Wellbore Trajectory Control Technologies for Ultra-Deep and High-Temperature Horizontal Wells in the Shunbei Oil &amp; Gas Field

LI Wenxia; WANG Juhe; WANG Zhiguo; YANG Weixing; SHI Yucai

doi:10.11911/syztjs.2022073

Volume 50 Issue 4

Jul. 2022

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Petroleum Drilling Techniques > 2022 > 50(4): 18-24. > DOI: 10.11911/syztjs.2022073

LI Wenxia, WANG Juhe, WANG Zhiguo, et al. Wellbore trajectory control technologies for ultra-deep and high-temperature horizontal wells in the Shunbei Oil & Gas Field [J]. Petroleum Drilling Techniques，2022, 50(4)：18-24. DOI: 10.11911/syztjs.2022073

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Wellbore Trajectory Control Technologies for Ultra-Deep and High-Temperature Horizontal Wells in the Shunbei Oil & Gas Field

LI Wenxia^{1, 2,},
WANG Juhe^{1, 2},
WANG Zhiguo³,
YANG Weixing^{1, 2},
SHI Yucai⁴

1.
Petroleum Engineering Technology Research Institute, Sinopec Northwest Oilfield Company, Urumqi, Xinjiang, 830011, China
2.
Sinopec Key Laboratory for Enhanced Oil Recovery in Fractured and Vuggy Reservoirs, Urumqi, Xinjiang, 830011, China
3.
Petroleum Engineering Supervision Center, Sinopec Northwest Oilfield Company, Luntai, Xinjiang, 841600, China
4.
School of Petroleum Engineering, China University of Petroleum (East China), Qingdao, Shadong, 266580, China

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Received Date: March 13, 2022
Revised Date: June 28, 2022
Available Online: November 03, 2022

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Abstract

Abstract

The failure rate of Measure While Drilling (MWD) instruments is high in the Shunbei Oil&Gas Field due to deep buried reservoir and high bottom-hole temperature and pressure. The MWD instruments are often not available in high temperature section of horizontal wells and the wellbore trajectory is difficult to control. In order to reduce the difficulty of wellbore trajectory control and improve the drilling efficiency of ultra-deep and high-temperature horizontal wells in the Shunbei Oil&Gas Field, this study integrated wellbore trajectory design and control technology. The wellbore trajectory was designed as multiple circular arcs with higher build-up rates in upper section and lower build-up rates in lower section to optimize the bottom hole assembly (BHA) and drilling parameters. A Positive Displacement Motor (PDM) with single bend and stabilizer was applied for compound drilling and controlling the wellbore trajectory when no MWD instrument was available in the lower high-temperature section. The research and field applications demonstrated that adopting the above compound drilling and optimizing BHA and drilling parameters according to the predicted well inclination variation rates, the inability to apply MWD for wellbore trajectory control can be solved. And in this way, the difficulties in wellbore trajectory control was lowered, and the drilling efficiency is highly improved.

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Wellbore Trajectory Control Technologies for Ultra-Deep and High-Temperature Horizontal Wells in the Shunbei Oil & Gas Field

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