Abstract:The main reservoirs of A gas field in Xihu sag of East China Sea Basin are sand bodies deposited by distributary channels of the shallow delta, with quick lateral variation and strong heterogeneity. Therefore, it is risky in the implementation of development wells. Moreover, the P-wave impedance values of sandstone and shale in the target layer are superimposed, so it is impossible to distinguish the lithology and detect hydrocarbon based on the attribute analysis of post-stack seismic and P-wave impedance inversion technology. Based on the determination of lithology and fluid sensitive elastic parameters by rock physics analysis, the authors predicted the lithology by the pre-stack elastic parameter inversion technology, and quantitatively predicted the probability of hydrocarbons by FFP analysis technology. These two techniques have achieved good results in the development of A gas field. The main channel sand body shape was clearly depicted by the vp/vs obtained from pre-stack inversion, which guided the optimization of horizontal well and resulted in high sandstone penetration rate of 95%. The spatial probability distribution of gas-bearing sand bodies as predicted by FFP analysis based on the combination of vp/vs and P-wave impedance, so the potential gas reservoirs were predicted and the adjustment well was guided to tap the potential gas successfully. These two techniques have good application value for reservoir description and potential hydrocarbon prediction of P-wave impedance superimposed reservoirs in the oil and gas field of East China Sea.
李炳颖, 王伟, 黄鑫, 陈波, 张锡楠. 叠前弹性参数反演及FFP分析技术在东海A气田开发中的应用[J]. 中国地质调查, 2020, 7(2): 101-108.
LI Bingying, WANG Wei, HUANG Xin, CHEN Bo, ZHANG Xinan. Application of pre-stack elastic parameters inversion and FFP analysis techniques in the exploitation of A gas field, East China Sea. , 2020, 7(2): 101-108.
[1] 陈妍,张明振,罗霞,等.山东埕岛东部东营组三角洲砂体地震预测技术[J].中国地质调查,2016,3(2):51-57. [2] Hammond A L.Bright spot:Better seismological indicators of gas and oil[J].Science,1974,185(4150):515-517. [3] Backus M M,Chen R L.Flat spot exploration[J].Geophys Prospect,1975,23(3):533-577. [4] Clayton R W,Stolt R H.A Born-WKBJ inversion method for acoustic reflection data[J].Geophysics,1981,46(11):1559-1567. [5] Cooke D A,Schneider W A.Generalized linear inversion of reflection seismic data[J].Geophysics,1983,48(6):665-676. [6] Rutherford S R,Williams R H.Amplitude-versus-offset variations in gas sands[J].Geophysics,1989,54(6):680-688. [7] Connolly P.Elastic impedance[J].Leading Edge,1999,18(4):438-452. [8] 李爱山,印兴耀,张繁昌,等.叠前AVA多参数同步反演技术在含气储层预测中的应用[J].石油物探,2007,46(1):64-68,93. [9] 胡明毅,柯岭,梁建设.西湖凹陷花港组沉积相特征及相模式[J].石油天然气学报,2010,32(5):1-5. [10] 张雷,姜勇,侯志强,等.西湖凹陷低孔渗储层岩石物理特征分析及叠前同步反演地震预测[J].中国海上油气,2013,25(2):36-39. [11] Zoeppritz K.On the reflection and penetration of seismic waves through unstable layers[J].Gottinger Nachr,1919,1(7B):66-84. [12] 强敏,周义军,钟艳,等.基于部分叠加数据的叠前同时反演技术的应用[J].石油地球物理勘探,2010,45(6):895-898. [13] 姚云霞,刘江,张雷.叠前纵横波联合反演技术在PH油气田薄储层预测中的应用[J].中国海上油气,2011,23(6):377-379,386. [14] Sams M,Saussus D.Uncertainty of estimating lithology probability from deterministic inversion[C]//Proceedings of the 79th SEG Annual Meeting.2009:1790-1794. [15] Sams M,Saussus D.Comparison of lithology and net pay uncertainty between deterministic and geostatistical inversion work-flows[J].First Break,2010,28(2):35-44.
2020, Vol. 7 
