Azimuthal cement evaluation with an acoustic phased-arc array transmitter: numerical simulations and field tests
Che Xiao-Hua1,2, Qiao Wen-Xiao1,2, Ju Xiao-Dong1,2, and Wang Rui-Jia1,2
1. State Key Laboratory of Petroleum Resources and Prospecting, China University of Petroleum, Beijing 102249, China.
2. Key Laboratory of Earth Prospecting and Information Technology, Beijing 102249, China.
Abstract:
We developed a novel cement evaluation logging tool, named the azimuthally acoustic bond tool (AABT), which uses a phased-arc array transmitter with azimuthal detection capability. We combined numerical simulations and field tests to verify the AABT tool. The numerical simulation results showed that the radiation direction of the subarray corresponding to the maximum amplitude of the first arrival matches the azimuth of the channeling when it is behind the casing. With larger channeling size in the circumferential direction, the amplitude difference of the casing wave at different azimuths becomes more evident. The test results showed that the AABT can accurately locate the casing collars and evaluate the cement bond quality with azimuthal resolution at the casing–cement interface, and can visualize the size, depth, and azimuth of channeling. In the case of good casing–cement bonding, the AABT can further evaluate the cement bond quality at the cement–formation interface with azimuthal resolution by using the amplitude map and the velocity of the formation wave.
CHE Xiao-Hua,QIAO Wen-Xiao,JU Xiao-Dong et al. Azimuthal cement evaluation with an acoustic phased-arc array transmitter: numerical simulations and field tests[J]. APPLIED GEOPHYSICS, 2016, 13(1): 194-202.
[1]
Bellabarba, M., Bulte-Loyer, H., and Froelich, B., et al., 2008, Ensuring zonal isolation beyond the life of the well: Oilfield Review, 20, 18-31.
[2]
Bigelow, E. L., Domangue, E. J., and Lester R. A., 1990, A new and innovative technology for cement evaluation: 65th Annual Technical Conference and Exhibition of the SPE 20585.
[3]
Bolshakov, A., Dubinsky, V., Tang X. M., et al., 2010, Casing resonant radial flexural modes in cement bond evaluation: U. S. Patent 7, 681, 450.
[4]
Che, X. H., and Qiao, W. X., 2009, Numerical simulation of an acoustic field generated by a phased arc array in a fluid-filled borehole: Petroleum Science, 6(3), 225-229.
[5]
Che, X. H., Qiao, W. X., Wang, R. J., et al., 2014, Numerical simulation of an acoustic field generated by a phased arc array in a fluid-filled cased borehole: Petroleum Science, 11(3), 385-390.
[6]
Cheng, N. Y., Cheng, C. H., and Toksöz, M. N., 1995, Borehole wave propagation in three dimensions: Journal of the Acoustical Society of America, 97, 3483-3493.
[7]
Duan, W. X., Qiao, W. X., Che, X. H., et al., 2014, Acoustic evaluation of cementing quality using obliquely incident ultrasonic signals: Applied Geophysics, 11(3), 269-276.
[8]
He, X. and Hu, H. S., 2009, Borehole flexural modes in transversely isotropic formations: the low-frequency asymptotic velocity: Geophysics, 74(4), E149-E158.
[9]
He, X., Hu H. S., and Guan, W., 2010, Fast and slow flexural waves in a deviated borehole in homogeneous and layered anisotropic formations: Geophysical Journal International, 181(1), 417-426.
[10]
He, X., Chen, H., and Wang, X. M., 2014, Ultrasonic leaky flexural waves in multilayered media: cement bond detection for cased wellbores: Geophysics, 79(2), A7-A11.
[11]
Hu, G. S., 2003, Digital signal processing: Tsinghua University press, second edition.
[12]
Liu, Q. H., Schoen, E., Daube, F. et al., 1996, A three-dimensional finite difference simulation of sonic logging: Journal of the Acoustical Society of America, 100, 72-79.
[13]
Loizzo, M., Miersemann, U., Lamy, P., et al., 2013, Advanced cement integrity evaluation of an old well in the Rousse field: Energy Procedia, 37, 5710-5721.
[14]
Lu, J. Q., Ju, X. D., Qiao, W. X., et al., 2014, Azimuthally acoustic logging tool to evaluate cementing quality: Journal of Geophysics and Engineering, 11(4), 1-12.
[15]
Mou, Y. G., 1993, Digital processing method of the seismic data: Petroleum Industry press.
[16]
Pardue, G. H., Morris, R. L., Gollwitzer, L. H., et al., 1963, Cement bond log-a study of cement and casing variables: Journal of Petroleum Technology, 15(5), 545-555.
[17]
Qiao, W. X., Ju, X. D., Chen, X. L., et al., 2006, Downhole acoustic arc array transmitter with controlled azimuthal directivity: China Patent 03137596. 0.
[18]
Qiao, W. X., Che, X. H., Ju, X. D., et al., 2008, Acoustic logging phased arc array and its radiation directivity: Chinese Journal of Geophysics, 51(3), 939-946.
[19]
Qiao, W. X., Ju, X. D., Che, X. H., et al., 2011, Progress in acoustic well logging technology: Well Logging Technology, 35(1), 14-19.
[20]
Song, R. L., Liu, J. X., Hou, C. H., et al., 2012, Numerical simulation of Sector Bond log and improved cement bond image: Geophysics, 77(4), no. 4, D95-D104.
[21]
Tubman, K. M., Cheng, C. H., Cole, S. P., et al., 1986, Synthetic full-waveform acoustic logs in cased boreholes, II-poorly bonded casing: Geophysics, 51(4), 902-913.
[22]
Tubman, K. M., Cheng, C. H., and Toksoz, M. N.. 1984, Synthetic full waveform acoustic logs in cased boreholes: Geophysics, 49(7), 1051-1059.
[23]
Tang, H. P., Zhang, H. T., and Li, G. R., 2012, Applications of isolation scanner (IBC) imaging logging in horizontal well: Journal of Oil and Gas Technology, 34(8), 88-93.
[24]
van Kuijk, R., Zeroug, S., Froelich, B., et al., 2005, A novel ultrasonic cased-hole imager for enhanced cement evaluation: International Petroleum Technology Conference.
[25]
Zhu, G. M., 1992, Vertical seismic profile method, Petroleum Industry Press.
2016, Vol. 13 
