Simulation of Multiphase Fluid-Hammer Effects during Well Shut-In and Opening

Han, Guoqing; Ling, Kegang; Khor, Siew Hiang; Zhang, He

doi:10.2118/160049-ms

Cited by 3 publications

(2 citation statements)

References 10 publications

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“…During exploitation of high-temperature, high-pressure and high-production gas wells, fluid flow rate in tubing string is high. In addition to well opening and shut-in conditions (Han et al, 2012;Jin et al, 2011), the different geological conditions of different regions will affect the production of gas well (Zhang et al, 2020a). If the fluid flow rate in tubing string changes significantly for certain factors and results in momentum conversion in these conditions, violent pressure fluctuations will be caused in tubing string (Li et al, 2013).…”

Section: Symbol Annotationsmentioning

confidence: 99%

Research on the influence of production fluctuation of high-production gas well on service security of tubing string

Zhi

Wang

Li³

et al. 2021

Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles

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The production of high temperature and high pressure gas wells fluctuates with time, which makes the pressure in the string fluctuate obviously and affects the service security of tubing string. In this paper, a pressure fluctuation model of the complete production process (including well opening, production and shut-in) is established, which is suitable for the multiphase flow of gas well. The pressure fluctuation in the tubing string is simulated. Influence of different well depth and average production on the fluctuating pressure of gas well are analyzed. According to the research results, if the well opening time top is 50 s, a transient pressure fluctuation is generated at wellhead and drops gradually. After the production starts, a pressure fluctuation will occur at wellhead 10~15 s after top, which is small and attenuates quickly. Pressure increases quickly in the shut-in moment and reaches the peak at tsh. Although pressure increases gradually with the well depth, fluctuation flattens out. The hysteresis phenomenon in appearance of pressure wave becomes more and more obvious with the well depth. The greater the production of gas well, the greater the pressure fluctuation in tubing string during well opening and production, but the value may not be very high. During well shut-in, the greater the production, the greater the pressure fluctuation and the value. Amplitude, angular frequency and value of phase are in direct proportion to pressure fluctuation degree and valve radix is in inverse proportion to pressure, which means that the greater the valve radix, the smaller the pressure.

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Section: Symbol Annotationsmentioning

confidence: 99%

Research on the influence of production fluctuation of high-production gas well on service security of tubing string

Zhi

Wang

Li³

et al. 2021

Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles

View full text Add to dashboard Cite

show abstract

“…Nonetheless, this modeling method was formulated based on the assumption that the gas void fraction uniform distribution. Han et al (2012 used the commercial software to represent the water hammer effects introduced during well startup and shut-in. Wang et al (2016) investigated the water hammer effect caused by the sudden intrusion of formation fluid into the drilling process, while it does not refer to shut-in and only limited parameters such as gas influx rates was analyzed.…”

Section: Introductionmentioning

confidence: 99%

Wellbore annulus water hammer pressure prediction based on transient multi-phase flow characteristics

Jiang

et al. 2019

Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles

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Water hammer pressure has been known to cause formation fracture and well-control problems. Accurate prediction of water hammer pressure is crucially important to determine the selection of shut-in methods. In this study, the mathematic model of wellbore annulus transient water hammer has been established with the consideration of transient multi-phase flow characteristics, and it has been solved by the Method Of Characteristic (MOC). Finally, this paper focused on the effects of gas cutting, shut-in time and friction on water hammer pressure, and gas kick time were also regarded to study on the influence of water hammer pressure. The results show that both the gas cutting and gas kick time have few influences on the maximum water hammer pressure, but intensified the attenuation of water hammer pressure. Additionally, the peak value of water hammer pressure declines with the increase of the shut-in time, and the effect of friction loss on water hammer pressure became significant with the increase of well depth. More importantly, both the additional water hammer pressure and Shut-In Casing Pressure (SICP) generated by the closure of BlowOut Preventer (BOP) are likely to cause formation at the shallow casing shoe damage.

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Water Hammer Modeling in Extended Reach Wells

Livescu

Watkins

2014

Day 2 Wed, March 26, 2014

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Water hammer tools (WHTs) are used in coiled tubing (CT) operations for postponing a potential helical lock-up and running deeper into the hole. By rapidly opening and closing a valve in the tool, pressure pulses are created and the axial vibrating force is overcoming the friction between the CT and the wellbore. The pressure pulses depend on the CT parameters (size and material), WHT parameters (size and valve frequency), pumping rate, and downhole pressure. Although the effect of the water hammer pulses on the axial and radial vibrations has been investigated before, the coupling between water hammer pulses and the axial and radial vibrations for CT operations is not currently understood. Radial vibrations may be important as they may reduce the normal and thus the frictional forces between the CT and the wellbore and increase the reach in long horizontal wells. In this paper the effect of the water hammer pulses on the radial vibrations is investigated. A numerical model was developed to simulate the water hammer pulses and vibrations of the CT and WHT assembly. The model was validated against lab data for the case of a single WHT located at the end of a CT. Then the model was used to investigate the optimal performance of the WHT. Several scenarios, such as a WHT located between two CTs and two WHTs working in tandem, were also investigated. It is concluded that the radial vibrations which appear due to the water hammer pulses when two WHTs are used in tandem may be beneficial in reducing the friction forces between the CT and the wellbore. When two WHTs are used, a relationship between the additional pumping pressure and the distance between the two tools is also proposed.

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Simulation of Multiphase Fluid-Hammer Effects during Well Shut-In and Opening

Cited by 3 publications

References 10 publications

Research on the influence of production fluctuation of high-production gas well on service security of tubing string

Research on the influence of production fluctuation of high-production gas well on service security of tubing string

Wellbore annulus water hammer pressure prediction based on transient multi-phase flow characteristics

Water Hammer Modeling in Extended Reach Wells

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