Numerical modeling of onset and rate of sand production in perforated wells

Mohamad-Hussein, A.; Ni, Qinglai

doi:10.1007/s13202-018-0443-6

Cited by 23 publications

(5 citation statements)

References 13 publications

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“…In Eshiet et al's 34 study from 2019, sand production was found to be related to wellbore and perforation depths, indicating an increase in sand production with the deepening of the wellbore and perforation depths. Lastly, in 2018, Mohamad‐Hussein et al 35 suggested that the sand production volume and rate from production wells increase with higher production pressure differentials.…”

Section: Introductionmentioning

confidence: 99%

Experimental study on critical sand production pressure gradient at different production stages of high temperature and high pressure tight sandstone gas reservoir

Li,

Tuo

et al. 2024

Energy Storage

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Sand production is a common issue in sandstone gas reservoir development, severely impacting the productivity of sandstone gas wells. In order to thoroughly investigate the sand production characteristics of high‐temperature and high‐pressure tight sandstone gas reservoirs, this study focuses on six core samples from tight sandstone gas reservoirs(three samples with fractures), under reservoir conditions (185 MPa, 160°C), sand production experiments were conducted to thoroughly investigate the sand production patterns in sandstone reservoirs under the combined influence of different effective stresses and production pressure differentials. The results indicate: (1) under the simultaneous increase of effective pressure and production pressure differential, sand production near the wellbore (r = 0.1 m) becomes more likely in the reservoir; (2) in actual reservoirs without fractures near the wellbore (r = 0.1 m), sand production phenomena do not occur; (3) reservoirs with fractures near the wellbore (r = 0.1 m) are more prone to sand production, under an effective stress of 90 MPa, with specimens containing fractures exhibiting a 76.48% lower critical sand production pressure gradient compared to those without fractures; (4) when the pore fluid pressure is 95 MPa, the maximum gas production rate for Well X without sand production is 12.4 × 104 m3/d. The experimental results have guiding significance for the rational production of gas wells in this type of reservoir.

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Section: Introductionmentioning

confidence: 99%

Experimental study on critical sand production pressure gradient at different production stages of high temperature and high pressure tight sandstone gas reservoir

Li,

Tuo

et al. 2024

Energy Storage

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“…Zhu et al (2020) characterized the sand production process in sediments bearing gas hydrates through a numerical model with the objective of studying the influence of several parameters on the production of these solids together with the gas. Eventually, Mohamad-Hussein and Ni (2018) proposed a model capable of predicting the mass of accumulated sand and the rate produced in an oil well.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Sand Production Control in a Mature Oil Reservoir Through Electrical Well Profiles

Melo,

Gomes,

Costa Júnior

et al. 2023

BJPG

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The sand production happens when the reservoir begins its productive life, and the consolidation of the grains that compose the framework of the oil-producing formation is not enough to keep them cohesive. The front of the drag force is caused by the flow of fluids inside the pores of the rock-reservoir. Therefore, reservoir parameters must be analyzed to observe how they behave considering the production of solids. The operational parameters used in this study were compressional wave, shear wave and gamma ray profiles, depth, average overburden density, reservoir fluid pressure, and bottom pressure in flow during production. These data allowed us to predict the production of sand in a mature oil reservoir. The results show that in the zones that presented solids production, through the control of the dynamic pressure, it is possible to control the production of sand and determine the critical point of its production.

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“…Optimal sand management requires a complete understanding of the causing parameters of sand problems, so different validated methods and tools can be developed for predicting sand onset production and controlling it [9]. Changes in formation consolidation degree, water breakthrough, reservoir pressure depletion, changes in production rate, difference in viscosity and velocity of produced fluid, tectonic stress, heterogeneity of formation, and formation temperature effects all contribute to sand production [10,11,12,13,14,15].…”

Section: Introductionmentioning

confidence: 99%

Prediction of Sanding Likelihood Intervals Using Different Approaches

Naji

Abdul-Majeed

Alhuraishawy³

et al. 2023

Journal of Petroleum Research and Studies

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Sand production is undesirable matters, occurring in wells that are producing from sand reservoirs. It causes many problems such as erosion and grains accumulation in downhole and surface equipment’s, and formation subsidence. Important stage in sanding problem solution is a prediction of likelihood sand production intervals. In present paper, a vertical well X1 that is producing from Asmari reservoir in Y field at southern Iraq was selected for study. Asmari reservoir was classified to six units: A, B1, B2, B3, B4, and C. B zones consisted from sandstone with others rock types. Eight approaches were used for prediction sanding onset intervals by dealing with X1 well as open hole completion. Utilized eight prediction methods are compressional sonic wave (CSW), unconfined compressive strength (UCS), total porosity (PHIT), shear modulus to bulk compressibility (G/Cb), B-Index, Schlumberger index (S- Index), combined index (Ec-Index) and critical drawdown pressure (CDDP). All these methods performed based on 2462 measured points of CSW, sonic shear wave log (SSW), and density log (DL). Sand production likelihood intervals was selected by determination of cutoff values of adopted methods. Sand is possible to occur if interval has values lower than cutoff values of G/Cb, UCS, B-Index, S-Index, Ec, and CDDP and greater than cutoff values of CSW, and PHIT. Obtained cutoff values of eight approaches were 800 x 109 psi2, 36 Mpa, 0.2, 80 us/ft, 10000 Mpa, 108 Mpa, and 2700 Mpa, of G/Cb, UCS, PHIT, CSW, B-Index, S-Index, and Ec respectively. As well as sand production is possible to occur of bottomhole flowing pressure lower than calculated CDDP. Some Intervals had high CDDP that referred to abnormal pressure zones consisted from shale. Determination of sand onset intervals is a key for selecting best methods for controlling.

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Numerical modeling of onset and rate of sand production in perforated wells

Cited by 23 publications

References 13 publications

Experimental study on critical sand production pressure gradient at different production stages of high temperature and high pressure tight sandstone gas reservoir

Experimental study on critical sand production pressure gradient at different production stages of high temperature and high pressure tight sandstone gas reservoir

Analysis of Sand Production Control in a Mature Oil Reservoir Through Electrical Well Profiles

Prediction of Sanding Likelihood Intervals Using Different Approaches

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