Fundamental Reservoir Fluid Behaviour
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Transcript of Fundamental Reservoir Fluid Behaviour
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FUNDAMENTAL RESERVOIR FLUID PROPERTIES
Ekeh Modesty KelechukwuDept. of Chemical & Petroleum Engineering
UCSI University56000 Cheras , Kuala Lumpur
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Syllabus
Fundamental of Reservoir Fluid Behaviours
Sampling and analysis of reservoir fluids Basic classification of hydrocarbons Hydrocarbon phase behaviours (single, double, multi- components) Classification of reservoir fluids Gas properties Liquid properties Formation water properties
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Typical Reservoir
Gas
Oil
water
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Hydrocarbon Reservoir
Fluids: oil, gas and water
Reservoir fluid must flow to the surface for marketable oil and gas
Typical Flow
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Hydrocarbon Reserves
Np A h Sw Swi 1
B oi
1
Bo
Gp A h 1 Swi Bgi Bg
1
gi g
1 1
B B
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Oil or Gas or Mixture of Both
Pre
ssur
e
Temperature
oil
gas
Oil + Gas
Bubble point
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Fluid flow in reservoir
qw kw A
p
L
qo ko A
p
L
qg kg A
p
L
Saturated with oil, gas and water
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Recovery optimization
separator
Oil reservoir
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Sampling and analysis of reservoir fluids
separator surface sampling
bottomhole sampling
PVT analysis
Sampling Methods:
Analysis Methods:
To obtain good equilibrium and representative reservoir fluid sample. Temperature and pressure changes influence equilibrium composition of the gas and liquid phases.
HPHT Compositional analysis up to C70 Constant composition expension Viscosity Differential liberation Compressibility
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General properties of hydrocarbon fluids
Formation volume factor, Bg, Bo, Bw: volres/volsc
Density, specific gravity
Isothermal Compressibility
Viscosity
Solution Gas-Oil Ratio
Ideal gas law: pV = nRT
Real gas law: pV = znRT
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Typical composition of Petroleum Gases
Natural Gas
Hydrocarbons
Methane 70-98%Ethane 1-10%Propane trace - 5%Butane trace - 2%Pentane trace - 1%Hexane trace - 0.5%Heptane+ trace - 0.5%
Non-hydrocarbons
Nitrogen trace - 15%Carbon dioxide trace - 5%Hydrogen Sulfide trace - 3%Helium up to 5%, normally traces or none
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Gas from Oil Well
Hydrocarbons
Methane 45-92%Ethane 4-21%Propane 1 - 15%Butane 0.5 - 7%Pentane v. little - 3%Hexane v. little - 2%Heptane+ v. little - 1.5%
Non-hydrocarbons
Nitrogen v. little – up to 10%Carbon dioxide v. little - 4%Hydrogen Sulfide v. little - 6%Helium none
Typical composition of Petroleum Gases
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Crude oil fractions Boiling Chemical Point, oF Composition Usages
Gas hydrocarbon C1 – C2 Fuel gas up to 100 C3 – C6 Bottled fuel gas, solvent
Gasoline 100 – 500 C5 – C10 Motor fuel, solvent
Kerosene 350 – 480 C11 – C13 Jet fuel, cracking stock
Light Gas Oil 450 – 480 C13 – C17 Diesel fuel, furnace fuel
Heavy Gas Oil 580 – 750 C18 – C25 Lubricating oil, bunker fuel
Lubricant and Wax 750 – 950 C26 – C38 Lubricating oil, paraffin wax, petroleum jelly
Residual Oil 950+ C38+ Tar, roof compound, asphalt, coke
Typical Crude Oil Fractions
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Typical composition analysis of crude oils
Carbon 84 - 87%
Hydrogen 11 - 14%
Sulfur 0.06 – 2%
Nitrogen 0.1 – 2%
Oxygen 0.1 – 2%
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Basic classification of hydrocarbons
Hydrocarbon Homolog Series
Hydrocarbons
Alkenes-unsaturated H-olefin: 1 double bond-diolefin: 2 double bonds
Alkanes (paraffin)-saturated H
Aliphatic
Alkynes (acetylene)-unsaturated H-triple bonds
Cyclic aliphaticNaphthalene
Aromatics(Benzene)
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Compounds in Crude Oil (South Ponca Field, Oklahoma)
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Alkanes, CnH2n+2
1 Methane2 Ethane3 Propane4 Butane5 Pentane6 Hexane7 Heptane8 Octane9 Nonane10 Decane20 Eicosane30 Triacontane
No. of Carbon Name
Covalent bond: sharing electrons Isomerism - same molecular formula but different structure, different physical and chemical properties Prefix isomers – n-, iso-, neo-, etc.
Heptane C5 H12
n-heptane iso-heptane neo-heptane
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Alkanes, CnH2n+2
Alkane FormulaBoiling point [°C]
Melting point [°C]
Density [g·cm3] (at 20°C)
Methane CH4 -162 -183 gas
Ethane C2H6 -89 -172 gas
Propane C3H8 -42 -188 gas
Butane C4H10 0 -138 gas
Pentane C5H12 36 -130 0.626(liquid)
Hexane C6H14 69 -95 0.659(liquid)
Heptane C7H16 98 -91 0.684(liquid)
Octane C8H18 126 -57 0.703(liquid)
Nonane C9H20 151 -54 0.718(liquid)
Decane C10H22 174 -30 0.730(liquid)
Undecane C11H24 196 -26 0.740(liquid)
Dodecane C12H26 216 -10 0.749(liquid)
Icosane C20H42 343 37 solid
Triacontane C30H62 450 66 solid
Tetracontane C40H82 525 82 solid
Pentacontane C50H102 575 91 solid
Physical properties:
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Nomenclature of Alkanes
Based on IUPAC (International Union of Pure and Applied Chemistry) rules:
Alkyl groups (missing one hydrocarbon atom): methyl group, ethyl group, prophyl group
The largest continuous chain of carbon atoms is taken as the framework on which the various alkyl groups are considered to be substituted. Thus the following hydrocarbon is a pentane.
The parent hydrocarbon is then numbered starting from the end of the chain and the substituent groups are assigned numbers corresponding to their positions on the chain. The direction of numbering is chosen to give the lowest sum for the numbers of the side chain substituents. Thus, thehydrocarbon is 2,3-dimethylpentane. .
These rules are as follows:
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Nomenclature of Alkanes
Where there are two identical substituents in one position as in the compound below numbers are supplied for each.
Branched-chain substituent groups are given appropriate names by a simple extension of the system used for branched chain hydrocarbons. The longest chain of the substituent is numbered starting with the carbon attached directly to the parent hydrocarbon chain. Parentheses are used to separate the numbering of the substituent and the main hydrocarbon chain.
When there are two or more different substituents present, the common method is to list the substituents in alphabetical order, although the substituents are sometimes listed in order of increasing complexity.