Critical parameters of horizontal well influenced by semi-permeable barrier in bottom water reservoir

Ping Yue; Zhi-min Du; Xiao-fan Chen; Su-yang Zhu; Hu Jia

doi:10.1007/s11771-015-2662-z

Journal of Central South University ›› 2015, Vol. 22 ›› Issue (4) : 1448 -1455. DOI: 10.1007/s11771-015-2662-z

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Critical parameters of horizontal well influenced by semi-permeable barrier in bottom water reservoir

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Abstract

It is well-known that barriers have a significant impact on the production performance of horizontal wells developed in a bottom water drive reservoir. In most cases, reservoir barriers are semi-permeable. Based on previous research on impermeable reservoir barrier, a mathematical flow model was derived for a horizontal well of a bottom water drive reservoir with a semi-permeable barrier. Besides, analytical equations were also presented to calculate critical parameters, such as production rate, pressure and potential difference. The effects of barrier, well and reservoir parameters on our model results were further investigated. The results show that the larger the barrier size is or the higher the barrier location is, the higher the critical production rate and potential difference of a horizontal well are. When the barrier permeability equals the formation permeability or the barrier width equals zero, the critical production rates converge to the values same to that of the case with no barrier. When the barrier permeability equals zero, the problem is regarded as a case of impermeable barrier. This model can be applied to predicting horizontal wells’ critical production parameters in reservoirs with semi-permeable barriers.

Keywords

horizontal well / bottom water reservoir / semi-permeable barrier / critical rate / cresting

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Ping Yue, Zhi-min Du, Xiao-fan Chen, Su-yang Zhu, Hu Jia. Critical parameters of horizontal well influenced by semi-permeable barrier in bottom water reservoir. Journal of Central South University, 2015, 22(4): 1448-1455 DOI:10.1007/s11771-015-2662-z

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	MuskatM, WyckoffR DAn approximate theory of water coning in oil production [J], 1935, 114: 144-163

[2]	OkwanankeA, IsehunwaS O, AdeosunT A. Water cresting predictions in horizontal oil wells [J]. Advances in Sustainable Petroleum Engineering Science, 2012, 4(3): 109-124

[3]	ChaperonI. Theoretical study of coning toward horizontal and vertical wells in anisotropic formations: Subcritical and critical rates [C]. SPE Annual Technical Conference and Exhibition, 1986, New Orleans, Louisiana, SPE

[4]	GigerF M. Analytic two-dimensional models of water cresting before breakthrough for horizontal wells [J]. SPE Reservoir Engineering, 1989, 4(4): 409-416

[5]	AulieT, AsheimH, OudemanP. Experimental investigation of cresting and critical flow rate of horizontal wells [J]. SPE Advanced Technology Series, 1995, 3(1): 207-215

[6]	FanZ-f, LinZ-fang. A study of critical rate of a horizontal well in a reservoir with bottom-water drive [J]. Petroleum Exploration and Development, 1994, 21(1): 65-70. ^(in Chinese)

[7]	PermadiP, LeeR L, KartoatmodjoR. Behavior of water cresting under horizontal wells [C]. SPE Annual Technical Conference and Exhibition, 1995, Dallas, Texas, SPE

[8]	PermadiP, JayadiT. An improved water coning calculation for horizontal wells [C]. Oil and Gas Conf. and Exhibition, 2010, Moscow, SPE

[9]	LuoW-j, ZhouY-f, WangX-dong. A novel 3-D model for the water cresting in horizontal wells [J]. Journal of Hydrodynamics, 2008, 20(6): 749-755

[10]	OzkanE, RaghavanR. A breakthrough time correlation for coning toward horizontal wells [C]. European Conf. The Hague, 1990, Netherlands, SPE

[11]	PapatzacosP, HerringT M, MartinsenR, SkjaevelandS M. Cone breakthrough time for horizontal wells [J]. SPE Res & Eng, 1991, 6(3): 311-318

[12]	LiL-f, YueX-a, ZhaoH-l, YangZ-g, ZhangL-juan. A novel method for predicting breakthrough time of horizontal wells in bottom water reservoirs [J]. Journal of Central South University, 2013, 20(12): 3612-3619

[13]	ZhengQ, LiuH, LiF. Study on water breakthrough regularity and influencing factors of horizontal wells in a heterogeneous reservoir with bottom water [J]. Petroleum Science and Technology, 2013, 31(8): 803-811

[14]	BahadorI. A mathematical predictive tool for determining the time to water cone breakthrough in horizontal wells [J]. Petroleum Science and Technology, 2013, 31(20): 2047-2055

[15]	BahadoriA. Determination of well placement and breakthrough time in horizontal wells for homogeneous and anisotropic reservoirs [J]. Journal of Petroleum Science and Engineering, 2010, 75(1/2): 196-202

[16]	SmithC R, PirsonS J. Water coning control in oil wells by fluid injection [J]. SPE Journal, 1963, 3(4): 314-326

[17]	WojtanowiczA K, HuiX, ZakiB. Segregated production method for oil wells with active water coning [J]. Journal of Petroleum Science and Engineering, 1994, 11(1): 21-35

[18]	SiddiqiS S, WojtanowiczA K. A study of water coning control in oil wells by injected or natural flow barriers using scaled physical model and numerical simulator [C]. SPE Annual Technical Conference and Exhibition, 2002, San Antonio, Texas, SPE

[19]	Ould-amerY, ChikhS, NajiH. Attenuation of water coning using dual completion technology [J]. Journal of Petroleum Science and Engineering, 2004, 45(1/2): 109-122

[20]	JinL, OjtanowiczA K, HughesR G. An analytical model for water coning control installation in reservoir with bottom water [J]. Journal of Canadian Petroleum Technology, 2010, 49(5): 65-70

[21]	BekbauovB E, KaltayevA, WojtanowiczA K, PanfilovM. Numerical modeling of the effects of disproportionate permeability reduction water-shutoff treatments on water coning [J]. Journal of Energy Resources Technology, 2013, 135(3): 011101

[22]	YueP, ChenX-f, FengR-peng. Determine the reasonable production parameters in bottom aquifer oil reservoir [C]. The 5th Int Conf of State Key Laboratory of Oil and Gas Reservoir Geology and Exploitation. Chendu, China, 2009834-841

[23]	YuePingStudy on theories of horizontal well productivity prediction and formulas of critical parameters in bottom water reservoirs with horizontal well [D], 2010, Chengdu, China Southwest Petroleum University

[24]	YueP, DuZ-m, ChenX-f, LiangB-sheng. The critical rate of horizontal wells in bottom-water reservoirs with an impermeable barrier [J]. Petroleum Science, 2012, 9(2): 223-228

[25]	KarpJ C, LoweD K, MarusovN. Horizontal barriers for controlling water coning [J]. Journal of Petroleum Technology, 1962, 14(7): 783-790

[26]	StricklandR F. Artificial barriers may control water coning-1 [J]. Oil and Gas Journal, 1974, 10: 61-64

[27]	LiC-l, SongH-cai. Computation formula of critical production oil wells in reservoir with bottom water and confining bed [J]. Petroleum Geology & Oilfield Development of Daqing, China, 1993, 12(4): 43-46

[28]	HouJ-gen. Prediction of interbeds intercalated into complex heterogeneous reservoirs at a high water cut stage [J]. Petroleum Science, 2007, 4(3): 26-30

[29]	ZhangP, WenX-h, GeL-z, YangQ-h, LanL-c, ZhouD-g, LiaoX-w, ZhangF-l, MichealS W. Existence of flow barriers improves horizontal well production in bottom water reservoirs [C]. SPE Annual Technical Conference and Exhibition, 2008, Denver, Colorado, SPE

[30]	QinW, WojtanowiczA K, ChristopherD W. New cold production technique for heavy oil with strong bottom water drive [C]. SPE Annual Technical Conference and Exhibition, 2011, Denver, Colorado, USA, SPE

[31]	WyckoffR D, BotsetH G, MuskatM. The mechanics of porous flow applied to water-flooding problems [J]. Transactions of the AIME, 1933, 103(1): 219-249