FormulaDen.com
Physics
Chemistry
Math
Chemical Engineering
Civil
Electrical
Electronics
Electronics and Instrumentation
Materials Science
Mechanical
Production Engineering
Financial
Health
You are here
-
Home
»
Engineering
»
Civil
»
Hydraulics and Waterworks
Dynamic Viscosity in Hydraulics and Waterworks 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 Hydraulics and Waterworks
f
x
Dynamic Viscosity given Velocity Gradient with Shear Stress
Go
f
x
Dynamic Viscosity given Flow Velocity of Stream
Go
f
x
Dynamic Viscosity given Pressure Gradient at Cylindrical Element
Go
f
x
Dynamic Viscosity given Velocity at any point in Cylindrical Element
Go
f
x
Dynamic Viscosity given Maximum Velocity at Axis of Cylindrical Element
Go
f
x
Dynamic Viscosity for Discharge through Pipe
Go
f
x
Dynamic Viscosity using Velocity Distribution Profile
Go
f
x
Dynamic Viscosity given Maximum Velocity between Plates
Go
f
x
Dynamic Viscosity given Mean Velocity of Flow with Pressure Gradient
Go
f
x
Dynamic Viscosity given Pressure Difference
Go
f
x
Dynamic Viscosity given Flow Velocity
Go
f
x
Dynamic Viscosity given Stress
Go
f
x
Dynamic Viscosity given Mean Velocity of Flow in Section
Go
f
x
Dynamic Viscosity given Discharge per Unit Channel Width
Go
f
x
Dynamic Viscosity given Pressure Gradient
Go
f
x
Dynamic Viscosity of fluid given Resistance Force on Spherical Surface
Go
f
x
Dynamic Viscosity of fluid given Terminal Fall Velocity
Go
f
x
Dynamic Viscosity given Velocity of Fluid
Go
f
x
Dynamic Viscosity for Pressure Drop over Length
Go
f
x
Dynamic Viscosity given Shear Stress in Piston
Go
f
x
Dynamic Viscosity given velocity of piston
Go
f
x
Dynamic Viscosity for Total Force in piston
Go
f
x
Dynamic Viscosity given Velocity of Flow in Oil Tank
Go
f
x
Dynamic Viscosity given Rate of Flow
Go
f
x
Dynamic Viscosity for Pressure Reduction over Length of Piston
Go
f
x
Dynamic Viscosity for Shear Force Resisting Motion of Piston
Go
f
x
Dynamic Viscosity of Fluid Flow given Torque
Go
f
x
Dynamic Viscosity given Torque exerted on Outer Cylinder
Go
f
x
Dynamic Viscosity given Total Torque
Go
f
x
Dynamic Viscosity of Fluids in Flow
Go
f
x
Dynamic Viscosity given Velocity
Go
f
x
Dynamic Viscosity given Friction Factor
Go
f
x
Dynamic Viscosity given Pressure Drop over Length of Pipe
Go
f
x
Dynamic Viscosity given Pressure Drop over Length of Pipe with Discharge
Go
f
x
Dynamic Viscosity given Head Loss over Length of Pipe
Go
f
x
Dynamic Viscosity given Head Loss over Length of Pipe with Discharge
Go
Hydraulics and Waterworks formulas that make use of Dynamic Viscosity
f
x
Velocity Gradient given Pressure Gradient at Cylindrical Element
Go
f
x
Distance of Element from Center Line given Velocity Gradient at Cylindrical Element
Go
f
x
Velocity at any point in Cylindrical Element
Go
f
x
Distance of Element from Center Line given Velocity at any point in Cylindrical Element
Go
f
x
Discharge through Pipe given Pressure Gradient
Go
f
x
Velocity Gradient given Piezometric Gradient with Shear Stress
Go
f
x
Piezometric Gradient given Velocity Gradient with Shear Stress
Go
f
x
Specific Weight of Liquid given Velocity Gradient with Shear Stress
Go
f
x
Radius of Elemental Section of Pipe given Velocity Gradient with Shear Stress
Go
f
x
Flow Velocity of Stream
Go
f
x
Specific Weight of Liquid given Flow Velocity of Stream
Go
f
x
Piezometric Gradient given Flow Velocity of Stream
Go
f
x
Radius of Elemental Section of Pipe given Flow Velocity of Stream
Go
f
x
Radius of Pipe for Flow Velocity of Stream
Go
f
x
Radius of Pipe given Velocity at any Point in Cylindrical Element
Go
f
x
Radius of Pipe for Maximum Velocity at Axis of Cylindrical Element
Go
f
x
Radius of Pipe given Discharge through Pipe
Go
f
x
Radius of Pipe for Mean Velocity of Flow
Go
f
x
Pressure Gradient given Velocity Gradient at Cylindrical Element
Go
f
x
Pressure Gradient given Velocity at any point in Cylindrical Element
Go
f
x
Pressure Gradient given Maximum Velocity at Axis of Cylindrical Element
Go
f
x
Pressure Gradient given Discharge through Pipe
Go
f
x
Pressure Gradients given Mean Velocity of Flow
Go
f
x
Velocity Distribution Profile
Go
f
x
Distance between Plates using Velocity Distribution Profile
Go
f
x
Maximum Velocity between Plates
Go
f
x
Distance between Plates given Maximum Velocity between Plates
Go
f
x
Discharge given Viscosity
Go
f
x
Distance between Plates given Discharge
Go
f
x
Distance between Plates given Mean Velocity of Flow with Pressure Gradient
Go
f
x
Pressure Difference
Go
f
x
Distance between Plates given Pressure Difference
Go
f
x
Length of Pipe given Pressure Difference
Go
f
x
Pressure Head Drop
Go
f
x
Distance between Plates given Pressure Head Drop
Go
f
x
Length of Pipe given Pressure Head Drop
Go
f
x
Pressure Gradient given Maximum Velocity between Plates
Go
f
x
Mean Velocity of Flow given Pressure Gradient
Go
f
x
Mean Velocity of Flow given Pressure Difference
Go
f
x
Mean Velocity of Flow given Pressure Head Drop
Go
f
x
Flow Velocity of Section
Go
f
x
Mean Velocity of Flow given Flow Velocity
Go
f
x
Pressure Gradient given Flow Velocity
Go
f
x
Shear Stress given Velocity
Go
f
x
Mean Velocity of Flow given Shear Stress
Go
f
x
Pressure Gradient given Shear Stress
Go
f
x
Mean Velocity of Flow in Section
Go
f
x
Slope of Channel given Mean Velocity of Flow
Go
f
x
Diameter of Section given Mean Velocity of Flow
Go
f
x
Discharge per unit channel width
Go
f
x
Diameter of Section given Discharge per Unit Channel Width
Go
f
x
Slope of Channel given Discharge per Unit Channel Width
Go
f
x
Potential Head Drop
Go
f
x
Diameter of Section given Potential Head Drop
Go
f
x
Length of Pipe given Potential Head Drop
Go
f
x
Pressure Gradient
Go
f
x
Rate of Flow given Pressure Gradient
Go
f
x
Resistance Force on Spherical Surface
Go
f
x
Diameter of Sphere given Resistance Force on Spherical Surface
Go
f
x
Velocity of Sphere given Resistance Force on Spherical Surface
Go
f
x
Terminal Fall Velocity
Go
f
x
Diameter of Sphere for given Fall Velocity
Go
f
x
Coefficient of Drag given density
Go
f
x
Velocity of Sphere given Coefficient of Drag
Go
f
x
Diameter of Sphere given Coefficient of Drag
Go
f
x
Velocity of Flow in Oil Tank
Go
f
x
Pressure Gradient given Velocity of Flow in Oil Tank
Go
f
x
Pressure Gradient given Rate of Flow
Go
f
x
Pressure Drop over Piston
Go
f
x
Length of Piston for Pressure Drop over Piston
Go
f
x
Vertical Upward Force on Piston given Piston Velocity
Go
f
x
Length of Piston for Vertical Upward Force on Piston
Go
f
x
Shear Force Resisting Motion of Piston
Go
f
x
Length of Piston for Shear Force Resisting Motion of Piston
Go
f
x
Velocity of Fluid
Go
f
x
Pressure Gradient given Velocity of Fluid
Go
f
x
Pressure Drop over Lengths of Piston
Go
f
x
Velocity of Piston for Pressure reduction over Length of Piston
Go
f
x
Length of Piston for Pressure Reduction over Length of Piston
Go
f
x
Diameter of Piston for Pressure Drop over Length
Go
f
x
Clearance given Pressure Drop over Length of Piston
Go
f
x
Velocity of Piston given Shear Stress
Go
f
x
Diameter of Piston given Shear Stress
Go
f
x
Clearance given Shear Stress
Go
f
x
Length of Piston for Total Force in Piston
Go
f
x
Velocity of Piston given Velocity of Flow in Oil Tank
Go
f
x
Velocity of Pistons for Pressure Drop over Length of Piston
Go
f
x
Velocity of Piston for Vertical Upward Force on Piston
Go
f
x
Velocity of Piston for Shear Force Resisting Motion of Piston
Go
f
x
Torque exerted on Inner Cylinder given Dynamic Viscosity of Fluid
Go
f
x
Height of Cylinder given Dynamic Viscosity of Fluid
Go
f
x
Speed of Outer Cylinder given Dynamic Viscosity of Fluid
Go
f
x
Torque Exerted on Outer Cylinder
Go
f
x
Clearance given Torque exerted on Outer Cylinder
Go
f
x
Speed of Outer Cylinder given Torque exerted on Outer Cylinder
Go
f
x
Radius of Inner Cylinder given Torque exerted on Outer Cylinder
Go
f
x
Total Torque
Go
f
x
Speed of Outer Cylinder given Total Torque
Go
f
x
Cross-Sectional Area of Tube using Dynamic Viscosity
Go
f
x
Diameter of Pipe using Dynamic Viscosity with Time
Go
f
x
Length of Reservoir using Dynamic Viscosity
Go
f
x
Diameter of Pipe given Dynamic Viscosity with Length
Go
f
x
Mean Velocity of Sphere given Dynamic Viscosity
Go
f
x
Density of Fluid given Friction Factor
Go
f
x
Diameter of Pipe given Friction Factor
Go
f
x
Friction Factor
Go
f
x
Mean Velocity of Fluid Flow
Go
f
x
Mean Velocity of Flow given Friction Factor
Go
f
x
Pressure drop over length of pipe
Go
f
x
Mean Velocity of Flow given Pressure Drop over Length of Pipe
Go
f
x
Diameter of Pipe given Pressure Drop over Length of Pipe
Go
f
x
Length of Pipe given Pressure Drop over Length of Pipe
Go
f
x
Pressure Drop over Length of Pipe given Discharge
Go
f
x
Diameter of Pipe given Pressure Drop over Length of Pipe with Discharge
Go
f
x
Length of Pipe given Pressure Drop over Length of Pipe with Discharge
Go
f
x
Discharge given Pressure Drop over Length of Pipe
Go
f
x
Head Loss over Length of Pipe
Go
f
x
Mean Velocity of Flow given Head Loss over Length of Pipe
Go
f
x
Diameter of Pipe given Head Loss over Length of Pipe
Go
f
x
Length of Pipe given Head Loss over Length of Pipe
Go
f
x
Specific Weight of Liquid given Head Loss over Length of Pipe
Go
f
x
Head Loss over Length of Pipe given Discharge
Go
f
x
Length of Pipe given Head Loss over Length of Pipe with Discharge
Go
f
x
Diameter of Pipe given Head Loss over Length of Pipe with Discharge
Go
List of variables in Hydraulics and Waterworks formulas
f
x
Specific Weight of Liquid
Go
f
x
Velocity Gradient
Go
f
x
Piezometric Gradient
Go
f
x
Radial Distance
Go
f
x
Velocity of Liquid
Go
f
x
Inclined Pipes Radius
Go
f
x
Pressure Gradient
Go
f
x
Fluid Velocity
Go
f
x
Radius of pipe
Go
f
x
Maximum Velocity
Go
f
x
Discharge in Pipe
Go
f
x
Width
Go
f
x
Horizontal Distance
Go
f
x
Mean Velocity
Go
f
x
Pressure Difference
Go
f
x
Length of Pipe
Go
f
x
Distance between plates
Go
f
x
Flow velocity
Go
f
x
Shear Stress
Go
f
x
Diameter of Section
Go
f
x
Slope of Bed
Go
f
x
Kinematic Viscosity
Go
f
x
Height of Channel
Go
f
x
Resistance Force
Go
f
x
Diameter of Sphere
Go
f
x
Terminal Velocity
Go
f
x
Specific Weight of Liquid in Piezometer
Go
f
x
Hydraulic Clearance
Go
f
x
Pressure Drop due to Friction
Go
f
x
Velocity of Piston
Go
f
x
Piston Length
Go
f
x
Radial Clearance
Go
f
x
Diameter of Piston
Go
f
x
Total Force in Piston
Go
f
x
Fluid Velocity in Oil Tank
Go
f
x
Discharge in Laminar Flow
Go
f
x
Shear Force
Go
f
x
Torque on Inner Cylinder
Go
f
x
Radius of Outer Cylinder
Go
f
x
Radius of Inner Cylinder
Go
f
x
Height of Cylinder
Go
f
x
Angular Speed
Go
f
x
Torque on Outer Cylinder
Go
f
x
Clearance
Go
f
x
Total Torque
Go
f
x
Viscometer Constant
Go
f
x
Time in Seconds
Go
f
x
Cross Sectional Area of Pipe
Go
f
x
Diameter of Pipe
Go
f
x
Average Reservoir Area
Go
f
x
Height of Column 1
Go
f
x
Height of Column 2
Go
f
x
Darcy Friction Factor
Go
f
x
Density of Fluid
Go
f
x
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.
Let Others Know
✖
Facebook
Twitter
Reddit
LinkedIn
Email
WhatsApp
Copied!