Investigation of Fine Migration, Clay Swelling and Injectivity problem during FAWAG Study in West Malaysia Oil Field

Osman, Adil Mohamed; Halim, Nor Hadhirah; Alwi, Noraliza; Sedaralit, M Faizal; Ibrahim, Jamal; Hamid, Pauziyah Abdul; Ohen, Henry A.

doi:10.2523/iptc-17748-ms

Cited by 7 publications

(2 citation statements)

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“…Based on previous research, there are a wide range of factors influencing the water permeability value of core samples such as clay swelling, rehydration of unreacted minerals, dissolution/precipitation of matrix, fines migration and also water adhesion to the smallest pores of the matrix [7,9,14,[19][20][21]. B. Kanimozhi et al [22] reported that fines migration is becoming a serious problem in carbonate reservoirs and disturbing the well productivity of affected reservoirs.…”

Section: Introductionmentioning

confidence: 99%

Klinkenberg-Corrected and Water Permeability Correlation for a Sarawak Carbonate Field

Ahmad

Ali

2021

Fluids

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Klinkenberg-corrected permeability (k∞) or water permeability (kw) is an important input parameter for hydrocarbon reservoir simulation studies. The theoretical concept that a core sample’s k∞ is comparable to its kw is flawed and has to be verified, since experimental evidence indicates that k∞ and kw are clearly different. Thus, a series of gas and water permeability measurements were conducted on eight carbonate core plug samples from Sarawak, Malaysia to develop a correlation between both permeability values. The new k∞ vs. kw correlation clearly proved the differences between both permeability values for all samples. The findings were in agreement with FESEM-EDX and total suspended solids (TSS) analysis, which proved the migration of fines and clay particles that blocked the pore throats, thus reducing kw values. The new k∞ vs. kw correlation was validated using four different samples from the PETRONS-2 well using its k∞ values and comparing them with the respective measured kw values. The new correlation will reduce the amount of time and cost needed to obtain absolute liquid permeability values but may be further improved by conducting permeability measurements on more samples from the PETRONS field, which will improve the accuracy of hydrocarbon reservoir simulation of the PETRONS field.

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Section: Introductionmentioning

confidence: 99%

Klinkenberg-Corrected and Water Permeability Correlation for a Sarawak Carbonate Field

Ahmad

Ali

2021

Fluids

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“…Figure 6 shows the pressure drop generated across core BL1-4 goes up during successive higher injection rates but came back to near base line when injection rate was reduced to 0.5 mL/min. Increase in the pressure drop was observed after 0.8 mL/min indicated fines start to mobilize (Chee et al 2013;Osman et al 2014). The stable pressure drops generated at each baseline rate (0.5 mL/min) after elevated flow rates were used to determine the k/k w and plotted against flow rate as shown in Fig.…”

Section: Critical Velocity Without C-snps Treatmentmentioning

confidence: 99%

Experimental investigation of colloidal silica nanoparticles (C-SNPs) for fines migration control application

et al. 2021

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Formation damage due to fines migration is among the root causes for hydrocarbon productivity decline. This occurs due to minerals dislodging when reservoir fluid flow beyond critical velocity and by poor cementation after acid stimulation activities. Conventional chemical methods have been widely used to prevent the fines migration, however, most of the chemical stabilizer is less robust, functional based on composition of exchangeable cations in rock minerals, cause temporary stabilization and are not environmentally friendly. This paper explores the potential of colloidal silica nanoparticles (C-SNPs) as new solution for fines migration control application. A series of critical velocity core flooding experiments has been carried out to determine the C-SNPs efficiency in enhancing the critical velocity at various temperatures. Berea Buff cores pre-treated with 0.05% C-SNPs (35 nm), were exposed to elevated injection rates. Synthetic formation brine was injected via alternating increasing and return to baseline rate from 0.5 to 41.5 mL/min. The stabilize pressure drops generated during brine injection after C-SNPs injection were used to establish the baseline permeability, k w . The stabilized pressure drops generated after each elevated rate were calculated to determine the permeability, k (at 0.5 mL/min) and to establish the k/k w graph plot. The critical rate's value was obtained when permeability reduction occurred in the range from 10 to 20% from the initial permeability value. Microscopic visualization using FESEM of the treated cores showed traces of nanoparticles on the core surface and surface modification by surface roughness measurement via atomic surface microscopy (AFM). The permeability of all treated cores remained constant up to 5 mL/min. At 8.3 mL/min and above, variation in permeability was observed caused by fines mobilization but with no significant permeability drops up to 41.5 mL/min. Modification of pore walls and fines surfaces by nanoparticles attachment was described by low surface roughness. The attraction of fines particles on the pore wall and within the particles themselves had strengthened surface morphology, therefore, their detachment and mobilization in porous media were not seen when exposed to high injection velocity.

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Effects of Fines Migration and Reservoir Heterogeneity on Well Productivity: Analytical Model and Field Cases

Russell,

Nguyen,

Loi

et al. 2024

Journal of Energy Resources Technology, Part B: Subsurface Energy and Carbon Capture

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Formation damage due to fines migration after water breakthrough during oil and gas production results in significant well productivity decline. A recent study derived an analytical model for fines migration during commingled water-oil production in homogeneous reservoirs. Yet, reservoir heterogeneity highly affects well productivity. This paper develops an analytical model for layer-cake reservoirs. We develop a novel methodology of characterising productivity decline by the function of impedance versus water-cut, two quantities that are commonly measured throughout the production life of the well. The methodology is based on a new analytical model for inflow performance in layer-cake reservoirs under fines migration. The new model integrates pseudo phase-permeability functions for water-oil flow with equations for fines release and induced permeability damage. The analytical model reveals linear well impedance growth versus water-cut increase, where the slope is determined by a modified form of the mobility ratio which includes the extent of formation damage. This linear form is shown to arise when the formation damage factor is constant, regardless of the reservoir permeability distribution. The model is validated by comparison with production histories of five wells from three fields, which exhibit good agreement with the linear trend predicted by the new model. The explicit formulae allow for prediction of productivity at abandonment, determining the optimal well stimulation time, as well as reconstructing skin values during the early stages of production to better estimate the influences of other formation damage factors, like those induced during drilling and completion.

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Investigation of Fine Migration, Clay Swelling and Injectivity problem during FAWAG Study in West Malaysia Oil Field

Cited by 7 publications

References 0 publications

Klinkenberg-Corrected and Water Permeability Correlation for a Sarawak Carbonate Field

Klinkenberg-Corrected and Water Permeability Correlation for a Sarawak Carbonate Field

Experimental investigation of colloidal silica nanoparticles (C-SNPs) for fines migration control application

Effects of Fines Migration and Reservoir Heterogeneity on Well Productivity: Analytical Model and Field Cases

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