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## Credits

Birsa Institute of Technology (BIT), Sindri
Suraj Kumar has created this Calculator and 1000+ more calculators!
Meerut Institute of Engineering and Technology (MIET), Meerut
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## Compressive End Fibre Stress at Horizontal Diameter Solution

STEP 0: Pre-Calculation Summary
Formula Used
end_fibre_stress = ((3*Load per unit length*Diameter of Pipe)/(8*Thickness of pipe^2)+(Load per unit length)/(2*Thickness of pipe))
S = ((3*w*D)/(8*t^2)+(w)/(2*t))
This formula uses 3 Variables
Variables Used
Diameter of Pipe - Diameter of Pipe is the length of the longest chord of the pipe in which the liquid is flowing. (Measured in Centimeter)
Thickness of pipe - Thickness of pipe is the smaller dimention of pipe . (Measured in Meter)
STEP 1: Convert Input(s) to Base Unit
Load per unit length: 3 --> No Conversion Required
Diameter of Pipe: 2 Centimeter --> 0.02 Meter (Check conversion here)
Thickness of pipe: 3 Meter --> 3 Meter No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
S = ((3*w*D)/(8*t^2)+(w)/(2*t)) --> ((3*3*0.02)/(8*3^2)+(3)/(2*3))
Evaluating ... ...
S = 0.5025
STEP 3: Convert Result to Output's Unit
0.5025 Pascal -->0.5025 Newton per Square Meter (Check conversion here)
0.5025 Newton per Square Meter <-- Extreme fibre stress
(Calculation completed in 00.172 seconds)

## < 11 Other formulas that you can solve using the same Inputs

Head loss due to Laminar Flow
head_loss = (128*Viscous Force*Rate of flow*Length of Pipe)/(specific weight of liquid*pi*(Diameter of Pipe)^(4)) Go
Moment of Inertia of shaft in terms of natural frequency
moment_inertia_shaft = ((4*frequency^2)*Load per unit length*(Length of Shaft^4))/((pi^2)*Young's Modulus*Acceleration Due To Gravity) Go
Length of the shaft in terms of static deflection
length_of_shaft = ((Static deflection*384*Young's Modulus*Moment of inertia of the shaft)/(5*Load per unit length))^(1/4) Go
Static deflection for simply supported beam with uniformly distributed load
static_deflection = (5*Load per unit length*(Length of the Beam^4))/(384*Young's Modulus*Moment of inertia of the beam) Go
Length of beam for Simply supported beam with a uniformly distributed load
length_of_beam = ((384*Young's Modulus*Moment of inertia of the beam*Static deflection)/(5*Load per unit length))^(1/4) Go
Static deflection of a simply supported shaft due to uniformly distributed load
static_deflection = (5*Load per unit length*(Length of Shaft^4))/(384*Young's Modulus*Moment of inertia of the shaft) Go
Static deflection for fixed beam with a uniformly distributed point load
static_deflection = (Load per unit length*(Length of the Beam^4))/(384*Young's Modulus*Moment of inertia of the beam) Go
Length of beam for fixed beam with a uniformly distributed load
length_of_beam = ((384*Young's Modulus*Moment of inertia of the beam*Static deflection)/(Load per unit length))^(1/4) Go
Static deflection for cantilever beam with a uniformly distributed load
static_deflection = (Load per unit length*(Length of the Beam^4))/(8*Young's Modulus*Moment of inertia of the beam) Go
Length of beam for cantilever beam with a uniformly distributed load
length_of_beam = ((8*Young's Modulus*Moment of inertia of the beam*Static deflection)/(Load per unit length))^(1/4) Go
Moment of Inertia of shaft in terms of static deflection if load per unit length is known
moment_inertia_shaft = (5*Load per unit length*(Length of Shaft^4))/(384*Young's Modulus*Static deflection) Go

## < 2 Other formulas that calculate the same Output

Tensile End Fibre Stress at Horizontal Diameter
end_fibre_stress = ((3*Load per unit length*Diameter of Pipe)/(8*Thickness of pipe^2)-(Load per unit length)/(2*Thickness of pipe)) Go
Maximum End Fibre Stress on Horizontal Point
end_fibre_stress = (3*Load per unit length*Diameter of Pipe)/(8*Thickness of pipe^2) Go

### Compressive End Fibre Stress at Horizontal Diameter Formula

end_fibre_stress = ((3*Load per unit length*Diameter of Pipe)/(8*Thickness of pipe^2)+(Load per unit length)/(2*Thickness of pipe))
S = ((3*w*D)/(8*t^2)+(w)/(2*t))

## What is stress ?

Stress is the force acting on the unit area of a material. The effect of stress on a body is named as strain. Stress can deform the body. How much force material experience can be measured using stress units.

## How to Calculate Compressive End Fibre Stress at Horizontal Diameter?

Compressive End Fibre Stress at Horizontal Diameter calculator uses end_fibre_stress = ((3*Load per unit length*Diameter of Pipe)/(8*Thickness of pipe^2)+(Load per unit length)/(2*Thickness of pipe)) to calculate the Extreme fibre stress, The Compressive End Fibre Stress at Horizontal Diameter calculates the value of compressive end fibre stress when we have prior information of other parameters used. Extreme fibre stress and is denoted by S symbol.

How to calculate Compressive End Fibre Stress at Horizontal Diameter using this online calculator? To use this online calculator for Compressive End Fibre Stress at Horizontal Diameter, enter Load per unit length (w), Diameter of Pipe (D) and Thickness of pipe (t) and hit the calculate button. Here is how the Compressive End Fibre Stress at Horizontal Diameter calculation can be explained with given input values -> 0.5025 = ((3*3*0.02)/(8*3^2)+(3)/(2*3)).

### FAQ

What is Compressive End Fibre Stress at Horizontal Diameter?
The Compressive End Fibre Stress at Horizontal Diameter calculates the value of compressive end fibre stress when we have prior information of other parameters used and is represented as S = ((3*w*D)/(8*t^2)+(w)/(2*t)) or end_fibre_stress = ((3*Load per unit length*Diameter of Pipe)/(8*Thickness of pipe^2)+(Load per unit length)/(2*Thickness of pipe)). Load per unit length is the distributed load which is spread over a surface or line, Diameter of Pipe is the length of the longest chord of the pipe in which the liquid is flowing and Thickness of pipe is the smaller dimention of pipe .
How to calculate Compressive End Fibre Stress at Horizontal Diameter?
The Compressive End Fibre Stress at Horizontal Diameter calculates the value of compressive end fibre stress when we have prior information of other parameters used is calculated using end_fibre_stress = ((3*Load per unit length*Diameter of Pipe)/(8*Thickness of pipe^2)+(Load per unit length)/(2*Thickness of pipe)). To calculate Compressive End Fibre Stress at Horizontal Diameter, you need Load per unit length (w), Diameter of Pipe (D) and Thickness of pipe (t). With our tool, you need to enter the respective value for Load per unit length, Diameter of Pipe and Thickness of pipe 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 Extreme fibre stress?
In this formula, Extreme fibre stress uses Load per unit length, Diameter of Pipe and Thickness of pipe. We can use 2 other way(s) to calculate the same, which is/are as follows -
• end_fibre_stress = ((3*Load per unit length*Diameter of Pipe)/(8*Thickness of pipe^2)-(Load per unit length)/(2*Thickness of pipe))
• end_fibre_stress = (3*Load per unit length*Diameter of Pipe)/(8*Thickness of pipe^2)
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