水层多角度裂缝介质中子测井响应数值模拟

doi:10.11720/wtyht.2018.0086

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Abstract

In geophysical exploration,crack medium is an important potential reservoir medium,and because of its complex structure and characteristics,the detection difficulty of crack medium is always great.For the purpose of identifying and studying the crack medium,it is necessary to conduct exploration and research through geophysical neutron logging method.In this paper,the authors applied the theory of dispersed multi-angle cracks to simulating the water layer strata in the pore-crack medium.The corresponding neutron log data were studied by changing crack parameters.The results of the study show that,in the low and medium angle crack environment,the maximum thermal neutron density is larger than that of approximate horizontal angle crack medium,and its sensitivity is significantly greater than that of other kinds crack environment,and that,in the high angle crack medium,the thermal neutron density map is smooth,indicating that the high angle crack medium has little effect on thermal neutron absorption.In the thermal neutron density distribution plan,the thermal neutron diffusion range is small because of the high hydrogen content in water.By analyzing the water layer thermal neutron density distribution,the maximum density distribution and the maximum time spectrum,the authors found that the neutron in the water layer is more sensitive to low and medium angle crack media,and is easy to be slowed down and absorbed.These results can provide theoretical guidance for geophysical survey work in the field.

Key words： crack neutron logging multi-angle crack theory numerical simulation water layer

Received: 08 March 2018 Published: 19 December 2018

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	Articles by authors
	Xue-Ang ZHANG
	Zhi-Chao YANG
	Xiong WEI

Cite this article:

Xue-Ang ZHANG,Zhi-Chao YANG,Xiong WEI. Water layer neutron logging in multi-angle crack environment[J]. Geophysical and Geochemical Exploration, 2018, 42(6): 1221-1227.

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https://www.wutanyuhuatan.com/EN/10.11720/wtyht.2018.0086 OR https://www.wutanyuhuatan.com/EN/Y2018/V42/I6/1221

[1]	Hudson J A . Overall properties of a cracked solid[J]. Mathematical Proceedings of the Cambridge Philosophical Society, 1980,88(2):371-384.
[2]	Hudson J A . Wave speeds and attenuation of elastic waves in material containing cracks[J]. Geophysical Journal International, 1981,64(1):133-150.
[3]	Hudson J A . Attenuation due to second-order scattering in material containing cracks[J]. Geophysical Journal International, 1990,102(2):485-490.
[4]	Hudson J A . Overall properties of heterogeneous material[J]. Geophysical Journal International, 1991,107(3):505-511.
[5]	Hudson J A, Liu E, Crampin S . The Mechanical properties of materials with interconnected cracks and pores[J]. Geophysical Journal International, 1996,124(1):105-112.
[6]	Hudson J A, Pointer T, Liu E . Effective-medium theories for fluid-saturated materials with aligned cracks[J]. Geophysical Prospecting, 2001,49(5):509-522.
[7]	Zhao Y, Yao G Q, Mu L H , et al. Characteristics and controlling factors of fractures in lacustrine dolostones reservoirs in Tanggu district[J]. Earth Science, 2016,41(2):252-264.
[8]	Germán R J, Quintal B M, Tobias M , et al. Energy dissipation of P and S-waves in fluid-saturated rocks:An overview focusing on hydraulically connected fractures[J]. Journal of Earth Science, 2015,26(6):785-790.
[9]	张福宏, 黄平, 黄开伟 , 等. 复杂裂缝地球物理模型制作及地震采集处理研究[J]. 物探与化探, 2018,42(1):87-95.
[10]	姜黎明, 余春昊, 齐宝权 , 等. 孔洞型碳酸盐岩储层饱和度建模新方法及应用[J]. 天然气地球科学, 2017,28(8):1250-1256.
[11]	Hall S A, Kendall J M, Maddock J , et al. Crack density tensor inversion for analysis of changes in rock frame architecture[J]. Geophysical Journal International, 2008,173(2):577-592.
[12]	俞岱, 孙渊, 路婧 , 等. 浅层初至波旅行时层析并行算法及在地裂缝调查中的应用[J]. 物探与化探, 2017,41(5):977-985.
[13]	Nandal J S, Saini T N . Reflection and refraction at an imperfectly bonded interface between poroelastic solid and cracked elastic solid[J]. Journal of Seismology, 2012,17(2):239-253.
[14]	全红娟, 朱光明, 潘渊 , 等. 勘探地震物理震源模拟分析[J]. 物探与化探, 2017,41(2):341-346.
[15]	薛娇, 顾汉明, 崔成国 , 等. 基于等效介质模型的裂缝参数AVOA反演[J]. 石油地球物理勘探, 2016,51(6):1171-1179.
[16]	Jennings R L, Weber G A . Towards fast quantitative modelling of pulsed neutron logging tools [C]//SPWLA 36 ^th Annual Logging Symposium , 1995.
[17]	Fricke S, David P, Adolph B , et al. Thermal neutron porosity using pulsed neutron measurement [C]//SPWLA 49 ^th Annual Logging Symposium , 2008.
[18]	张锋, 王新光 . 脉冲中子—中子测井影响因素的数值模拟[J]. 中国石油大学学报:自然科学版, 2009,6:46-51.
[19]	张锋, 孙燕 . 蒙特卡罗方法在脉冲中子测井中的应用[J].同位素, 2005(s1):21-25.
[20]	Meléndez-Martínez J, Schmitt D R . A comparative study of the anisotropic dynamic and static elastic moduli of unconventional reservoir shales:implication for geomechanical investigations[J]. Geophysics, 2016,81(3):D253-D269.
[21]	Ruan Z, Yu B S, Chen Y Y . Application of fluid inclusion analysis for buried dissolution predicting in the Tahe oilfield of Tarim basin,NW China[J]. Journal of Earth Science, 2014,24(3):343-354.
[22]	刘建伟, 张云银, 曾联波 , 等. 非常规油藏地应力和应力甜点地球物理预测——渤南地区沙三下亚段页岩油藏勘探实例[J]. 石油地球物理勘探, 2016,51(4):792-800.
[23]	Zhang Z G, Du Y S, Gao L F , et al. The late mesozoic granodiorites from the Southwest Basin in the South China Sea and its tectonic implication[J]. Journal of Earth Science, 2012,23(3):268-276.
[24]	Antonio J, Tadeu A, Amado Mendes P A .Simulation of wave propagation in a fluid-filled borehole embedded in a cracked medium using a coupled BEM/TBEM formulation[J]. Bulletin of the Seismological Society of America, 2009,99(6):3326-3339.
[25]	Zhang X A, Wang Z W . Distinguishing oil and water layers by interpreting acoustic logging data with changing well diameters[J]. Geophysical Prospecting, 2015,63(3):669-679.