M. Mardi scite author profile

A polymer flooding technique is developed to reduce the amount of residual oil saturation that cannot be recovered through waterflooding or gas injection processes. Using polymer flooding in the case of high-viscosity oil has been successful due to reducing mobility ratio (M), whereas there is conflict in efficiency of polymer flooding in the case of low-viscosity oil.In this study, to investigate the behavior of polymer flooding in low-viscosity oil, the transparent materials (glass) were used to construct a micromodel and to study various aspects of micro-displacement. By using a micromodel, the displacement of the fluid and menisci was observed and investigated with the aid of images captured by a camera.In this work, two kinds of quarter five-spot glass micromodel patterns were designed and developed and considered as pores medium. These patterns were saturated with light and low-viscosity oil samples from an Iranian fractured reservoir and then flooded by a polymer slug in low-pressure and low-temperature conditions. Three polymer types, hydrolyzed polyacrylamide (HPAM 25%), very low hydrolyzed polyacrylamide (<5%; PA) and xanthan, were utilized to inspect the effects of polymer type, concentration, injection rate, pore structure, and presence of connate water on recovery of low-viscosity oil.The results of experiments illustrated that recovery from HPAM is higher than both xanthan and very low hydrolyzed polyacrylamide. Rate sensitivity tests showed that increasing rate injection induced a decrease in recovery. Flooding in two different micromodel patterns demonstrated that higher permeability leads to lower recovery. In addition, experiments indicated that the presence of connate water caused a reduction in recovery. Finally, compared with waterflooding, polymer flooding resulted in a considerable growth in ultimate oil recovery.

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An Experimental Investigation of Surfactant Flooding Efficiency in Low Viscosity Oil Using a Glass Micromodel

Hematpour¹,

Arabjamloei

Nematzadeh

et al. 2012

Energy Sources, Part A: Recovery, Utilization, and Environmenta

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A surfactant flooding technique is developed to reduce the amount of residual oil saturation by reducing interfacial tension between multiple phases. Using surfactant flooding in the case of high viscosity oil has been successful, whereas there has not been a complete study of efficiency of this method when dealing with low viscosity oil. In the present study, to investigate the behavior of surfactant flooding in low viscosity oil, the transparent material (glass) was used to construct a micromodel and to study various features of micro-displacement. By implementing a micromodel, the displacement of the fluid and menisci was observed and investigated with the aid of high resolution images. In this work, three types of quarter fivespot glass micromodel patterns were designed and developed, and considered as porous medium. These patterns were saturated with a light and low viscosity oil sample from an Iranian fractured reservoir, and then flooded by surfactant slug in low pressure and low temperature conditions. Two surfactant types, PNX-2360 TM and linear alkylbenzene sulphonate, were utilized to inspect the effects of surfactant type, surfactant concentration, co-surfactant concentration, and pore structure in the presence of connate water, and their results were compared to water flooding. Moreover, high resolution images were captured, which illustrate the interaction between surfactant and connate water in micro-scale. The results of experiments illustrated that linear alkylbenzene sulphonate results in higher recovery. It was also found that recovery rises by increasing surfactant concentration. Testing different concentrations of co-surfactants demonstrated that, however, lower concentration of co-surfactants leads to higher recovery, but this increase in recovery is economically considerable. In addition, compared with water flooding, surfactant flooding resulted in a considerable growth in ultimate oil recovery.

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Application of Artificial Neural Networks in Water Saturation Prediction in from Iranian Oil Field

Mardi¹,

Ghasemalaskari²

2010

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M. Mardi

A Water Saturation Prediction Using Artificial Neural Networks and an Investigation on Cementation Factors and Saturation Exponent Variations in an Iranian Oil Well

Experimental Study of Polymer Flooding in Low-Viscosity Oil Using One-Quarter Five-Spot Glass Micromodel

An Experimental Investigation of Surfactant Flooding Efficiency in Low Viscosity Oil Using a Glass Micromodel

Application of Artificial Neural Networks in Water Saturation Prediction in from Iranian Oil Field

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