Microbe-induced fluid viscosity variation: field-scale simulation, sensitivity and geological uncertainty

Eric O Ansah,Hung Vo Thanh,Yuichi Sugai,Ronald Nguele,Kyuro Sasaki

doi:10.1007/s13202-020-00852-1

Eric O Ansah, Hung Vo Thanh + Show 3 more

Open Access

https://doi.org/10.1007/s13202-020-00852-1

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Abstract

This study is intended to expand the scope of microbial enhanced oil recovery (MEOR) simulation studies from 1D to field scale focussing on fluid viscosity variation and heterogeneity that lacks in most MEOR studies. Hence, we developed a model that incorporates: (1) reservoir simulation of microbe-induced oil viscosity reduction and (2) field-scale simulation and robust geological uncertainty workflow considering the influence of well placement. Sequential Gaussian simulation, co-kriging and artificial neural network were used for the petrophysical modelling prior to field-scale modelling. As per this study, the water viscosity increased from 0.5 to 1.72 cP after the microbe growth and increased biomass/biofilm. Also, we investigated the effect of the various component compositions and reaction frequencies on the oil viscosity and possibly oil recovery. For instance, the fraction of the initial CO2 in the oil phase (originally in the reservoir) was varied from 0.000148 to 0.005 to promote the reactions, and more light components were produced. It can be observed that the viscosity of oil reduced considerably after 90 days of MEOR operation from an initial 7.1–7.07 cP and 6.40 cP, respectively. Also, assessing the pre- and post-MEOR oil production rate, we witnessed two main typical MEOR field responses: sweeping effect and radial colonization occurring at the start and tail end of the MEOR process, respectively. MEOR oil recovery factors varied from 28.2 to 44.9% OOIP for the various 200 realizations. Since the well placement was the same for all realizations, the difference in the permeability distribution amongst the realizations affected the microbes’ transport and subsequent interaction with nutrient during injection and transport.

Highlights

Microbes are ubiquitous in almost all global oil reservoirs; normally, they are noted for biodegradation of alkane components of hydrocarbons, thereby changing its physical property
microbial enhanced oil recovery (MEOR) can be more effective in the mixed wet core than on the water wet core, because the residual oil is mostly in interconnected films in mixed wet cores against dislodged drops, which might be in the waterwet cores (Kaster et al 2012)
Placing an injection well in an extreme environment such as a high shale, low-porosity and low-permeability area can be detrimental to oil production and the overall success of MEOR

Summary

Introduction

Microbes are ubiquitous in almost all global oil reservoirs; normally, they are noted for biodegradation of alkane components of hydrocarbons, thereby changing its physical property (e.g. viscosity). MEOR could be achieved by the reduction in IFT through biosurfactant or bacteria cell, selective plugging by biopolymer, and oil viscosity reduction by biogas, acids and solvents. The need to model and optimizing MEOR considering fluid viscosity and reservoir heterogeneity at field scale. After 19 months of MEOR operations, there were decreased oil viscosity and 10% increase in average daily production (Segovia et al 2009). 3. Unable to simulate real field scenarios such as (2010), Nielsen et al (2016), Saito et al (2016), microbe-induced selective plugging and oil viscos- Shabani-Afrapoli et al (2011, 2012), Sugai et al

Limited data to validate the model

Conclusion

Findings

Compliance with ethical standards