Due to the growing importance of shale oil and gas resources, more effective techniques to develop unconventional reservoirs are strongly required. In this paper, a new volumetric fracturing measure for unconventional resources based on oriented perforation technology has been introduced. Moreover, this innovative approach was validated through a series of laboratory experiments varying the parameters of physical models, such as perforation azimuth, perforation length and horizontal stress difference. The results showed that the artificial hydraulic fracture formed by using oriented perforation technology was not a satisfactory straight dual-wing fracture, instead, it was a bent dual-wing crack like “S” or “X”, which could significantly increase the stimulated reservoir volume. The perforation azimuth and horizontal stress difference were the primary factors that affected the formation of multi fractures. The reorientation path was extended with the increasing of the oriented perforation azimuth angle, but decreased with the increasing of horizontal stress difference. In addition, increasing the perforation length could greatly decrease the initiation pressure. Therefore, the oriented perforation technology could be as a powerful way to accelerate the exploitation of the unconventional reservoirs.

[1] Weng, D. W., Lei, Q., Xu, Y., Li, Y., Li, D. Q., & Wang, W. X. (2011). Network fracturing techniques and its application in the field. Acta Petrolei Sinica, 32(2), 280-284.

[2] Wang, H., Liao, X. W., Zhao, X. L., Zhao, D. F., & Liao, C. L. (2014). The progress of reservoir stimulation simulation technology in unconventional oil and gas reservoir. Special Oil and Gas Reservoirs, 21(2), 8-15.

[3] Hu, Y. Q., Jia, S. G., Zhao, J. Z., Zhang Y., & Mi, Q. B. (2013). Study on controlling conditions in network hydraulic fracturing. Journal of Southwest Petroleum University (Science & Technology Edition), 35(4), 126-132.

[4] Warpinski, N., Mayerhofer, M., & Vincent, M. (2008). Stimulating unconventional reservoirs: Maximizing network growth while optimizing fracture conductivity. Paper presented at the SPE Unconventional Resources Conference, Keystone, Colorado, USA.

[5] Wu, Q., Xu, Y., Wang, X. Q., Wang, T. F., & Zhang, S. L. (2012). Volume fracturing technology of unconventional reservoirs: Connotation, design optimization and implementation. Petroleum Exploration and Development, 39(3), 377-384.

[6] Zhang, G. Q., & Chen, M. (2009). Complex fracture shapes in hydraulic fracturing with oriented perforations. Petroleum Exploration and Development, 36(1), 103-107.

[7] Jiang, H., Chen, M., Zhang, G. Q., Jin, Y., Zhao, Z. F., & Zhu, G. F. (2009). Impact of oriented perforation on hydraulic fracture initiation and propagation. Chinese Journal of Rock Mechanics and Engineering, 28(7), 1321-1326.

[8] Tang, M. R., Zhao, Z. F., Li, X. W., & Zhao, W. (2010). Study and test on the new technology of multi-fracture fracturing. Oil Drilling & Production Technology, 32(2), 71-74.

[9] Zhu, H. Y., Deng, J. G., Jin, X. C., Hu, L. B., & Luo, B. (2015). Hydraulic fracture initiation and propagation from wellbore with oriented perforation. Rock Mechanics and Rock Engineering, 48(2), 585-601.