✖Extreme Fiber Stress is the maximum stress experienced by the outermost fibers of a material or structural element when subjected to external loads.ⓘ Extreme Fiber Stress [S]			+10% -10%
✖Load per Meter Length of Pipe is the amount of weight or force exerted on a pipe per unit length, it is crucial for ensuring the safe and efficient operation of piping systems.ⓘ Load per Meter Length of Pipe [w^'']			+10% -10%
✖Thickness of Pipe is the smaller dimension of pipe. It is the distance between the inner and outer or front and back surfaces of the pipe.ⓘ Thickness of Pipe [t_pipe]			+10% -10%

✖Diameter of Pipe is the diameter of the pipe in which the liquid is flowing.ⓘ Diameter of Pipe for Maximum End Fiber Stress [D_pipe]

⎘ Copy

👎

Formula

✖

Diameter of Pipe for Maximum End Fiber Stress

Formula

`"D"_{"pipe"} = "S"/((3*"w"^{"''"})/(8*"t"_{"pipe"}^2))`

Example

`"0.910116m"="20.0kN/m²"/((3*"56.28kN/m")/(8*("0.98m")^2))`

Calculator

LaTeX

Reset

👍

Download Stresses Due to External Loads Formulas PDF PDF Image

Diameter of Pipe for Maximum End Fiber Stress Solution

STEP 0: Pre-Calculation Summary

Formula Used

Diameter of Pipe = Extreme Fiber Stress/((3*Load per Meter Length of Pipe)/(8*Thickness of Pipe^2))
D_pipe = S/((3*w^'')/(8*t_pipe^2))
This formula uses 4 Variables

Variables Used

Diameter of Pipe - (Measured in Meter) - Diameter of Pipe is the diameter of the pipe in which the liquid is flowing.
Extreme Fiber Stress - (Measured in Pascal) - Extreme Fiber Stress is the maximum stress experienced by the outermost fibers of a material or structural element when subjected to external loads.
Load per Meter Length of Pipe - (Measured in Newton per Meter) - Load per Meter Length of Pipe is the amount of weight or force exerted on a pipe per unit length, it is crucial for ensuring the safe and efficient operation of piping systems.
Thickness of Pipe - (Measured in Meter) - Thickness of Pipe is the smaller dimension of pipe. It is the distance between the inner and outer or front and back surfaces of the pipe.

STEP 1: Convert Input(s) to Base Unit

Extreme Fiber Stress: 20 Kilonewton per Square Meter --> 20000 Pascal (Check conversion here)
Load per Meter Length of Pipe: 56.28 Kilonewton per Meter --> 56280 Newton per Meter (Check conversion here)
Thickness of Pipe: 0.98 Meter --> 0.98 Meter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

D_pipe = S/((3*w^'')/(8*t_pipe^2)) --> 20000/((3*56280)/(8*0.98^2))

Evaluating ... ...

D_pipe = 0.910116086235489

STEP 3: Convert Result to Output's Unit

0.910116086235489 Meter --> No Conversion Required

FINAL ANSWER

0.910116086235489 ≈ 0.910116 Meter <-- Diameter of Pipe

(Calculation completed in 00.004 seconds)

You are here -

Home » Engineering » Civil » Environmental Engineering » Conveyance of Water » Stresses in Pipes » Stresses Due to External Loads » Diameter of Pipe for Maximum End Fiber Stress

Credits

Created by Suraj Kumar

Birsa Institute of Technology (BIT), Sindri

Suraj Kumar has created this Calculator and 2200+ more calculators!

Verified by Ishita Goyal

Meerut Institute of Engineering and Technology (MIET), Meerut

Ishita Goyal has verified this Calculator and 2600+ more calculators!

< 19 Stresses Due to External Loads Calculators

Total Tension in Pipe with known Head of Water

Go Total Tension of Pipe in MN = ((Unit Weight of Liquid*Head of the Liquid)*Cross-Sectional Area)+((Unit Weight of Liquid*Cross-Sectional Area*(Flow Velocity of Fluid)^2)/Acceleration due to Gravity in Environment)

Total Tension in Pipe using Water Pressure

Go Total Tension of Pipe in MN = (Water Pressure*Cross-Sectional Area)+((Unit Weight of Water in KN per Cubic Meter*Cross-Sectional Area*(Flow Velocity of Fluid)^2)/Acceleration due to Gravity in Environment)

Compressive End Fiber Stress at Horizontal Diameter

Go Extreme Fiber Stress = ((3*Load on Buried Pipe per Unit Length*Diameter of Pipe in Centimeter)/(8*Thickness of Pipe^2)+(Load on Buried Pipe per Unit Length)/(2*Thickness of Pipe))

Diameter of Pipe given Compressive End Fiber Stress

Go Diameter of Pipe = (Extreme Fiber Stress-(Load on Buried Pipe per Unit Length)/(2*Thickness of Pipe))*((8*Thickness of Pipe^2)/(3*Load on Buried Pipe per Unit Length))

Diameter of Pipe given Tensile End Fiber Stress

Go Diameter of Pipe = (Extreme Fiber Stress+(Load on Buried Pipe per Unit Length)/(2*Thickness of Pipe))*((8*Thickness of Pipe^2)/(3*Load on Buried Pipe per Unit Length))

Load per Meter Length of Pipe for Compressive End Fiber Stress

Go Load on Buried Pipe per Unit Length = Extreme Fiber Stress/((3*Diameter of Pipe)/(8*Thickness of Pipe^2)+(1)/(2*Thickness of Pipe))

Width of Trench for Load per Meter Length of Pipe

Go Width of Trench = sqrt(Load on Buried Pipe per Unit Length/(Coefficient Dependent on Soil in Environmental*Unit Weight of Fill))

Concentrated Wheel Load given Average Load on Pipe

Go Concentrated Wheel Load = (Average Load on Pipe in Newton per Meter*Effective Length of Pipe)/(Impact Factor*Load Coefficient)

Load Coefficient using Average Load on Pipe

Go Load Coefficient = (Average Load on Pipe in Newton per Meter*Effective Length of Pipe)/(Impact Factor*Concentrated Wheel Load)

Impact Factor using Average Load on Pipe

Go Impact Factor = (Average Load on Pipe in Newton per Meter*Effective Length of Pipe)/(Load Coefficient*Concentrated Wheel Load)

Effective Length of Pipe using Average Load on Pipe

Go Effective Length of Pipe = (Impact Factor*Load Coefficient*Concentrated Wheel Load)/Average Load on Pipe in Newton per Meter

Average Load on Pipe due to Wheel Load

Go Average Load on Pipe in Newton per Meter = (Impact Factor*Load Coefficient*Concentrated Wheel Load)/Effective Length of Pipe

Thickness of Pipe given Maximum End Fiber Stress

Go Thickness of Pipe = sqrt((3*Load on Buried Pipe per Unit Length*Diameter of Pipe)/(8*Extreme Fiber Stress))

Constant which depend upon type of Soil for Load per meter Length of Pipe

Go Coefficient Dependent on Soil in Environmental = Load on Buried Pipe per Unit Length/(Unit Weight of Fill*(Width of Trench)^2)

Unit Weight of Backfill Material for Load per Meter Length of Pipe

Go Unit Weight of Fill = Load on Buried Pipe per Unit Length/(Coefficient Dependent on Soil in Environmental*(Width of Trench)^2)

Load per Meter Length of Pipe

Go Load on Buried Pipe per Unit Length = Coefficient Dependent on Soil in Environmental*Unit Weight of Fill*(Width of Trench)^2

Maximum End Fiber Stress on Horizontal Point

Go Extreme Fiber Stress = (3*Load on Buried Pipe per Unit Length*Diameter of Pipe)/(8*Thickness of Pipe^2)

Load per Meter Length of Pipe for Maximum End Fiber Stress

Go Load per Meter Length of Pipe = Extreme Fiber Stress/((3*Diameter of Pipe)/(8*Thickness of Pipe^2))

Diameter of Pipe for Maximum End Fiber Stress

Go Diameter of Pipe = Extreme Fiber Stress/((3*Load per Meter Length of Pipe)/(8*Thickness of Pipe^2))

Diameter of Pipe for Maximum End Fiber Stress Formula

Diameter of Pipe = Extreme Fiber Stress/((3*Load per Meter Length of Pipe)/(8*Thickness of Pipe^2))
D_pipe = S/((3*w^'')/(8*t_pipe^2))

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 Diameter of Pipe for Maximum End Fiber Stress?

Diameter of Pipe for Maximum End Fiber Stress calculator uses Diameter of Pipe = Extreme Fiber Stress/((3*Load per Meter Length of Pipe)/(8*Thickness of Pipe^2)) to calculate the Diameter of Pipe, The Diameter of Pipe for Maximum End Fiber Stress formula is defined as the value of diameter of pipe when we have prior information of maximum end fiber stress. Diameter of Pipe is denoted by D_pipe symbol.

How to calculate Diameter of Pipe for Maximum End Fiber Stress using this online calculator? To use this online calculator for Diameter of Pipe for Maximum End Fiber Stress, enter Extreme Fiber Stress (S), Load per Meter Length of Pipe (w^'') & Thickness of Pipe (t_pipe) and hit the calculate button. Here is how the Diameter of Pipe for Maximum End Fiber Stress calculation can be explained with given input values -> 0.388028 = 20000/((3*56280)/(8*0.98^2)).

FAQ

What is Diameter of Pipe for Maximum End Fiber Stress?

The Diameter of Pipe for Maximum End Fiber Stress formula is defined as the value of diameter of pipe when we have prior information of maximum end fiber stress and is represented as D_pipe = S/((3*w^'')/(8*t_pipe^2)) or Diameter of Pipe = Extreme Fiber Stress/((3*Load per Meter Length of Pipe)/(8*Thickness of Pipe^2)). Extreme Fiber Stress is the maximum stress experienced by the outermost fibers of a material or structural element when subjected to external loads, Load per Meter Length of Pipe is the amount of weight or force exerted on a pipe per unit length, it is crucial for ensuring the safe and efficient operation of piping systems & Thickness of Pipe is the smaller dimension of pipe. It is the distance between the inner and outer or front and back surfaces of the pipe.

How to calculate Diameter of Pipe for Maximum End Fiber Stress?

The Diameter of Pipe for Maximum End Fiber Stress formula is defined as the value of diameter of pipe when we have prior information of maximum end fiber stress is calculated using Diameter of Pipe = Extreme Fiber Stress/((3*Load per Meter Length of Pipe)/(8*Thickness of Pipe^2)). To calculate Diameter of Pipe for Maximum End Fiber Stress, you need Extreme Fiber Stress (S), Load per Meter Length of Pipe (w^'') & Thickness of Pipe (t_pipe). With our tool, you need to enter the respective value for Extreme Fiber Stress, Load per Meter Length of Pipe & 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 Diameter of Pipe?

In this formula, Diameter of Pipe uses Extreme Fiber Stress, Load per Meter Length of Pipe & Thickness of Pipe. We can use 2 other way(s) to calculate the same, which is/are as follows -

Diameter of Pipe = (Extreme Fiber Stress-(Load on Buried Pipe per Unit Length)/(2*Thickness of Pipe))*((8*Thickness of Pipe^2)/(3*Load on Buried Pipe per Unit Length))
Diameter of Pipe = (Extreme Fiber Stress+(Load on Buried Pipe per Unit Length)/(2*Thickness of Pipe))*((8*Thickness of Pipe^2)/(3*Load on Buried Pipe per Unit Length))

Home

FREE PDFs

🔍 Search