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Properties of Oilfield Waters Lectures # 30 – 31 PETE 310.

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Presentation on theme: "Properties of Oilfield Waters Lectures # 30 – 31 PETE 310."— Presentation transcript:

1 Properties of Oilfield Waters Lectures # 30 – 31 PETE 310

2 Topics Brine composition and density Water (brine) compressibility Formation volume factor and Pb Viscosity Mutual solubilities (gas in water, water in gas)

3 Water Production Issues Oil and gas wells produce more water than oil (7 bbl/1 bbl oil in Texas) Composition of co-produced water determines need for anti-scaling additives Regulations limit disposal and beneficial use options Environmental impact

4 Oilfield Water Issues Expensive Oilfield Water Management Diversity of Oilfield Waters (amount, compositions) Corrosion, Scale Control and Plugging Microbiological Problems Water Quality for Water-flooding, Steam Injection or Surface Disposal Injectivity Decline in Water Injection Wells

5 Dissolved Solids in Brines Cations  Na +  K +  Li +  Ca ++  Mg ++  Ba ++  Fe ++  Sr ++ Anions  Cl -  SO 4 =  CO 3 =  CO 3 H -  NO 3 -  Br -  I - NaCl S A L T S

6 Total Dissolved Solids (TDS)

7 Measures of Solids Concentration  w is brine density which depends upon solids in solution

8 Stiff Diagrams Milliequivalents per liter

9 Typical Concentrations TDS = 68,030 ppm  6.8%  get  w  convert to mg/l

10 Periodic Table Info for each element here! http://pearl1.lanl.gov/periodic/default.htmMore information here

11 Conversions: mg per liter  milliequivalents per liter See examples in text

12 Conversions: mg per liter  milliequivalents per liter Valence is # of charges (+ or -). Expressed as equivalent wt per g mole  Ca ++ has ionic weight of 40.08 g/g mole  Equivalent weight is 40.08 g/g mole/2 eq wt/g mole = 20.4 g/eq wt Atomic weight divided equivalent weight is mg / meq Milliequivalents per liter of calcium are  *** mg/l / 20.04 mg/meq = ***

13 Bubble Point Pressure of Oilfield Water Pb is the same as the Pb of the coexisting oil due to thermodynamic equilibrium

14 Formation Volume Factor (B w ) Depends upon pressure Depends upon temperature Depends upon gas in solution Offsetting – negligible effect -

15 Formation Volume Factor of Water (B w ) Works well even for brines up to 30% TDS

16 Temperature Correction +

17 Pressure Correction -

18 Effect of TDS on Brine Density

19 Solubility of Hydrocarbons in Water

20 Solubility of Methane in Water

21 Effect of Salinity on solubility of gas in water

22 Coefficient of Isothermal Compressibility (C w )

23 Viscosity of Water versus Pressure At a fixed T

24 Water (Brine) Viscosity versus TDS At atmospheric pressure Increasing TDS

25 Viscosity of Water at Reservoir Pressure

26 Solubility of Water in Natural Gas (low pressure) Lb of water / MMSCF

27 Solubility of Water in Gas (high P) Lb of water / MMSCF To evaluate dehydration requirements (equipment, chemicals) In natural gas processing

28 Resistivity of Oilfield Water Use in logging tools Formation evaluation Resistivity is inversely proportional to conductivity R w = rA/L = [ohm/meters]

29 Calculate Resistivity or TDS

30 Gas-Water IFT

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