Calculate dynamic and kinematic viscosity for two phase gas liquids (gas and oil or gas and liquid).
Kinematic viscosity is equal to the dynamic viscosity divided by the density of the fluid. The viscosity of two phase fluids and mixtures can be calculated from the dynamic viscosity and the volume fraction. The gas oil ratio is the ratio of gas moles to oil volume. It is often measured as gas standard volume (scf or scm) per oil volume (barrels, gallons, cubic feet or cubic meters).
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CALCULATOR : Two Phase Gas Liquid Viscosity [FREE] ±
Calculate fluid viscosity for single phase fluid, single phase gas, and two phase gas liquid. The viscosity of two phase fluids can be calculated from the gas and liquid dynamic viscosity using the volume average viscosity. The fluid density can either be calculated, or user defined. Tool Input- mvtype : Fluid Density Type
- GORu : User Defined Gas Oil Ratio
- Xmu : User Defined Gas Mass Fraction
- Xvu : User Defined Gas Volume Fraction
- ρu : User Defined Fluid Density
- visctype : Viscosity Type
- μu : User Defined Dynamic Viscosity
- νu : User Defined Kinematic Viscosity
- μl : Liquid Dynamic Viscosity
- μg : Gas Dynamic Viscosity
- ρl : Liquid Density
- P : Fluid Pressure
- T : Fluid Temperature
- Z : Gas Compressibility Factor
- SG : Gas Specific Gravity
Tool Output- μf : Fluid Dynamic Viscosity
- νf : Fluid Kinematic Viscosity
- ρf : Average Fluid Density
- ρg : Gas Density
- GOR : Gas Oil Ratio
- Xm : Gas Mass Fraction
- Xv : Gas Volume Fraction
- vg : Gas Mole Specific Volume
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CALCULATOR : Two Phase Gas Liquid Pipeline Fluid Viscosity And Volume [PLUS] ±
Calculate pipeline fluid viscosity, density, mass and volume for single phase fluid, single phase gas, and two phase gas liquid. The fluid viscosity, volume and density can either be calculated or user defined. For two phase fluids the viscosity is calculated from the dynamic viscosity of the gas and liquid phases using the volume average viscosity. Tool Input- schdtype : Pipe Schedule Type
- diamtype : Pipe Diameter Type
- ODu : User Defined Outside Diameter
- IDu : User Defined Inside Diameter
- wtntype : Wall Thickness Type
- tnu : User Defined Wall Thickness
- mvtype : Fluid Density Type
- GORu : User Defined Gas Oil Ratio
- Xmu : User Defined Gas Mass Fraction
- Xvu : User Defined Gas Volume Fraction
- ρu : User Defined Fluid Density
- voltype : Fluid Volume Type
- Vlu : User Defined Liquid Volume
- Ngu : User Defined Gas Moles
- Vfu : User Defined Total Fluid Volume
- Mfu : User Defined Total Fluid Mass
- Lu : User Defined Pipeline Length
- visctype : Viscosity Type
- μu : User Defined Dynamic Viscosity
- νu : User Defined Kinematic Viscosity
- μl : Liquid Dynamic Viscosity
- μg : Gas Dynamic Viscosity
- ρl : Liquid Density
- P : Fluid Pressure
- T : Fluid Temperature
- Z : Gas Compressibility Factor
- SG : Gas Speciffic Gravity
Tool Output- μf : Fluid Dynamic Viscosity
- νf : Fluid Kinematic Viscosity
- ρf : Average Fluid Density
- ρg : Gas Density (At T P)
- GOR : Gas Oil Ratio
- ID : Inside Diameter
- L : Pipe Length
- Mf : Total Mass
- Mg : Gas Mass
- Ml : Liquid Mass
- Ng : Gas Moles
- Vf : Total Fluid Volume
- Vg : Gas Volume
- Vl : Liquid Volume
- Xm : Gas Mass Fraction
- Xv : Gas Volume Fraction (At T P)
- vg : Gas Mole Volume (At T P)
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CALCULATOR : Two Phase Gas Liquid Pipeline Fluid Viscosity And Flow Rate [PLUS] ±
Calculate pipeline fluid viscosity, density and flow rate for single phase fluid, single phase gas, and two phase gas liquid. The fluid viscosity, density and flowrate can either be calculated, or user defined. The viscosity of two phase fluids is calculated from the dynamic viscosity using the volume average viscosity of the liquid and gas phases. Tool Input- schdtype : Pipe Schedule Type
- diamtype : Pipe Diameter Type
- ODu : User Defined Outside Diameter
- IDu : User Defined Inside Diameter
- wtntype : Wall Thickness Type
- tnu : User Defined Wall Thickness
- mvtype : Fluid Density Type
- GORu : User Defined Gas Oil Ratio
- Xmu : User Defined Gas Mass Fraction
- Xvu : User Defined Gas Volume Fraction
- ρu : User Defined Fluid Density
- voltype : Fluid Flow Rate Type
- Qlu : User Defined Liquid Volume Flow Rate
- Ngu : User Defined Gas Mole Flow Rate
- Qfu : User Defined Total Fluid Volume Flow Rate
- Mfu : User Defined Total Fluid Mass Flow Rate
- Vfu : User Defined Fluid Velocity
- Reu : User Defined Reynolds Number
- visctype : Viscosity Type
- μu : User Defined Dynamic Viscosity
- νu : User Defined Kinematic Viscosity
- μl : Liquid Dynamic Viscosity
- μg : Gas Dynamic Viscosity
- ρl : Liquid Density
- P : Fluid Pressure
- T : Fluid Temperature
- Z : Gas Compressibility Factor
- SG : Gas Specific Gravity
Tool Output- μf : Fluid Dynamic Viscosity
- νf : Fluid Kinematic Viscosity
- ρf : Average Fluid Density
- ρg : Gas Density (At T P)
- GOR : Gas Oil Ratio
- ID : Inside Diameter
- Mf : Total Mass Flowrate
- Mg : Gas Mass Flowrate
- Ml : Liquid Mass Flowrate
- Ng : Gas Mole Flowrate
- Qf : Total Volume Flowrate
- Qg : Gas Volume Flowrate
- Ql : Liquid Volume Flowrate
- Re : Reynolds Number
- Vf : Total Fluid Velocity
- Vg : Superficial Gas Velocity
- Vl : Superficial Liquid Velocity
- Xm : Gas Mass Fraction
- Xv : Gas Volume Fraction (At T P)
- vg : Gas Mole Volume (At T P)
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CALCULATOR : Gas Density And Compressibility Factor [FREE] ±
Calculate single phase gas compressibility factor and density from gas temperature and pressure for selected gases. The gas compressibility factor is calculated from the critical point temperature, critical point temperature, and the accentric factor using either the Peng Robinson, Soave, Redlich Kwong or Van Der Waals equations of state (EOS). The compressibility factor calculation is valid for gas phase only. Use the Result Plot option to plot compressibility factor versus pressure and temperature, compressibility factor versus pressure and equation of state type, or compressibility factor versus temperature and equation of state type. Tool Input- fluidtype : Fluid Type
- SGu : User Defined Gas Specific Gravity
- ωu : User Defined Acentric Factor
- Pcu : User Defined Critical Pressure
- Tcu : User Defined Critical Temperature
- eostype : Equation Of State
- Zu : User Defined Compressibility Factor
- P : Fluid Pressure
- T : Fluid Temperature
Tool Output- ρ : Fluid Density
- ω : Accentric Factor
- Pc : Critical Point Pressure
- Pr : Reduced Pressure
- SG : Gas Specific Gravity Relative To Air
- Tc : Critical Point Temperature
- Tr : Reduced Temperature
- Vm : Molar Volume
- Z : Compressibility Factor
- cvg : Convergence Check
- mw : Fluid Molar Mass
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CALCULATOR : Pipe Inside Diameter And Cross Section Area [FREE] ±
Calculate pipe inside diameter and inside cross section area from pipe diameter and wall thickness. Use the Result Table option to display a table of the inside diameter and cross section area versus either outside diameter or wall thickness. Tool Input- schdtype : Schedule Type
- diamtype : Diameter Type
- ODu : User Defined Outside Diameter
- IDu : User Defined Inside Diameter
- wtntype : Wall Thickness Type
- tnu : User Defined Wall Thickness
Tool Output- AX : Pipe Inside Cross Section Area
- ID : Nominal Inside Diameter
- OD : Nominal Outside Diameter
- OD/tn : Diameter Over Wall Thickness Ratio
- tn : Nominal Wall Thickness
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CALCULATOR : Liquid Density [FREE] ±
Calculate single phase liquid density from specific gravity, degrees Baume, degrees Twaddell, or degrees API. For liquids lighter than or equal to water the density can be defined as degrees API, or degrees Baume (Be-). For liquids heavier than water the density can be defined by degrees Baume (Be+), or degrees Twaddell. Tool Input- sgtype : Density Type
- SGu : User Defined Specific Gravity
- Be+u : User Defined Degrees Baume SG > 1
- Be-u : User Defined Degrees Baume SG <= 1
- Twu : User Defined Degrees Twaddell SG > 1
- APIu : User Defined Degrees API SG <= 1
- ρu : User Defined Liquid Density
Tool Output- ρ : Fluid Density
- API : Degrees API SG ≤ 1
- Be+ : Degrees Baume SG > 1
- Be- : Degrees Baume SG ≤ 1
- SG : Specific Gravity
- Tw : Degrees Twaddell SG > 1
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