Radius of Elemental Section of Pipe given Velocity Gradient with Shear Stress Solution

STEP 0: Pre-Calculation Summary
Formula Used
Radial Distance = (2*Velocity Gradient*Dynamic Viscosity)/(Piezometric Gradient*Specific Weight of Liquid)
dradial = (2*VG*μ)/(dh/dx*γf)
This formula uses 5 Variables
Variables Used
Radial Distance - (Measured in Meter) - The Radial Distance refers to the distance from a central point, such as the center of a well or pipe, to a point within the fluid system.
Velocity Gradient - (Measured in Meter per Second) - The Velocity Gradient refers to the difference in velocity between the adjacent layers of the fluid.
Dynamic Viscosity - (Measured in Pascal Second) - The Dynamic Viscosity refers to the internal resistance of a fluid to flow when a force is applied.
Piezometric Gradient - The Piezometric Gradient refers to the measure of the change in hydraulic head (or piezometric head) per unit distance in a given direction within a fluid system.
Specific Weight of Liquid - (Measured in Newton per Cubic Meter) - The Specific Weight of Liquid refers to the weight per unit volume of that substance.
STEP 1: Convert Input(s) to Base Unit
Velocity Gradient: 76.6 Meter per Second --> 76.6 Meter per Second No Conversion Required
Dynamic Viscosity: 10.2 Poise --> 1.02 Pascal Second (Check conversion ​here)
Piezometric Gradient: 10 --> No Conversion Required
Specific Weight of Liquid: 9.81 Kilonewton per Cubic Meter --> 9810 Newton per Cubic Meter (Check conversion ​here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
dradial = (2*VG*μ)/(dh/dxf) --> (2*76.6*1.02)/(10*9810)
Evaluating ... ...
dradial = 0.00159290519877676
STEP 3: Convert Result to Output's Unit
0.00159290519877676 Meter --> No Conversion Required
FINAL ANSWER
0.00159290519877676 0.001593 Meter <-- Radial Distance
(Calculation completed in 00.007 seconds)

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Laminar Flow Through Inclined Pipes Calculators

Radius of Elemental Section of Pipe given Shear Stress
​ LaTeX ​ Go Radial Distance = (2*Shear Stress)/(Specific Weight of Liquid*Piezometric Gradient)
Specific Weight of Fluid given Shear Stress
​ LaTeX ​ Go Specific Weight of Liquid = (2*Shear Stress)/(Radial Distance*Piezometric Gradient)
Piezometric Gradient given Shear Stress
​ LaTeX ​ Go Piezometric Gradient = (2*Shear Stress)/(Specific Weight of Liquid*Radial Distance)
Shear Stresses
​ LaTeX ​ Go Shear Stress = Specific Weight of Liquid*Piezometric Gradient*Radial Distance/2

Radius of Elemental Section of Pipe given Velocity Gradient with Shear Stress Formula

​LaTeX ​Go
Radial Distance = (2*Velocity Gradient*Dynamic Viscosity)/(Piezometric Gradient*Specific Weight of Liquid)
dradial = (2*VG*μ)/(dh/dx*γf)

What is meant by velocity gradient?

According to the definition of velocity gradient, the difference in velocity between the layers of the fluid is known as the velocity gradient. It is represented by v/x, where v stands for velocity and x stands for the distance between the adjacent layers of the fluid.

How to Calculate Radius of Elemental Section of Pipe given Velocity Gradient with Shear Stress?

Radius of Elemental Section of Pipe given Velocity Gradient with Shear Stress calculator uses Radial Distance = (2*Velocity Gradient*Dynamic Viscosity)/(Piezometric Gradient*Specific Weight of Liquid) to calculate the Radial Distance, The Radius of Elemental Section of Pipe given Velocity Gradient with Shear Stress formula is defined as width of section. Radial Distance is denoted by dradial symbol.

How to calculate Radius of Elemental Section of Pipe given Velocity Gradient with Shear Stress using this online calculator? To use this online calculator for Radius of Elemental Section of Pipe given Velocity Gradient with Shear Stress, enter Velocity Gradient (VG), Dynamic Viscosity (μ), Piezometric Gradient (dh/dx) & Specific Weight of Liquid f) and hit the calculate button. Here is how the Radius of Elemental Section of Pipe given Velocity Gradient with Shear Stress calculation can be explained with given input values -> 0.001593 = (2*76.6*1.02)/(10*9810).

FAQ

What is Radius of Elemental Section of Pipe given Velocity Gradient with Shear Stress?
The Radius of Elemental Section of Pipe given Velocity Gradient with Shear Stress formula is defined as width of section and is represented as dradial = (2*VG*μ)/(dh/dxf) or Radial Distance = (2*Velocity Gradient*Dynamic Viscosity)/(Piezometric Gradient*Specific Weight of Liquid). The Velocity Gradient refers to the difference in velocity between the adjacent layers of the fluid, The Dynamic Viscosity refers to the internal resistance of a fluid to flow when a force is applied, The Piezometric Gradient refers to the measure of the change in hydraulic head (or piezometric head) per unit distance in a given direction within a fluid system & The Specific Weight of Liquid refers to the weight per unit volume of that substance.
How to calculate Radius of Elemental Section of Pipe given Velocity Gradient with Shear Stress?
The Radius of Elemental Section of Pipe given Velocity Gradient with Shear Stress formula is defined as width of section is calculated using Radial Distance = (2*Velocity Gradient*Dynamic Viscosity)/(Piezometric Gradient*Specific Weight of Liquid). To calculate Radius of Elemental Section of Pipe given Velocity Gradient with Shear Stress, you need Velocity Gradient (VG), Dynamic Viscosity (μ), Piezometric Gradient (dh/dx) & Specific Weight of Liquid f). With our tool, you need to enter the respective value for Velocity Gradient, Dynamic Viscosity, Piezometric Gradient & Specific Weight of Liquid and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate Radial Distance?
In this formula, Radial Distance uses Velocity Gradient, Dynamic Viscosity, Piezometric Gradient & Specific Weight of Liquid. We can use 2 other way(s) to calculate the same, which is/are as follows -
  • Radial Distance = (2*Shear Stress)/(Specific Weight of Liquid*Piezometric Gradient)
  • Radial Distance = sqrt((Inclined Pipes Radius^2)+Velocity of Liquid/((Specific Weight of Liquid/(4*Dynamic Viscosity))*Piezometric Gradient))
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