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Abstract

To improve the recovery rate of oil in the formation, oil recovery technology has been continuously studied. Considering the experimental cost and data measurement in oil recovery research, laboratory oil recovery is the most effective method. The rock core model used in the simulation directly affects whether the research results are credible. However, the current three-dimensional rock core model manufacturing methods and corresponding models lack of reproducible, customizable, and visualized characteristics. In this study, a reproducible rock core model of microsphere accumulation based on the structure of natural rock core was designed and manufactured by microstereolithography. Oil recovery experiments and simulation studies show that the rock core model has similar flow characteristics to natural rock cores. In addition, resin rock core models with different structures and hydrogel rock core models with deformability are also manufactured by microstereolithography and used for simulation analysis. This research provides an effective and reproducible rock core structure model for the experiment of oil recovery research.

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References

Huang

, Chen

, Liu

, et al. Experimental and numerical study of steam-chamber evolution during solvent-enhanced steam flooding in thin heavy-oil reservoirs. J Petrol Sci Eng, 2019; 172:776.

Wang

, Dang

, Gao

. Method of moderate water injection and its application in ultra-low permeability oil reservoirs of Yanchang Oilfield, NW China. Petrol Explor Dev, 2018; 45:1094.

Liao

, Yang

, Jiang

, et al. Applicable scope of oxygen-reduced air flooding and the limit of oxygen content. Petrol Explor Dev, 2018; 45:111.

Jiang

, Wu

, Couples

, et al. The impact of pore size and pore connectivity on single-phase fluid flow in porous media. Adv Eng Mater, 2011; 13:208.

Bera

, Hauner

, Qazi

, et al. Oil-water displacements in rough microchannels. Phys Fluids, 2018; 30:112101.

Fan

, Liu

, Ni

, et al. Displacement mechanisms of residual oil film in 2D microchannels. ACS Omega, 2021; 6:4155.

Rezaei Dehshibi

, Mohebbi

, Riazi

, et al. Visualization study of the effects of oil type and model geometry on oil recovery under ultrasonic irradiation in a glass micro-model. Fuel, 2019; 239:709.

Liu

, Cheng

, Li

, et al. Experimental investigation of synergy of components in surfactant/polymer flooding using three-dimensional core model. Transport Porous Med, 2019; 126:317.

Vavra

, Zeng

, Xiao

, et al. Microfluidic devices for characterizing pore-scale event processes in porous media for oil recovery applications. J Vis Exp, 2018; 131:56592.

10.

, Zhu

, Huh

, et al. Microfluidic investigation of nanoparticles' role in mobilizing trapped oil droplets in porous media. Langmuir, 2015; 31:13673.

11.

Abgrall

, Gué

. Lab-on-chip technologies: Making a microfluidic network and coupling it into a complete microsystem—a review. J Micromech Microeng, 2007; 17:R15.

12.

Zhang

, Zhang

, Liu

, et al. 3D-printed multi-channel metal lattices enabling localized electric-field redistribution for dendrite-free aqueous Zn ion batteries. Adv Energy Mater, 2021; 11:2003927.

13.

Wang

, Martin

, Hini

, et al. Rapid fabrication of multilayer microfluidic devices using the liquid crystal display-based stereolithography 3D printing system. 3D Print Addit Manuf, 2017; 4:156.

14.

Macdonald

, Cabot

, Smejkal

, et al. Comparing microfluidic performance of three-dimensional (3D) printing platforms. Anal Chem, 2017; 89:3858.

15.

Bao

, Riordon

, Mostowfi

, et al. Microfluidic and nanofluidic phase behaviour characterization for industrial CO2, oil and gas. Lab Chip, 2017; 17:2740.

16.

Bhattacharjee

, Urrios

, Kang

, et al. The upcoming 3D-printing revolution in microfluidics. Lab Chip, 2016; 16:1720.

17.

Gentry

, Halloran

. Light scattering in absorbing ceramic suspensions: Effect on the width and depth of photopolymerized features. J Eur Ceram Soc, 2015; 35:1895.

18.

, Zhang

. Imaging and characterizing fluid invasion in micro-3D printed porous devices with variable surface wettability. Soft Matter, 2019; 15:6978.

19.

Shojaei

, Osei-Bonsu

, Grassia

, et al. Foam flow investigation in 3D-printed porous media: fingering and gravitational effects. Ind Eng Chem Res, 2018; 57:7275.

20.

Osei-Bonsu

, Grassia

, Shokri

. Investigation of foam flow in a 3D printed porous medium in the presence of oil. J Colloid Interf Sci, 2017; 490:850.

21.

, Krishnan

, van der Schaaf

, et al. Viscoelastic effects on residual oil distribution in flows through pillared microchannels. J Colloid Interf Sci, 2018; 510:262.

22.

Blunt

, Bijeljic

, Dong

, et al. Pore-scale imaging and modelling. Adv Water Resour, 2013; 51:197–216.

23.

Chen

, Liu

, Dong

, et al. High-speed 3D printing of millimeter-size customized aspheric imaging lenses with sub 7 nm surface roughness. Adv Mater, 2018; 30:8.

24.

Jamshidnezhad

, Montazer-Rahmati

, Sajjadian

. Experimental study of miscible fluid injection in Iranian artificially fractured porous media. J Jpn Petrol Inst, 2004; 47:54.

25.

Turksoy

, Bagci

. Improved oil recovery using alkaline solutions in limestone medium. J Petrol Sci Eng, 2000; 26:105.

26.

Ahmadi

, Zholobko

, Wu

. Inhomogeneous swelling behavior of a bi-layered spherical hydrogel containing a hard core. J. Appl Phys, 2020; 128:7.

27.

Kim

, Son

, Lee

, et al. pH dependent swelling behavior of poly(2-hydroxyethyl methacrylate)-based copolymer hydrogels. Polym-Korea, 2019; 43:181.

28.

Ilseng

, Prot

, Skallerud

, et al. Buckling initiation in layered hydrogels during transient swelling. J Mech Phys Solids, 2019; 128:219.

29.

Wang

, Chen

, et al. 3D printed ultrastretchable, hyper-antifreezing conductive hydrogel for sensitive motion and electrophysiological signal monitoring. Research, 2020; 2020:11.

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Three-Dimensional Rock Core-Like Microstructure Fabricated by Additive Manufacturing for Petroleum Engineering

Abstract

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