Dynamic Simulation of Major Kick for an HP/HT Well in Western China

Zhao, Haiyang; Li, Shuanggui; Jia, Xiaobin; Sun, Guo Hua; Wang, Ke; Peiliang, Chen; Xu, Yandong; Wu, Long; Xu, Liru; Gao, Wei; Qiu, Kaibin

doi:10.2118/183027-ms

Cited by 3 publications

(1 citation statement)

References 14 publications

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“…Yin et al established a model for multiphase transient flow in annuli during gas kick on the bases of gas‐liquid two‐phase flow and flash theories in annuli. Zhao et al simulated the gas kick development and well killing for an HP/HT Well in Western China using a dynamic hydraulic and well control simulator powered by transient multiphase flow model, and the results showed that the killing pump rate was not adequate given the gas kick in the wellbore. The dynamic simulations successfully revealed the reason for the gas suspension in the wellbore during shut‐in and predicted the gas cap.…”

Section: Introductionmentioning

confidence: 99%

Research on dynamical overflow characteristics of a vertical H₂S‐containing natural gas well

Mao

Cai

Liu

et al. 2019

Energy Science & Engineering

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This work aims to explore the overflow characteristics of a vertical H2S‐containing natural gas well. A two‐phase flow model for H2S‐containing natural gas well combining with a transient temperature prediction model was established to simulate the overflow process of a vertical H2S‐containing natural gas well. The model was validated by reproducing the field data of Well Longhui #2. The effects of H2S content, mud displacement, drilling fluid density, geothermal gradient, and reservoir permeability on the overflow characteristics of a vertical H2S‐containing natural gas well were studied and analyzed in this work. Results indicate that bubble, slug, and churn flows constitute the main flow patterns in the whole overflow process. The higher the H2S content is, the more obviously the gas void fraction increases. The phase change position of H2S is closer to the wellhead at lower H2S content. An increase in mud displacement indicates the decreases in overflow time. As drilling fluid density increases, the release position of H2S moves up, and the overflow time and shut‐in casing pressure increase. The initial gas void fraction is higher and the gas invasion volume will be larger in gas reservoirs with higher permeability. As the reservoir permeability increases, the shut‐in casing pressure rises while the overflow time declines. With higher geothermal gradient, the wellbore temperature tends to be higher at the same depth, leading to an increase in the H2S solubility. The gasification starting position is further away from the wellhead at higher geothermal gradient. The results of this work could provide important theoretical basis and technical guidance for drilling engineers to reduce a blowout risk during drilling of H2S‐containing natural gas well.

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Section: Introductionmentioning

confidence: 99%

Research on dynamical overflow characteristics of a vertical H₂S‐containing natural gas well

Mao

Cai

Liu

et al. 2019

Energy Science & Engineering

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Dynamic Well Control Simulation to Ensure Safer Sampling and Deep Transient Testing: Case Studies from the Southeast Asia Region

Kassim,

Marzuki,

Azid

et al. 2023

Day 1 Tue, May 23, 2023

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The objective of this paper is to present well control challenges, and results of utilizing wellbore dynamic simulation to achieve safer formation tester (FT) sampling and deep transient tests (DTT) operations. Insight will be provided based on the first implementation in a Southeast-Asia offshore well, with focus on pre-job simulation that is validated with measured data to help improve understanding of gas/hydrocarbon interaction with wellbore mud during and after FT pump-out operations. FT involves obtaining formation pressure, pressure transients, and downhole fluid samples, and the latest DTT technology enables larger gas/hydrocarbon volumes to be pumped into the wellbore which requires a comprehensive understanding of the processes involved. Wellbore dynamics accurately predicts the interactions between downhole pumped hydrocarbon and drilling fluid using a dynamic multiphase flow simulator. For the sampling operation, a maximum allowable downhole gas volume is evaluated prior to operation and simulations are compared to surface gas observation obtained during a wiper trip (mud circulation). During DTT operations, pumped formation fluids are routed to a circulating sub, where they are mixed with circulated mud and the mixed fluids are simultaneously carried to surface. Downhole wellbore pressure measurements are sent to a real time cloud-based dashboard and compared with simulations. The ability to weigh measurements against simulations creates a comprehensive understanding of well control scenarios and provides a much safer execution of FT operations than conventional methods. For wireline FT operation, post job comparison showed that the simulation matched well with surface observations during the wiper trip. The simulator accurately predicted the surface free gas arrival compared to mud-gas logging measurements, which confirmed that gas stayed dissolved in the Synthetic Based Mud (SBM) downhole without migrating upwards. For DTT, wellbore pressure measurements were sent in real time to a cloud-based dashboard and are compared to simulations and simulations could be quickly re-run to account for changes in observed formation fluid, downhole flowrates or mud circulation rates. The FT and DTT operations were conducted successfully and safely and in both cases the measured data agreed well with the simulations. With the accurate wellbore dynamics simulator, changes in drilling fluid design, circulating rates, hydrocarbon composition, downhole pump rates, and pump duration for various FT design sequences are quantified, and the downhole well pressure, free-gas distribution along the well geometry, and gas rates on surface can be predicted. This insight provides more flexibility and understanding to plan advanced FT operations and enables larger volumes of hydrocarbon to be pumped downhole. Furthermore, adopting an advanced pressure transient testing method like DTT also aligns with the industrial effort of reducing carbon dioxide emission footprint.

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Enhancing Well Control Safety with Dynamic Well Control Cloud Solutions: Case Studies of Successful Deep Transient Test in Southeast Asia

Abu Talib,

Ahmad Kassim,

Marzuki

et al. 2023

SPE/IATMI Asia Pacific Oil &Amp; Gas Conference and Exhibition

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The objective of this paper is to address the challenges related to well control and highlight the successful implementation of deep transient tests (DTT) operations in an offshore well located in Southeast Asia that was carried out by PETRONAS with the help of a dynamic well control simulation platform. The paper aims to provide insights into the pre-job simulation process, which ensured a safer operation from a well control perspective. Additionally, a comparison between simulated and actual sensor measurements during the DTT operation will be presented. The latest DTT technology enables a higher volume of gas or hydrocarbon to be pumped into wellbore compared to formation tester (FT) operation. During the DTT operation, the pumped formation fluids are mixed with mud that is pumped from surface through a circulation sub into the annulus, and the mixture of fluids is then circulated out from annulus simultaneously to the surface during the drawdown period. To ensure well control safety, it is crucial to have a comprehensive understanding of the processes involved. Therefore, a dynamic multiphase flow simulator that takes into account the interactions between downhole pumped hydrocarbon and drilling fluids is important to better simulate the pressure downhole throughout the DTT operation. In this case study, simulations were conducted prior to the job execution, considering several sensitivities, to ensure that the operation stayed within a safe operating mud weight window while meeting the surface gas handling limits. During DTT execution, real time downhole measurements were sent to a cloud-based platform, where they were plotted on a graph alongside the simulation data for monitoring purposes. Any changes in observed formation fluid, downhole flow rates and mud circulation rates during the DTT operation were quickly reflected in the simulation, this enabled effective communication between the PETRONAS project and execution teams ensuring a safe well control condition throughout the operation. As a result, the DTT operation was conducted successfully and safely, with the measured data aligning well with the simulations. The accurate wellbore dynamics simulator allowed for quantification of changes in drilling fluid design, circulating rates, hydrocarbon composition, downhole pump rates, and pump duration for various formation testing design sequences. It also facilitated predictions of downhole well pressure, free-gas distribution along the well geometry, and gas rate on the surface. This valuable insight provides PETRONAS with more flexibility in understanding and planning advanced FT operations, while enabling larger volumes of hydrocarbons to be pumped downhole. Furthermore, adopting an advanced pressure transient testing method like DTT is in line with both industry and PETRONAS's efforts to reduce carbon dioxide emissions.

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Dynamic Simulation of Major Kick for an HP/HT Well in Western China

Cited by 3 publications

References 14 publications

Research on dynamical overflow characteristics of a vertical H₂S‐containing natural gas well

Research on dynamical overflow characteristics of a vertical H₂S‐containing natural gas well

Dynamic Well Control Simulation to Ensure Safer Sampling and Deep Transient Testing: Case Studies from the Southeast Asia Region

Enhancing Well Control Safety with Dynamic Well Control Cloud Solutions: Case Studies of Successful Deep Transient Test in Southeast Asia

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Dynamic Simulation of Major Kick for an HP/HT Well in Western China

Cited by 3 publications

References 14 publications

Research on dynamical overflow characteristics of a vertical H2S‐containing natural gas well

Research on dynamical overflow characteristics of a vertical H2S‐containing natural gas well

Dynamic Well Control Simulation to Ensure Safer Sampling and Deep Transient Testing: Case Studies from the Southeast Asia Region

Enhancing Well Control Safety with Dynamic Well Control Cloud Solutions: Case Studies of Successful Deep Transient Test in Southeast Asia

Contact Info

Product

Resources

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Research on dynamical overflow characteristics of a vertical H₂S‐containing natural gas well

Research on dynamical overflow characteristics of a vertical H₂S‐containing natural gas well