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Dynamic Viscosity in Laminar Flow Formulas

The Dynamic Viscosity refers to the internal resistance of a fluid to flow when a force is applied. And is denoted by μ. Dynamic Viscosity is usually measured using the Poise for Dynamic Viscosity. Note that the value of Dynamic Viscosity is always positive.

Formulas to find Dynamic Viscosity in Laminar Flow

fxDynamic Viscosity given Velocity Gradient with Shear Stress​Go
fxDynamic Viscosity given Flow Velocity of Stream​Go
fxDynamic Viscosity given Pressure Gradient at Cylindrical Element​Go
fxDynamic Viscosity given Velocity at any point in Cylindrical Element​Go
fxDynamic Viscosity given Maximum Velocity at Axis of Cylindrical Element​Go
fxDynamic Viscosity for Discharge through Pipe​Go
fxDynamic Viscosity using Velocity Distribution Profile​Go
fxDynamic Viscosity given Maximum Velocity between Plates​Go
fxDynamic Viscosity given Mean Velocity of Flow with Pressure Gradient​Go
fxDynamic Viscosity given Pressure Difference​Go
fxDynamic Viscosity given Flow Velocity​Go
fxDynamic Viscosity given Stress​Go
fxDynamic Viscosity given Mean Velocity of Flow in Section​Go
fxDynamic Viscosity given Discharge per Unit Channel Width​Go
fxDynamic Viscosity given Pressure Gradient​Go
fxDynamic Viscosity of fluid given Resistance Force on Spherical Surface​Go
fxDynamic Viscosity of fluid given Terminal Fall Velocity​Go
fxDynamic Viscosity given Velocity of Fluid​Go
fxDynamic Viscosity for Pressure Drop over Length​Go
fxDynamic Viscosity given Shear Stress in Piston​Go
fxDynamic Viscosity given velocity of piston​Go
fxDynamic Viscosity for Total Force in piston​Go
fxDynamic Viscosity given Velocity of Flow in Oil Tank​Go
fxDynamic Viscosity given Rate of Flow​Go
fxDynamic Viscosity for Pressure Reduction over Length of Piston​Go
fxDynamic Viscosity for Shear Force Resisting Motion of Piston​Go
fxDynamic Viscosity of Fluid Flow given Torque​Go
fxDynamic Viscosity given Torque exerted on Outer Cylinder​Go
fxDynamic Viscosity given Total Torque​Go
fxDynamic Viscosity of Fluids in Flow​Go
fxDynamic Viscosity given Velocity​Go
fxDynamic Viscosity given Friction Factor​Go
fxDynamic Viscosity given Pressure Drop over Length of Pipe​Go
fxDynamic Viscosity given Pressure Drop over Length of Pipe with Discharge​Go
fxDynamic Viscosity given Head Loss over Length of Pipe​Go
fxDynamic Viscosity given Head Loss over Length of Pipe with Discharge​Go

Laminar Flow formulas that make use of Dynamic Viscosity

fxVelocity Gradient given Pressure Gradient at Cylindrical Element​Go
fxDistance of Element from Center Line given Velocity Gradient at Cylindrical Element​Go
fxVelocity at any point in Cylindrical Element​Go
fxDistance of Element from Center Line given Velocity at any point in Cylindrical Element​Go
fxDischarge through Pipe given Pressure Gradient​Go
fxVelocity Gradient given Piezometric Gradient with Shear Stress​Go
fxPiezometric Gradient given Velocity Gradient with Shear Stress​Go
fxSpecific Weight of Liquid given Velocity Gradient with Shear Stress​Go
fxRadius of Elemental Section of Pipe given Velocity Gradient with Shear Stress​Go
fxFlow Velocity of Stream​Go
fxSpecific Weight of Liquid given Flow Velocity of Stream​Go
fxPiezometric Gradient given Flow Velocity of Stream​Go
fxRadius of Elemental Section of Pipe given Flow Velocity of Stream​Go
fxRadius of Pipe for Flow Velocity of Stream​Go
fxRadius of Pipe given Velocity at any Point in Cylindrical Element​Go
fxRadius of Pipe for Maximum Velocity at Axis of Cylindrical Element​Go
fxRadius of Pipe given Discharge through Pipe​Go
fxRadius of Pipe for Mean Velocity of Flow​Go
fxPressure Gradient given Velocity Gradient at Cylindrical Element​Go
fxPressure Gradient given Velocity at any point in Cylindrical Element​Go
fxPressure Gradient given Maximum Velocity at Axis of Cylindrical Element​Go
fxPressure Gradient given Discharge through Pipe​Go
fxPressure Gradients given Mean Velocity of Flow​Go
fxVelocity Distribution Profile​Go
fxDistance between Plates using Velocity Distribution Profile​Go
fxMaximum Velocity between Plates​Go
fxDistance between Plates given Maximum Velocity between Plates​Go
fxDischarge given Viscosity​Go
fxDistance between Plates given Discharge​Go
fxDistance between Plates given Mean Velocity of Flow with Pressure Gradient​Go
fxPressure Difference​Go
fxDistance between Plates given Pressure Difference​Go
fxLength of Pipe given Pressure Difference​Go
fxPressure Head Drop​Go
fxDistance between Plates given Pressure Head Drop​Go
fxLength of Pipe given Pressure Head Drop​Go
fxPressure Gradient given Maximum Velocity between Plates​Go
fxMean Velocity of Flow given Pressure Gradient​Go
fxMean Velocity of Flow given Pressure Difference​Go
fxMean Velocity of Flow given Pressure Head Drop​Go
fxFlow Velocity of Section​Go
fxMean Velocity of Flow given Flow Velocity​Go
fxPressure Gradient given Flow Velocity​Go
fxShear Stress given Velocity​Go
fxMean Velocity of Flow given Shear Stress​Go
fxPressure Gradient given Shear Stress​Go
fxMean Velocity of Flow in Section​Go
fxSlope of Channel given Mean Velocity of Flow​Go
fxDiameter of Section given Mean Velocity of Flow​Go
fxDischarge per unit channel width​Go
fxDiameter of Section given Discharge per Unit Channel Width​Go
fxSlope of Channel given Discharge per Unit Channel Width​Go
fxPotential Head Drop​Go
fxDiameter of Section given Potential Head Drop​Go
fxLength of Pipe given Potential Head Drop​Go
fxPressure Gradient​Go
fxRate of Flow given Pressure Gradient​Go
fxResistance Force on Spherical Surface​Go
fxDiameter of Sphere given Resistance Force on Spherical Surface​Go
fxVelocity of Sphere given Resistance Force on Spherical Surface​Go
fxTerminal Fall Velocity​Go
fxDiameter of Sphere for given Fall Velocity​Go
fxCoefficient of Drag given density​Go
fxVelocity of Sphere given Coefficient of Drag​Go
fxDiameter of Sphere given Coefficient of Drag​Go
fxVelocity of Flow in Oil Tank​Go
fxPressure Gradient given Velocity of Flow in Oil Tank​Go
fxPressure Gradient given Rate of Flow​Go
fxPressure Drop over Piston​Go
fxLength of Piston for Pressure Drop over Piston​Go
fxVertical Upward Force on Piston given Piston Velocity​Go
fxLength of Piston for Vertical Upward Force on Piston​Go
fxShear Force Resisting Motion of Piston​Go
fxLength of Piston for Shear Force Resisting Motion of Piston​Go
fxVelocity of Fluid​Go
fxPressure Gradient given Velocity of Fluid​Go
fxPressure Drop over Lengths of Piston​Go
fxVelocity of Piston for Pressure reduction over Length of Piston​Go
fxLength of Piston for Pressure Reduction over Length of Piston​Go
fxDiameter of Piston for Pressure Drop over Length​Go
fxClearance given Pressure Drop over Length of Piston​Go
fxVelocity of Piston given Shear Stress​Go
fxDiameter of Piston given Shear Stress​Go
fxClearance given Shear Stress​Go
fxLength of Piston for Total Force in Piston​Go
fxVelocity of Piston given Velocity of Flow in Oil Tank​Go
fxVelocity of Pistons for Pressure Drop over Length of Piston​Go
fxVelocity of Piston for Vertical Upward Force on Piston​Go
fxVelocity of Piston for Shear Force Resisting Motion of Piston​Go
fxTorque exerted on Inner Cylinder given Dynamic Viscosity of Fluid​Go
fxHeight of Cylinder given Dynamic Viscosity of Fluid​Go
fxSpeed of Outer Cylinder given Dynamic Viscosity of Fluid​Go
fxTorque Exerted on Outer Cylinder​Go
fxClearance given Torque exerted on Outer Cylinder​Go
fxSpeed of Outer Cylinder given Torque exerted on Outer Cylinder​Go
fxRadius of Inner Cylinder given Torque exerted on Outer Cylinder​Go
fxTotal Torque​Go
fxSpeed of Outer Cylinder given Total Torque​Go
fxCross-Sectional Area of Tube using Dynamic Viscosity​Go
fxDiameter of Pipe using Dynamic Viscosity with Time​Go
fxLength of Reservoir using Dynamic Viscosity​Go
fxDiameter of Pipe given Dynamic Viscosity with Length​Go
fxMean Velocity of Sphere given Dynamic Viscosity​Go
fxDensity of Fluid given Friction Factor​Go
fxDiameter of Pipe given Friction Factor​Go
fxFriction Factor​Go
fxMean Velocity of Fluid Flow​Go
fxMean Velocity of Flow given Friction Factor​Go
fxPressure drop over length of pipe​Go
fxMean Velocity of Flow given Pressure Drop over Length of Pipe​Go
fxDiameter of Pipe given Pressure Drop over Length of Pipe​Go
fxLength of Pipe given Pressure Drop over Length of Pipe​Go
fxPressure Drop over Length of Pipe given Discharge​Go
fxDiameter of Pipe given Pressure Drop over Length of Pipe with Discharge​Go
fxLength of Pipe given Pressure Drop over Length of Pipe with Discharge​Go
fxDischarge given Pressure Drop over Length of Pipe​Go
fxHead Loss over Length of Pipe​Go
fxMean Velocity of Flow given Head Loss over Length of Pipe​Go
fxDiameter of Pipe given Head Loss over Length of Pipe​Go
fxLength of Pipe given Head Loss over Length of Pipe​Go
fxSpecific Weight of Liquid given Head Loss over Length of Pipe​Go
fxHead Loss over Length of Pipe given Discharge​Go
fxLength of Pipe given Head Loss over Length of Pipe with Discharge​Go
fxDiameter of Pipe given Head Loss over Length of Pipe with Discharge​Go

List of variables in Laminar Flow formulas

fx Specific Weight of Liquid ​Go
fx Velocity Gradient ​Go
fx Piezometric Gradient ​Go
fx Radial Distance ​Go
fx Velocity of Liquid ​Go
fx Inclined Pipes Radius ​Go
fx Pressure Gradient ​Go
fx Fluid Velocity ​Go
fx Radius of pipe ​Go
fx Maximum Velocity ​Go
fx Discharge in Pipe ​Go
fx Width ​Go
fx Horizontal Distance ​Go
fx Mean Velocity ​Go
fx Pressure Difference ​Go
fx Length of Pipe ​Go
fx Distance between plates ​Go
fx Flow velocity ​Go
fx Shear Stress ​Go
fx Diameter of Section ​Go
fx Slope of Bed ​Go
fx Kinematic Viscosity ​Go
fx Height of Channel ​Go
fx Resistance Force ​Go
fx Diameter of Sphere ​Go
fx Terminal Velocity ​Go
fx Specific Weight of Liquid in Piezometer ​Go
fx Hydraulic Clearance ​Go
fx Pressure Drop due to Friction ​Go
fx Velocity of Piston ​Go
fx Piston Length ​Go
fx Radial Clearance ​Go
fx Diameter of Piston ​Go
fx Total Force in Piston ​Go
fx Fluid Velocity in Oil Tank ​Go
fx Discharge in Laminar Flow ​Go
fx Shear Force ​Go
fx Torque on Inner Cylinder ​Go
fx Radius of Outer Cylinder ​Go
fx Radius of Inner Cylinder ​Go
fx Height of Cylinder ​Go
fx Angular Speed ​Go
fx Torque on Outer Cylinder ​Go
fx Clearance ​Go
fx Total Torque ​Go
fx Viscometer Constant ​Go
fx Time in Seconds ​Go
fx Cross Sectional Area of Pipe ​Go
fx Diameter of Pipe ​Go
fx Average Reservoir Area ​Go
fx Height of Column 1 ​Go
fx Height of Column 2 ​Go
fx Darcy Friction Factor ​Go
fx Density of Fluid ​Go
fx Head Loss due to Friction ​Go

FAQ

What is the Dynamic Viscosity?
The Dynamic Viscosity refers to the internal resistance of a fluid to flow when a force is applied. Dynamic Viscosity is usually measured using the Poise for Dynamic Viscosity. Note that the value of Dynamic Viscosity is always positive.
Can the Dynamic Viscosity be negative?
No, the Dynamic Viscosity, measured in Dynamic Viscosity cannot be negative.
What unit is used to measure Dynamic Viscosity?
Dynamic Viscosity is usually measured using the Poise[P] for Dynamic Viscosity. Pascal Second[P], Newton Second per Square Meter[P], Millinewton Second per Square Meter[P] are the few other units in which Dynamic Viscosity can be measured.
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