Comparison of all produced oil samples ANALYSIS OF ASPHALTENES- A MAJOR FACTOR BEHIND EMULSIONS- IN PRODUCED OIL AND SPENT ROCK FOR SAGD AND ES-SAGD Taniya.

Slides:

Advertisements

Similar presentations

Surfactant-Enhanced Spontaneous Imbibition in Oil-Wet, Heavy Oil Bearing Carbonate Formations Amir Amini Maura Puerto Clarence Miller George Hirasaki April.

Advertisements

SUSTAINABLE PROCESS INDUSTRY EUROPEAN INDUSTRIAL COMPETTIVENESS TROUGH RESOURCE AND ENERGY EFFICIENCY SPIRE Brokerage event October 22 nd 2013 Project.

Alberta Tar Sands Is it good for Canada?. Alberta Oil Sands Area.

P. Kim Sturgess, P.Eng. FCAE Canadian Water Summit June 14, 2011 Water – Energy Nexus: The Evolving Story.

The Alberta Oil Sands. Where are the Oil Sands? Alberta Oil Sands There are 3 major Deposits: 1.Athabasca 2.Cold Lake 3.The Carbonate Triangle: Peace.

1 Advancing a Low Carbon and Sustainable Water Economy Water in a World of 7 Billion Session 4: Getting at the Water-Energy Nexus May 8-12, 2012 Eddy Isaacs,

Construction Materials (CE 1206)

Laboratory Characterization of Municipal Solid Waste Incineration Ash Sita Marie Syal, Mohammad Kabalan, Matt Hambright, and Dr. Dimitrios Zekkos, P.E.

Asphalt Materials.

Ionic liquids enhanced solvent extraction for bitumen recovery from oil sands Reporter: Zhang Jianqiang Academic Advisor ： Professor Sui.

USEPA Petroleum Refinery Enforcement Emerging Issues February 22, 2011.

Heavy Oil Recovery Techniques

Pore-scale modelling of carbonates 1 Hiroshi Okabe Petroleum Engineering and Rock Mechanics Research Group Department of Earth Science and Engineering.

REVOLUTIONARY PORE SIZE AND POROSITY ANALYSIS Background image © renjith krishnan.

Regeneration of granular activated carbon (GAC) exhausted by model diesel fuel Xue Han Supervisor: Dr. Ying Zheng Hydroprocessing Laboratory Department.

Visit from DONG Energy Åsmund Haugen, Bergen, 9 jan

Observations of Microdrop Decan and Oil on Mica Surface by AFM and VSI. Ueda, A. 1, Kunieda, M. 1, Fukunaka, Y. 1, Liang, Y. 1, Matsuoka, T. 1 and Okatsu,

COMPARISON OF DRYING KINETICS OF SPENT GRAIN DRIED ON INERT MATERIAL OF DIFFERENT HEAT CAPACITY M. Zielinska a,b S. Cenkowski b a Department of Agro-Food.

PHARMACEUTICAL SUSPENSIONS AND EMULSIONS

The Framework of Modeling SOA Formation from Toluene Oxidation Di Hu and Richard Kamens Department of Environmental Sciences and Engineering, University.

Dr. Mohammed M. Amro Petroleum Engineering Dept. King Saud University Effect of Scale and Corrosion Inhibitors on Well Productivity in Reservoirs Containing.

Imbibition Assisted Recovery

Saleh K Al-Mansoori, Stefan Iglauer, Christopher H Pentland, Martin J Blunt Three-Phase Measurements of Non-Wetting Phase Trapping Applied to Carbon Dioxide.

Texas A&M UniversityFeb, 2004 Application of X-Ray CT to Investigate Effect of Rock Heterogeneity and Injection Rates During CO 2 Flood Process Deepak.

Tar Sands A Bridge to Tomorrow. What are Tar Sands? Tar sands, also called oil sands, are a mixture of bitumen, sand, water, and clay Tar sands, also.

Introduction to Effective Permeability and Relative Permeability

Seed Germination Biology I. The Scenario You will be given a dish with 10 seeds. Your job is to answer the following question: What is the percent Germination.

Organic matter migration through sediments without water 4(v)

Heavy Oil Issues & Solutions Aubrey Arms October 11, 2005 Energy Technology.

Presented by Sudiptya Banerjee

Wittaya Julklang, Boris Golman School of Chemical Engineering Suranaree University of Technology STUDY OF HEAT AND MASS TRANSFER DURING FALLING RATE PERIOD.

PRESENTS THE MOST ENVIRONMENTALLY-FRIENDLY OILFIELD CHEMICAL TO EVER COME TO MARKET:

Rheology of Viscoelastic surfactants and foam in homogeneous porous media Aarthi Muthuswamy, Clarence Miller, Rafael Verduzco and George Hirasaki Chemical.

The distillation mechanism in steam displacement of oil Dan Marchesin and Hans Bruining, ECMOR X Sept 4-7, 2006.

LOGO Feasibility Test of Applying Complex Remediation Technology for Diesel Contamination in Soil and Groundwater 2012 International Conference on Environmental.

Oil Sands Michael Cibicki. Oil Sands aka “Tar Sands” What are they? Where are they found? How are they extracted?

Investigation of Oil-Mineral Aggregates Formation and the Effect of Minerals Haiping Zhang a, Ying Zheng a *, Kenneth Lee b, Zhengkai Li b, Joseph V Mullin.

Fossil Fuels Chapter 19.

Prediction of wettability variation and its impact on flow using pore- to reservoir-scale simulations Matthew Jackson, Per Valvatne and Martin Blunt Centre.

Laboratory Determination of Fluid Saturations

Hyperbolic Solar Collector

Oil Shale Sub-economic Resource. Oil shale  a sedimentary rock containing an organic material called kerogen.  Kerogen is a solid in the rocks.  Where.

Petroleum in context Petrolm in context University of Georgia Department of Geology GEOL 4320/6320 Petroleum Geology.

Petroleum in context Petrolm in context University of Georgia Department of Geology GEOL 4320/6320 Petroleum Geology.

Coal Formation.

Content Standard 2 Define mass, volume, and density. Define mass as the amount of matter in an object. Define volume as the amount of space an object.

Research Institute of Petroleum Industry

Ashley Finan, 2006 Page 1 Nuclear Energy and Oil Sands? Ashley Finan Massachusetts Institute of Technology Department of Nuclear Science & Engineering.

Electrical Properties Effect of Clays Effect of Wettability.

Civil Engineering Department College of Engineering Course: Soil and Rock Mechanics (CE 260) Lecturer: Dr. Frederick Owusu-Nimo.

Material Processing of Polystyrene Boron Nitride Nanocomposites Raed Ayoob Supervisor(s): Thomas Andritsch and Alun Vaughan 16 September 2015 Early Career.

Gradek Energy. Process for hydrocarbon decontamination of soils n No Chemicals n No Bacteria n Homogeneous residuals n Rapid intervention n Immediate.

Objective  To develop methods for analysis of compounds in organic aerosol particles Why is this important?  Environmental impact  Alternative fuels.

Heavy Oils By: Rebecca Mowbray Molly Riddles & Kate Sweeney.

Capillary Electrophoresis on Unconventional Fluids Presented By Yafei Liu.

SIBERIAN FEDERAL UNIVERSITY

Nathalya Ramirez1, Zach McNulty2, Michael Orrill3, Saniya Leblanc3

Thermal and thermo-chemical methods of heavy oil recovery

Nanoparticle-stabilized emulsions for improved oil recovery Steven Bryant, The University of Texas at Austin Nanoparticles with appropriate coatings can.

Effects of Air Pressure and Wettability on Drop Impact on Dry Surfaces Taehun Lee, Department of Mechanical Engineering, City University of New York,

Date of download: 11/15/2017 Copyright © ASME. All rights reserved.

on Petroleum and Refinery

Refinery: Separation units

DJR 3000 S1 Emulsion Stabilizer CUSTOMER OBJECTIVES: Provide quality products that help protect the environment Stress service to the customer.

D.B.E.B. Indian Institute of Technology-Delhi

Changing the structure of resin-asphaltenes molecules in cracking

Fig. 1 ATR-FTIR spectra of LO ionomer and liquid ZnPa.

Heavy Oil Recovery Techniques

Seed Germination Biology I.

Presentation transcript:

Comparison of all produced oil samples ANALYSIS OF ASPHALTENES- A MAJOR FACTOR BEHIND EMULSIONS- IN PRODUCED OIL AND SPENT ROCK FOR SAGD AND ES-SAGD Taniya Kar, Matthew Williamson, and Berna Hascakir Petroleum Engineering Department, Texas A&M University STATEMENT OF THE PROBLEM SAGD proved to be efficient for oil sand extraction. ES-SAGD proved to have much less environmental impact, energy consumption, and better recovery than SAGD. Oil-in-water emulsions Water-in-oil emulsions Role of asphaltenes in emulsion formation. Comparison of SAGD and SAGD with solvents in terms of produced emulsions. MATERIALS METHODS AND SAMPLES COLLECTED FROM THE EXPERIMENTS CONDUCTED PREVIOUSLY SAGD & ES-SAGD EXPERIMENTS CONDUCTED PREVIOUSLY - Base SAGD - SAGD with n-hexane - SAGD with co-injection of n- hexane and toluene - Produced Oil - Produced Water - Spent Rock Microscope Contact Angle Zeta Potential FTIR SARA EXPERIMENTAL RESULTS A) PRODUCED OIL ANALYSIS B) SPENT ROCK ANALYSIS Bitumen Characterization Microscopic image Parameter, UnitValue 23 o C54,000 Gravity, o 23 o C8.65 Asphaltene Content, wt%34.3 Zeta Potential for Asphaltenes of original bitumen, mV Contains six vol% water Base SAGD (Sample1) SAGD with nC6 (Sample 2) SAGD with nC6 + tolueneExperimentNames Microscopic Images Water-in-oil emulsion Oil-in-water-in-oil emulsion (triple emulsion) Sample Name Asphaltene Content, wt% Zeta Potential, mV Original Bitumen Sample Sample Sample (Sample 3) The greatest asphaltene content was observed for the produced oil sample originated from SAGD (Sample1) O-H stretch prominent for SAGD Base SAGD High amount of asphaltenes More oil-wet asphaltenes (zeta potential value) Detection of water in FTIR spectrum. Both Water-in-oil & oil-in-water-in-oil emulsions SAGD SAGD with nC6SAGD with nC6+toluene Original sample before experiment Intermediate wet ̊ ̊ More oil-wet Inside SC ̊ Intermediate wet Outside SC Original sample before experiment ̊ Intermediate wet ̊ Intermediate wet ̊ More oil-wet Outside SC Inside SC ̊ Intermediate wet Original sample before experiment ̊ Intermediate wet ̊ More oil-wet Outside SC Inside SC Sample Name Asphaltene Content, wt%Residual Oil, wt% Inside Steam Chamber Outside Steam Chamber Inside Steam Chamber Outside Steam Chamber Sample Sample Sample SIGNIFICANCE Base SAGD: High amount and more oil-wet asphaltenes in produced oil → Problems upstream (emulsion, precipitation) High residual oil and asphaltenes on spent rock → Problems downstream (reduced porosity, precipitation) SAGD with solvents promising to reduce the emulsion formation with the generation of more stable asphaltenes. Higher residual oil → higher contact angle (more oil wet nature) clay oil Clay and impurities Original sample before experiment Inside Steam Chamber Outside Steam Chamber clay oil Clay and impurities clay oil Clay and impurities Comparison of all spent rock samples with FTIR Spectrum O-H stretch missing in this region → no significant presence of water in spent rock → supports the oil-wet nature