Your search keyword '"Onyejekwe, Ifeanyi Michael"' showing total 5 results

1. Prospects of Supercritical CO2 Injection for Niger Delta Heavy Oil-Fields Recovery.

Author

Izuwa, Nkemakolam Chinedu, Abili, Jackreece Denovan, Onyejekwe, Ifeanyi Michael, and Ekwueme, Stanley Toochukwu

Subjects

HEAVY oil, ENHANCED oil recovery, PETROLEUM reservoirs, VISCOSITY, OIL fields, INTERFACIAL tension

Abstract

This study assesses the potential of supercritical CO2 injection for the recovery of heavy oil in the Niger Delta Z-field, characterized by high viscosity crude with an API gravity of 18.6 API. Given the challenges posed by the viscosity of the reservoir fluid, conventional primary and secondary production schemes were deemed impractical. As a solution, hot supercritical CO2, was chosen as an enhanced oil recovery (EOR) method due to its miscibility properties with oil and the environmental benefit of reducing atmospheric CO2 concentrations. In the EOR process, supercritical CO2 with a viscosity of 0.095 cP was injected at a pressure of 3500 psia and a temperature of 200°F, above the Minimum Miscibility Pressure (MMP) to ensure miscibility with the reservoir fluids and mobilization of residual oil. The CO2 was heated at the surface and injected as hot CO2 to achieve viscosity reduction by heating up the reservoir fluid. The injected CO2, meeting the reservoir oil at miscible conditions, reduces the interfacial tension between the oil and the injected CO2, leading to oil phase swelling. The study employed a compositional simulator for the simulation of CO2 flooding, comparing two cases: natural depletion and supercritical (hot) CO2 injection. The simulation results after 5000 days of recovery indicate a recovery efficiency of 3.3% for the natural depletion case. In contrast, the supercritical CO2 EOR case demonstrates a remarkable recovery efficiency of 73%. Additionally, the analysis of gas recovery shows no significant difference between the two cases. These results show that natural depletion is not feasible for heavy oil recovery due to the low energy (dissolved gas) present in the oil at reservoir conditions and the inhibiting high viscous forces of the reservoir fluid that impede flow to the surface. In contrast, the deployment of hot CO2 injection emerges as a highly promising and substantial prospect for the recovery of heavy oil in the Z-field. The study suggests that this process should be considered for application in the recovery of other non-conventional heavy oil fields in the Niger Delta, particularly those that are not extractable through primary and secondary drive mechanisms. The success of hot CO2 injection, with its ability to reduce viscosity, achieve miscibility, and enhance recovery efficiency, positions it as a viable and environmentally beneficial EOR strategy for heavy oil reservoirs. [ABSTRACT FROM AUTHOR]

Published

2024

2. Modelling Fluid Inflow Equalisation using Inflow Control Devices on Horizontal Compartmentalised Oil Wells: Case Study of Niger Delta Oilfield.

Author

Yahya, Hassan Babidi, Ohia, Nnaemeka Princewill, Onyejekwe, Ifeanyi Michael, Duru, Ugochukwu Ilozurike, Ekwueme, Stanley Toochukwu, and Nwachukwu, Angela Nkechi

Subjects

HORIZONTAL wells, OIL well casing, PETROLEUM reservoirs, BERNOULLI equation, PRESSURE drop (Fluid dynamics), FLUID flow

Abstract

This study focuses on the modelling wellbore compartmentalization techniques for downhole flow control in both homogeneous and heterogeneous oil reservoirs. The objective was to achieve fluid inflow equalization to address variable productivity effects (VPE) in heterogeneous multilayered reservoirs and to ensure flow uniformity across horizontal intervals in homogeneous reservoirs, mitigating the heel-to-toe effect (THE) caused by frictional pressure drop in horizontal well completions. The compartmentalization along the wellbore was achieved using swellable packers, ensuring each well compartment had uniform productivity before equalization. Inflow equalization across compartments was accomplished using inflow control devices (ICDs). Analytical models for ICDs were developed based on fundamental fluid flow equations, including Darcy's and Bernoulli's equations. Simulation of the developed model was conducted using MATLAB 2014Rb. Three simulation cases were explored: Case 1 studied variable pressure effects in homogeneous reservoirs where pressure and permeability influenced inflow inequality; Case 2 examined variable pressure effects considering pressure, permeability, and skin as factors for inflow variation; Case 3 simulated inflow equalization in horizontal homogeneous reservoirs to counteract the heel-to-toe effects. The results demonstrated successful equalization in all cases: Case 1 achieved a target well production rate of 7500 stb/d; Case 2 resulted in a total target well inflow rate of 6250 stb/d; Case 3 achieved a composite well inflow rate of 15000 stb/d. Implementation of variable ICDs in the horizontal well segment prevented early water/gas breakthrough due to THE, enhancing well longevity and recovery efficiency, thereby improving total well recovery. [ABSTRACT FROM AUTHOR]

Published

2024

3. Performance analyses of hydroxyethyl cellulose (HEC) polymer as gelling agent in gravel-pack carrier fluid formulation for sand control of hydrocarbon production wells.

Author

Obibuike, Ubanozie Julian, Ekwueme, Stanley Toochukwu, Igbojionu, Anthony Chemazu, Onyejekwe, Ifeanyi Michael, Ohia, Nnaemeka Princewill, and Udochukwu, Mathew Chidubem

Subjects

HYDROCARBON manufacturing, BIOCIDES, SAND control in oil wells, DISTILLED water, SHEARING force

Abstract

Copyright of Materials Protection (0351-9465) is the property of Engineers Society for Corrosion Republic of Serbia, Belgrade and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

4. Rheological evaluation of Mucuna solannie for non-aqueous mud additive in drilling operations

Author

Omoregbee K. Osaretin, Uwaezuoke Nnaemeka, Hezekiah Agogo, Igwilo Kevin Chinwuba, Amaefule C. Vivian, and Onyejekwe Ifeanyi Michael

Subjects

Mucuna, Aqueous solution, Materials science, biology, Rheology, Nano, Drilling, Annular flow, Consistency index, Composite material, biology.organism_classification, Plastic viscosity

Abstract

Mucuna solannie is a Papilionaceace used in culinary. Its rheology using API specifications was evaluated. Compared with Carbogel, plastic viscosity of 17 against 16cP at 8ppb, yield point of 27 against 26 lb/100ft2 at 2ppb, 10 minutes gel strength of 17 against 15 lb/100ft2 at 6ppb, annular flow index of 0.46 against 0.42 at 8ppb, annular consistency index of 44.6 against 30.6 eq-centipoise at 2ppb, pressure drops of 10.43psi against 8.60psi at 2ppb, and cutting concentration of 1.272 vol. % against 1.215 vol. % at 8ppb were obtained. The results showed it has nano- particles

Published

2021

5. Analytical Model for the Estimation of Leak Location in Natural Gas Pipeline

Author

Onyejekwe Ifeanyi Michael, Ohia Nnaemeka Princewill, Igbojionu Anthony Chemazu, Ekwueme Stanley Toochukwu, Igwilo Kevin Chinwuba, and Obibuike Ubanozie Julian

Subjects

Leak, Steady state, Mathematical model, business.industry, Pipeline (computing), Flow (psychology), Mechanics, Natural gas, Upstream (networking), business, MATLAB, computer, Geology, computer.programming_language

Abstract

Mathematical model for leak location in natural gas pipeline has been developed in this paper. The model employs an isothermal steady state approach. Leak occurrence in the pipeline divides the pipeline into two sections-the upstream and downstream sections respectively. Analyses of leak incidences were carried out in the two pipeline sections giving rise to two equations being developed to address the leak localization. The first leak equation was developed by considering the upstream section of the pipeline while the second leak equation was developed by considering the downstream section of the pipeline. The two equations were analytically developed by slight modification of the Weymouth’s equation for gas flow in horizontal pipeline. Matlab software was used in the model simulation. Seven field data were used in the model simulation. The results from the Matlab simulation of the mathematical models developed gave the leak locations for each of the field cases. Comparison of the simulated results with actual results of leak locations determined experimentally revealed high level of accuracy with an average error of only 0.377% which is below the minimum acceptable limit. Furthermore analyses of results show that the two leak equations yield same results when used in the Matlab simulator. The model is highly suitable for accurate detection of leak in natural gas pipeline especially where economics and reliability is of essence.

Published

2019