high density are able to be used to address the settling stability problems associated with high density drilling fluids. These micro powder high density weighting materials also have the advantages of reducing friction and equivalent circulating density of drilling fluids. Problems associated with the use of micro powder weighting materials include difficulties in solids control and mud cake removal, and the glomeration of the micro particles of the weighting materials, which are now being addressed by many researchers all over the world.
- High density drilling fluid /
- Weighting material /
- Settling stability /
- Barite /
- Micro manganese oxides

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参考文献(61)

[1]	OMLAND T H, A SAASEN, C VAN DER ZWAAG, et al. The effect of weighting material sag on drilling operation efficiency[C]. SPE 110537, 2007.
[2]	AMIGHI M, K SHAHBAZI. Effective ways to avoid barite sag and technologies to predict sag in HPHT and deviated wells[C]. SPE 132015, 2010.
[3]	ZAMORA M. Mechanisms, Measurement and mitigation of barite sag, in offshore mediterranean conference and exhibition[C]//Offshore Mediterranean Conference:Ravenna, Italy, 2009:14.
[4]	BERN P A, M ZAMORA, K S SLATER, et al, The influence of drilling variables on barite sag, in spe annual technical conference and exhibition[R]. SPE 36670-MS, 1996.
[5]	AMIGHI M R, K SHAHBAZI. The best common ways to manage barite sag in HPHT and deviated operations with a case study in the Iran oil industry[J]. Petroleum Science and Technology, 2011, 29(17):1864-1872.
[6]	FATTAH K A, A LASHIN. Investigation of mud density and weighting materials effect on drilling fluid filter cake properties and formation damage[J]. Journal of African Earth Sciences, 2016, 117:345-357.
[7]	BU H C, WANG J. SUN, et al. Influence and mechanism for the particle size of weighting material on the rheological properties of high-density drilling fluids[C]//International Maritime Commission Meeting,2012.
[8]	BYBEE K. Barite-sag management[J]. Journal of Petroleum Technology, 2004, 56(11):62-63.
[9]	NGUYEN T, S MISKA, M YU, et al. Predicting dynamic barite sag in newtonian-oil based drilling fluids in pipe[J]. Journal of Energy Resources Technology, 2011, 133(2):023102-023102-10.
[10]	RIBEIRO J M, F M ELER, A L MARTINS, et al. A simplified model applied to the barite sag and fluid flow in drilling muds:simulation and experimental results[J]. Oil & Gas Science & Technology, 2017. 72(4):23.
[11]	HASHEMIAN Y, S MISKA, M YU, et al, Experimental study and modelling of barite sag in annular flow[J].Journal of Canadian Petroleum Technology, 2014, 53(6):365-374.
[12]	MURPHY, R J, D E JAMISON, T HEMPHILL, et al. Measuring and predicting dynamic sag[J]. SPE Drilling & Completion, 2008, 23(2):142-149.
[13]	OMLAND T H, H HODNE, A SAASEN, et al. OGJ FOCUS rig-site equipment determines drilling fluid weight material sag[J]. Oil & Gas Journal, 2010, 108(1):39-45.
[14]	DYE W, T HEMPHILL, W GUSLER, et al. Correlation of ultralow-shear-rate viscosity and dynamic barite sag[J]. SPE Drilling & Completion, 2001, 16(1):27-34.
[15]	Bern, P.A., E. van Oort, B. Neustadt, et al.Measurement, modeling, and management[J]. SPE Drilling & Completion, 2000. 15(1):p. 25-30.
[16]	NGUYEN T, S MISKA, M YU, et al. Experimental study of dynamic barite sag in oil-based drilling fluids using a modified rotational viscometer and a flow loop[J]. Journal of Petroleum Science and Engineering, 2011, 78(1):160-165.
[17]	ELKATATNY S. Enhancing the stability of invert emulsion drilling fluid for drilling in high-pressure hightemperature conditions[J]. Energies, 2018,11(9).
[18]	BASFAR S, S ELKATATNY, M MAHMOUD, et al. Prevention of barite sagging while drilling high-pressure high-temperature (HPHT) wells[C]. SPE 192198, 2018.
[19]	NADERI A, K SHAHBAZI. The effect of weight material type on barite sag tendency[J]. Petroleum Science and Technology, 2014. 32(1):84-90.
[20]	XU P, M XU, Z TAO, et al. Rheological properties and damage-control mechanism of oil-based drilling fluid with different types of weighting agents[J]. Royal Society open science, 2018,5(7):180358-180358.
[21]	张晖, 蒋绍宾, 袁学芳, 等. 微锰加重剂在钻井液中的应用[J]. 钻井液与完井液,2018. 35(1):1-7. ZHANG Hui,JIANG Shaobin,YUAN Xuefang,et al. Application of manganese tetraoxide weighting agent in drilling fluid[J].Drilling Fluid & Completion Fluid,2018, 35(1):1-7.
[22]	YE Y, W H AN, D YIN, et al. Application of ultrafine weighting materials in high-density oil-based drilling fluid technology[J]. Materials Science Forum, 2015, 814:338-344.
[23]	RANDOLPH S B, WALKER S H, YOUNG G A, et al. Use of a unique weighting agent for slimhole drilling[C]. SPE 24595, 1992.
[24]	MAHROUS R, B P MONTOTO, M SOBRINHO, et al. A significant mwd tool signal strength improvement:another advantage of using a treated micronized barite drilling fluid system[C]. SPE 159748, 2012.
[25]	QUERCIA G, R BELISARIO, R RENGIFO. Reduction of erosion rate by particle size distribution (PSD) modification of hematite as weighting agent for oil based drilling fluids[J]. Wear, 2009, 266(11):1229-1236.
[26]	MOHAMED B, EBRAHIM A. Investigations of Alternative Substitute to Barite as Drilling Weighting Material[M]//MASTORAKIS N, MLADENOV V, DEMIRALP M, et al. Advances in biology, bioengineering and environment. World Scientific and Engineering Acad and Soc., 2010:114-118.
[27]	BLOMBERG N E, B MELBERG. Evaluation of ilmenite as weight material in drilling fluids[J]. Journal of Petroleum Technology, 1984, 36(6):969-974.
[28]	AL-BAGOURY M. Micronized ilmenite-a nondamaging non-sagging new weight material for drilling fluids[C]. SPE 169182, 2014.
[29]	AL-BAGOURY M, C D STEELE. A new alternative weight material for drilling fluids[C]. SPE 151331, 2012.
[30]	ELKATATNY S M, H A NASR-EL-DIN, M ALBAGOURY. Properties of ilmenite water-based drilling fluids for HPHT applications[C]. SPE 16983, 2013.
[31]	ELKATATNY S M. Evaluation of ilmenite as weighting material in water-based drilling fluids for HPHT applications[C]. SPE 163377, 2012.
[32]	AL-YAMI A S, H A NASR-EL-DIN. An innovative manganese tetroxide/kcl water-based drill-in fluid for HT/HP wells[C]. SPE 110638, 2007.
[33]	AL-YAMI A S, H A NASR-EL-DIN, M A AL-SHAFEI, et al. Impact of water-based drill-in fluids on solids invasion and damage characteristics[C]. SPE 117162, 2008.
[34]	AL-YAMI A S, H A NASR-EL-DIN, M A BATAWEEL, et al. Formation damage induced by various water-based fluids used to drill HP/HT wells[C]. SPE 112421, 2008.
[35]	STEELE C, W L HART, D OAKLEY. Microfine particles-an alternative to heavy brines[C]//Offshore Mediterranean Conference and Exhibition, Offshore Mediterranean Conference:Ravenna, Italy, 2007.
[36]	WAGLE V, A S AL-YAMI, Z ALABDULLATIF, et al. Mitigation of stuck pipe challenges in hthp conditions using acid soluble blend of barite and manganese tetroxide as weighting materials for drilling fluids[C]. SPE 175844, 2015.
[37]	ALABDULLATIF Z A, A S AL-YAMI, V B WAGLE, et al. Development of new kill fluids with minimum sagging problems for high pressure jilh formation in saudi arabia[C]. SPE 171683, 2014.
[38]	FIMREITE G, A ASKO, J MASSAM, et al. Invert emulsion fluids for drilling through narrow hydraulic windows[C]. SPE 87128, 2004.
[39]	BOLIVAR N, S F DEAR, J B YOUNG, et al. Field result of equivalent circulating density reduction with a lowrheology fluid[C]. SPE 105487, 2007.
[40]	JAMES R W, O I PREBENSEN, O RANDEBERG. Reducing risk by using a unique oil-based drilling fluid in an offshore casing directional drilling operation[C]. SPE 112529, 2008.
[41]	Gregoire M R, M H Hodder, S Peng, et al. Successful Drilling of a Deviated, Ultra-HTHP Well Using a Micronised Barite Fluid[C]. SPE 119567, 2009.
[42]	Muller W, M Karad. Use of Ultra-Fine Barite for Horizontal Sections Presented by the Example of the Well Mittelplate MP A19a[J]. Oil Gas-European Magazine, 2009, 35(3):117-120.
[43]	Gadalla A, R Pino, P Ezi, et al. High Density Fluids Customization and Field Application in Khursaniyah Challenging Wells[C]. SPE 183997, 2017.
[44]	SVENDSEN O, J K TOFTEN, D S MARSHALL, et al. Use of a novel drill-in/completion fluid based on potassium formate brine on the first open hole completion in the gullfaks field[C]. SPE 29409, 1995.
[45]	FRANKS T, D S MARSHALL. Novel drilling fluid for through-tubing rotary drilling[C]. SPE 87127, 2004.
[46]	BYBEE K. Manganese tetraoxide weighted invert emulsions as completion fluids[J]. Journal of Petroleum Technology, 2008, 60(11):81-82.
[47]	CARBAJAL D L, C N BURRESS, W SHUMWAY, et al. Combining proven anti-sag technologies for hpht north sea applications:clay-free oil-based fluid and synthetic, sub-micron weight material[C]. SPE 119378, 2009.
[48]	AL-SAEEDI M J, B AL-KHAYAT, D R AL ENEZI, et al. Successful HPHT application of potassium formate/manganese tetra-oxide fluid helps improve drilling characteristics and imaging log quality[C]. SPE 132151, 2010.
[49]	ZHOU S M, G S LI, Q C WANG. Research and preparation of ultra-heavy slurry[J]. Petroleum Exploration and Development, 2013. 40(1):115-118.
[50]	MASSAM J, S K STOCKS, D OAKLEY, et al. How effective is current solids control equipment for drilling fluids weighted with micron sized weight material?[C]. SPE 112620, 2008.
[51]	AL MOAJIL A M, H A NASR-EL-DIN, A S AL-YAMI, et al. Removal of filter cake formed by manganese tetraoxide-based drilling fluids[C]. SPE 112450, 2008.
[52]	VAN NETTEN, K J ZHOU, K P GALVIN, et al. Influence of magnetic and hydrodynamic forces on chain-aggregation and motion of magnetisable particles and composites[J]. Chemical Engineering Science, 2013, 93:229-237.
[53]	KOVALCHUK N M, V M STAROV. Aggregation in colloidal suspensions:Effect of colloidal forces and hydrodynamic interactions[J]. Advances in Colloid and Interface Science, 2012, 179-182:99-106.
[54]	AL MOAJIL A M, A I RABIE, H A NASR-EL-DIN, et al. Effective dispersants for mn3o4 water-based drilling fluids:Influence of Clay and Salt[C]//Offshore Technology Conference Asia, Offshore Technology Conference:Kuala Lumpur, Malaysia, 2016:18.
[55]	AL MOAJIL A M, H A NASR-EL-DIN, Y KAR, et al. Dispersants for cement and salt contaminated manganese tetraoxide high-density water-based drilling fluids[C]. SPE 177935, 2015.
[56]	KAR Y, A M AL-MOAJIL, H A NASR-EL-DIN, et al. Environmentally friendly dispersants for HP/HT aqueous drilling fluids containing Mn₃O₄, contaminated with cement, rock salt and clay[C]. SPE 141957, 2011.
[57]	REHMAN A, A M AL MOAJIL, H A NASR-EL-DIN, et al. Environmentally acceptable friendly dispersants for high temperature invert-emulsion drilling fluids weighted by manganese tetraoxide[C]. SPE 153646, 2012.
[58]	CHERN G, L HORNG, M Z LIN, et al. Structural and magnetic characterization of Fe₃O₄/Mn₃O₄ superlattices[J]. Journal of Magnetism & Magnetic Materials, 2000, 209(1):138-141.
[59]	AL MOAJIL A M, H A NASR-EL-DIN. Formation damage caused by improper Mn₃O₄-based filter-cakecleanup treatments[J]. Journal of Canadian Petroleum Technology, 2013,52(1):64-74.
[60]	AL MOAJIL A M, H A NASR-EL-DIN. Removal of manganese tetraoxide filter cake using a combination of HCl and organic acid[J]. Journal of Canadian Petroleum Technology, 2014,53(2):122-130.
[61]	ELKATATNY S, A M AL MOAJIL, H A NASR-EL-DIN. Evaluation of a new environmentally friendly treatment to remove Mn₃O₄ filter cake[C]. SPE 156451, 2012.

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高密度钻井液加重材料沉降问题研究进展

doi: 10.3969/j.issn.1001-5620.2019.01.001

作者简介:
潘谊党,1993年生,中国地质大学(北京)地质工程专业硕士研究生(2017级),研究方向钻井工程。电话15510533606;E-mail:575928874@qq.com

通讯作者:
于培志,E-mail:yupz@cugb.edu.cn

计量

Progresses in Research on Settling of Weighting Materials in High Density Drilling Fluids

计量

目录

留言板

高密度钻井液加重材料沉降问题研究进展

doi: 10.3969/j.issn.1001-5620.2019.01.001

作者简介: 潘谊党,1993年生,中国地质大学(北京)地质工程专业硕士研究生(2017级),研究方向钻井工程。电话15510533606;E-mail:575928874@qq.com

通讯作者: 于培志,E-mail:yupz@cugb.edu.cn

计量

出版历程

Progresses in Research on Settling of Weighting Materials in High Density Drilling Fluids

计量

出版历程

目录

作者简介:
潘谊党,1993年生,中国地质大学(北京)地质工程专业硕士研究生(2017级),研究方向钻井工程。电话15510533606;E-mail:575928874@qq.com

通讯作者:
于培志,E-mail:yupz@cugb.edu.cn