Numerical Simulation of Response Characteristic of Neutron Porosity Logging While Drilling
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摘要: 随钻中子孔隙度测井在随钻地层评价中发挥重要作用, 对其响应特性研究具有重要意义.利用蒙特卡罗方法建立随钻条件下地层模型, 模拟研究随钻中子孔隙度测井响应特性.模拟结果表明: 随钻和电缆测井相同条件下中子孔隙度响应变化趋势相同, 随钻中子孔隙度曲线反映孔隙度灵敏程度高于电缆测井, 但其测井响应受钻铤影响较大; 探测深度与地层孔隙度有关, 文中条件下探测深度和纵向分辨率分别为28 cm和19 cm; 在水平井和大斜度井中, 测量方位对中子孔隙度曲线影响较大; 相对倾角α越小, 中子孔隙度曲线过渡区域中点越接近地层界面; α小于60°时, 中子孔隙度曲线受围岩影响可忽略.Abstract: Neutron porosity logging while drilling (LWD) plays an important role in formation evaluation under LWD environment, so it has a great significance to study the logging response characteristic. Monte Carlo method is employed to build formation modeling under LWD conditions, and the response characteristic is simulated. The results reveal that the changing trend of porosity response of neutron logging while drilling is similar to that of wireline under the same conditions, the sensitivity of porosity curve in LWD to porosity is higher than wireline, but the neutron porosity logging response of LWD is affected severely by the drilling collar. The depth of investigation is related to formation porosity, and the depth of investigation and vertical resolution under the conditions in this paper is 28 cm and 19 cm, respectively. In high angle and horizontal wells, the effect of measurement azimuth on neutron porosity curve is slight. When the relative dip α is low, the midpoint of transition area of neutron porosity curve is close to the boundary surface. If α is less than 60°, the effect of the adjacent formation on porosity curve can be ignored.
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图 1 单个中子与物质的随机作用过程
作用过程:1.非弹性散射;2.裂变;3.种子俘获;4.中子逃逸;5.光子散射;6.光子逃逸;7.光子俘获
Fig. 1. Random action process of one neutron with materials
图 3 随钻与电缆测井中子孔隙度响应关系对比
Fig. 3. Comparison of neutron porosity response between LWD and wireline
图 4 随钻和电缆测井中子孔隙度绝对灵敏度(a)和相对灵敏度(b)随孔隙度变化曲线
Fig. 4. Relationship of absolute and relative sensitivity to neutron porosity in LWD and WL logging
图 5 α=0时视中子孔隙度模拟计算值与测量参考点关系曲线
Fig. 5. Relation of simulated value of apparent porosity and reference point for measurement when α=0
图 6 仪器穿过不同距离砂岩目的层时中子孔隙度响应曲线
Fig. 6. Porosity response curve when tool travels through target sand formation with different intervals
图 7 相对倾角为10°(a)和85°(b)时仪器穿过地层界面不同测量方位中子孔隙度响应曲线
Fig. 7. Porosity response curve of different measurement azimuth when tool travels through boundary surface with relative angle of 10° and 85 °
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[1] Afonso de Andre, C., Mainieri Vieira da Cunha, A., Boonen, P., et al., 2004. A Comparison of Logging-While-Drilling and Wireline Nuclear Porosity Logs in Shales from Wells in Brazil. Society of Petrophysicists and Well-Log Analysts, Netherlands. [2] Anton, N., Roberts, L.P., Inanc, F., et al., 2011. Neutron Porosity Measurements Using a Pulsed Neutron Generator and Li-6 Glass Neutron Detectors. Society of Petrophysicists and Well-Log Analysts, Colorado. [3] Briesmeister, J.F., 2000. MCNPTM-A General Monte Carlo N-Particle Transport Code. Society of Petrophysicists and Well-Log Analysts, Los Alamos. [4] Davis, R.R., Hall, J.E., Boutemy, Y.L., et al., 1981. A Dual Porosity CNL Logging System. Society of Petroleum Engineers, San Antonio, Texas. [5] Fricke, S., Madio, D.P., Adolph, B., et al., 2008. Thermal Neutron Porosity Using Pulsed Neutron Measurements. Society of Petrophysicists and Well-Log Analysts, Edinburgh, Scotland. [6] Holenka, J., David, B., Evans, M., et al., 1995. Azimuthal Porosity While Drilling. Society of Petrophysicists and Well-Log Analysts, Paris, France. [7] Hong, Y.M., 2007. Logging Principles and Comprehensive Interpretation. China University of Petroleum Press, Dongying, 249 (in Chinese). [8] Huang, L.J., 1985. Theory of Radioactive Well Logging. Petroleum Industry Press, Beijing, 150-151 (in Chinese). [9] Huang, L.J., Hu, Q.D., Yang, R.L., et al., 1996. Thin Bed Response of NGS Logs. Well Logging Technology, 20(5): 313-319 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTOTAL-CJJS605.000.htm [10] Mendoza, A., Preeg, W.E., Torres-Verdin, C., et al., 2005. Monte Carlo Modeling of Nuclear Measurements in Vertical and Horizontal Wells in the Presence of Mud-Filtrate Invasion and Salt Mixing. Society of Petrophysicists and Well-Log Analysts, New Orleans, Louisiana. [11] Peng, H., 2009. Review on Progress of Radioactive Well Logging Technology in 2000-2008. Well Logging Technology, 33(1): 1-8 (in Chinese with English abstract). http://www.cnki.com.cn/Article/CJFDTotal-CJJS200901002.htm [12] Qin, X.Y., Xiao, L.Z., Suo, B.F., 2003. The Developments of Logging-While-Drilling and Its Application. Progress in Exploration Geophysics, 26(4): 313-322 (in Chinese with English abstract). http://www.researchgate.net/publication/288927944_The_development_of_logging_while_drilling_and_its_application [13] Reichel, N., Evans, M., Allioli, F., et al., 1995. Neutron-Gamma Density (NGD): Principles, Field Test Results and Log Quanlity Control of a Radioisotope-Free Bulk Density Measurement. Society of Petrophysicists and Well-Log Analysts, Colombia. [14] Roberts, L.P., Kopal, M.M., 2010. Formation Absorption Effects on LWD Pulsed Thermal-Neutron Porosity Measurements. Society of Petrophysicists and Well-Log Analysts, Perth, Australia. [15] Tittman, J., Sherman, H., Nagel, W.A., 1966. The Sidewall Epithermal Neutron Porosity Log. Journal of Petroleum Technology, 18(10): 1351-1362. doi: 10.2118/1180-PA [16] Wang, X.G., Zhang, F., 2009. Effect of Drilling Fluid Density on Neutron Porosity in Underbalanced Drilling. Well Logging Technology, 33(3): 293-298 (in Chinese with English abstract). [17] Weller, G., Galvin, S.D., El-Halawani, T., 2005. A New Integrated LWD Platform Delivers Improved Drilling Efficiency, Well Placement, and Formation Evaluation Services. Society of Petroleum Engineers, Aberdeen, United Kingdom. [18] Wraight, P.D., Evans, M., Marienbach, E., et al., 1989. Combination Formation Density and Neutron Porosity Measurements While Drilling. Society of Petrophysicists and Well-Log Analysts, Denver, Colorado. [19] Xu, L.B., Gardner, R.P., Yin, H.Z., 2007. Responses of Nuclear Tools in Layered Media. Society of Petrophysicists and Well-Log Analysts, Austin, Texas. [20] Xu, L.B., Huiszoon, C., Schultz, W., 2009. A Comprehensive Investigation of Source Effects on Neutron Porosity Response for Logging-While-Drilling Measurements. Petrophysics, 51(3): 185-198. http://www.researchgate.net/publication/288284557_A_Comprehensive_Investigation_of_Source_Effects_on_Neutron_Porosity_Response_for_Logging-While-Drilling_Measurements [21] Yu, H.W., Sun, J.M., Yang, J.Z., et al., 2008. The Effect of Cuttings Bed on Compensated Neutron Log in the Horizontal Wells. Well Logging Technology, 32(4): 300-303 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTOTAL-CJJS200804005.htm [22] Zhang, F., Guo, J.F., Wang, X.G., 2010a. Monte Carlo Simulation of Neutron Porosity Response under the Condition of Air Drilling. Journal of Jilin University (Earth Science Edition), 40(1): 209-214 (in Chinese with English abstract). http://www.researchgate.net/publication/291287917_Monte_Carlo_simulation_of_neutron_porosity_response_under_the_condition_of_air_drilling [23] Zhang, F., Jin, X.Y., Hou, S., 2010b. Monte Carlo Simulation on Compensated Neutron Porosity Logging in LWD with D-T Pulsed Neutron Generator. Journal of Isotopes, 23(1): 15-21 (in Chinese with English abstract). http://www.researchgate.net/publication/303255745_Monte_Carlo_simulation_on_compensated_neutron_porosity_logging_in_LWD_with_D-T_pulsed_neutron_generator [24] Zhang, F., Yuan, C., 2010. Monte Carlo Simulation on Compensated Neutron Porosity Logging with D-D Neutron Generator. Well Logging Technology, 34(3): 227-232 (in Chinese with English abstract). http://www.researchgate.net/publication/303255745_Monte_Carlo_simulation_on_compensated_neutron_porosity_logging_in_LWD_with_D-T_pulsed_neutron_generator [25] Zhang, X.Y., Wang, J.N., Guo, Y.J., 2006. Advances and Trends in Logging While Drilling Technology. Well Logging Technology, 30(1): 10-15 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTOTAL-CJJS200601001.htm [26] Zou, D.J., Fan, Y.R., Deng, S.G., 2005. The Latest Development of Logging While Drilling Technology. Petroleum Instruments, 19(5): 1-4 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTOTAL-SYYQ200505000.htm [27] 洪有密, 2007. 测井原理与综合解释. 东营: 中国石油大学出版社, 249. [28] 黄隆基, 1985. 放射性测井原理. 北京: 石油工业出版社, 150-151. [29] 黄隆基, 胡庆东, 杨荣利, 等, 1996. 自然伽马能谱测井薄层研究. 测井技术, 20(5): 313-319. https://www.cnki.com.cn/Article/CJFDTOTAL-CJJS605.000.htm [30] 彭琥, 2009.2000-2008年放射性测井技术进展评述. 测井技术, 33(1): 1-8. doi: 10.3969/j.issn.1004-1338.2009.01.001 [31] 秦绪英, 肖立志, 索佰峰, 2003. 随钻测井技术最新进展及其应用. 勘探地球物理进展, 26(4): 313-322. https://www.cnki.com.cn/Article/CJFDTOTAL-KTDQ200304014.htm [32] 王新光, 张锋, 2009. 欠平衡钻井条件下钻井液的密度对中子孔隙度测井的影响. 测井技术, 33(3): 293-298. https://www.cnki.com.cn/Article/CJFDTOTAL-CJJS200903022.htm [33] 于华伟, 孙建孟, 杨锦舟, 等, 2008. 水平井内岩屑层对补偿中子测井的影响. 测井技术, 32(4): 300-303. doi: 10.3969/j.issn.1004-1338.2008.04.003 [34] 张锋, 郭建芳, 王新光, 2010a. 空气钻井条件下中子孔隙度测井响应的蒙特卡罗模拟. 吉林大学学报(地球科学版), 40(1): 209-214. https://www.cnki.com.cn/Article/CJFDTOTAL-CCDZ201001035.htm [35] 张锋, 靳秀云, 侯爽, 2010b. D-T脉冲中子发生器随钻中子孔隙度测井的蒙特卡罗模拟. 同位素, 23(1): 15-21. https://www.cnki.com.cn/Article/CJFDTOTAL-TWSZ201001005.htm [36] 张锋, 袁超, 2010. 利用D-D中子发生器进行补偿中子孔隙度测井的模拟研究. 测井技术, 34(3): 227-232. https://www.cnki.com.cn/Article/CJFDTOTAL-CJJS201003008.htm [37] 张辛耘, 王敬农, 郭彦军, 2006. 随钻测井技术进展和发展趋势. 测井技术, 30(1): 10-15. https://www.cnki.com.cn/Article/CJFDTOTAL-CJJS200601001.htm [38] 邹德江, 范宜仁, 邓少贵, 2005. 随钻测井技术最新进展. 石油仪器, 19(5): 1-4. https://www.cnki.com.cn/Article/CJFDTOTAL-SYYQ200505000.htm -
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