Computation of Surge-Pressure-Wave Propagation During Cementation Process

Assaad, W.; Crescenzo, Daniele Di; Murphy, Darren; Boyd, John W.

doi:10.2118/194151-pa

Cited by 3 publications

(1 citation statement)

References 12 publications

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“…Assaad et al proposed a model to simulate the surge pressure and pressure wave propagation that may occur during oil and gas well construction. [17] Adiputro applied to pressure transient analysis (PTA) numerical simulation of well MOL-GT-03 in Belgium, adopting 1D radial fractal grid model, which clearly reflects the low permeability and fracture of the reservoir. [18] The water hammer effect is studied by solving the wave equation to help identify the range of the well section, thus providing the estimation of the reservoir boundary.…”

Section: Introductionmentioning

confidence: 99%

Influence of Instantaneous Shut‐In on the Safety of Tubing String in Ultra‐Deep High‐Temperature and High‐Pressure Gas Well

Zhang,

Zheng,

Yang

et al. 2024

Energy Tech

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In this article, considering the factors such as well trajectory and tubing string structures, the transient shut‐in tubing string pressure fluctuation model of ultra‐deep high‐temperature and high‐pressure (hereinafter referred to as HTHP) gas well is established, the propagation of pressure wave along the well depth is obtained, and the effects of different production and shut‐in time on the fluctuating pressure and its variation range are analyzed. Through calculation and analysis, it can be seen that there are differences in pressure waveforms at different well depths. The closer to the bottom of the well, the more delayed the occurrence of water hammer, and the smaller the water hammer pressure value. The larger the production, the greater the pressure wave velocity, and the closer to the wellhead, the more obvious the change. For well X, the pressure wave velocity in the well section below 6500 m varies greatly with the increase of production. When the production is 140 × 104 m3 D−1, the difference of pressure wave velocity between the bottom hole and the wellhead is 105.19 m s−1. After instantaneous shut‐in, the wellhead pressure increases by 3.2% compared with the initial pressure and the bottom hole pressure increases by 0.6%.

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Section: Introductionmentioning

confidence: 99%

Influence of Instantaneous Shut‐In on the Safety of Tubing String in Ultra‐Deep High‐Temperature and High‐Pressure Gas Well

Zhang,

Zheng,

Yang

et al. 2024

Energy Tech

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Research on the Fluid Flow Characteristics in the Process of Pump Closing in Cementing

Zheng

Liu

et al. 2020

Chem Technol Fuels Oils

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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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Computation of Surge-Pressure-Wave Propagation During Cementation Process

Cited by 3 publications

References 12 publications

Influence of Instantaneous Shut‐In on the Safety of Tubing String in Ultra‐Deep High‐Temperature and High‐Pressure Gas Well

Influence of Instantaneous Shut‐In on the Safety of Tubing String in Ultra‐Deep High‐Temperature and High‐Pressure Gas Well

Research on the Fluid Flow Characteristics in the Process of Pump Closing in Cementing

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

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