Compressive Stress Produced when Pipe is Empty Calculator

✖Load per unit length is defined as load applied per unit length of the pipe.ⓘ Load per unit Length [W]			+10% -10%
✖Total Load per Unit Length means the sum of all load applied per unit length of the pipe.ⓘ Total Load per Unit Length [W^']			+10% -10%
✖Thickness is the distance through an object.ⓘ Thickness [t]			+10% -10%

✖Compressive Stress is the force that is responsible for the deformation of the material such that the volume of the material reduces.ⓘ Compressive Stress Produced when Pipe is Empty [σ_c]

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Formula

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Compressive Stress Produced when Pipe is Empty

Formula

`"σ"_{"c"} = ("W"+"W"^{"'"})/"t"`

Example

`"23.33333kN/m²"=("22kN/m"+"6.0kN/m")/"1.2m"`

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Compressive Stress Produced when Pipe is Empty Solution

STEP 0: Pre-Calculation Summary

Formula Used

Compressive Stress = (Load per unit Length+Total Load per Unit Length)/Thickness
σ_c = (W+W^')/t
This formula uses 4 Variables

Variables Used

Compressive Stress - (Measured in Pascal) - Compressive Stress is the force that is responsible for the deformation of the material such that the volume of the material reduces.
Load per unit Length - (Measured in Newton per Meter) - Load per unit length is defined as load applied per unit length of the pipe.
Total Load per Unit Length - (Measured in Newton per Meter) - Total Load per Unit Length means the sum of all load applied per unit length of the pipe.
Thickness - (Measured in Meter) - Thickness is the distance through an object.

STEP 1: Convert Input(s) to Base Unit

Load per unit Length: 22 Kilonewton per Meter --> 22000 Newton per Meter (Check conversion here)
Total Load per Unit Length: 6 Kilonewton per Meter --> 6000 Newton per Meter (Check conversion here)
Thickness: 1.2 Meter --> 1.2 Meter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

σ_c = (W+W^')/t --> (22000+6000)/1.2

Evaluating ... ...

σ_c = 23333.3333333333

STEP 3: Convert Result to Output's Unit

23333.3333333333 Pascal -->23.3333333333333 Kilonewton per Square Meter (Check conversion here)

FINAL ANSWER

23.3333333333333 ≈ 23.33333 Kilonewton per Square Meter <-- Compressive Stress

(Calculation completed in 00.020 seconds)

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Created by Suraj Kumar

Birsa Institute of Technology (BIT), Sindri

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Verified by Ishita Goyal

Meerut Institute of Engineering and Technology (MIET), Meerut

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< 16 Pressure Due to External Loads Calculators

Distance of Top of Pipe to below Surface of Fill given Unit Pressure

Go Distance between pipe and fill = ((Unit Pressure*2*pi*(Slant Height)^5)/(3*Superimposed load))^(1/3)

Slant Height of considered Point given Unit Pressure

Go Slant Height = ((3*Superimposed load*(Distance between pipe and fill)^3)/(2*pi*Unit Pressure))^(1/5)

Unit Pressure Developed at any Point in Fill at Depth

Go Unit Pressure = (3*(Distance between pipe and fill)^3*Superimposed load)/(2*pi*(Slant Height)^5)

Superimposed Load given Unit Pressure

Go Superimposed load = (2*pi*Unit Pressure*(Slant Height)^5)/(3*(Distance between pipe and fill)^3)

External Diameter of Pipe given Load Per Unit Length for Pipes

Go External diameter = sqrt(Load per unit Length/(Pipe coefficient*Specific Weight of Fill))

Pipe Coefficient given Load Per Unit Length for Pipes

Go Pipe coefficient = (Load per unit Length/(Specific Weight of Fill*(External diameter)^2))

Specific Weight of Fill Material given Load Per Unit Length for Pipes

Go Specific Weight of Fill = Load per unit Length/(Pipe coefficient*(External diameter)^2)

Load Per Unit Length for Pipes Resting on Undisturbed Ground on Cohesion Less Soil

Go Load per unit Length = Pipe coefficient*Specific Weight of Fill*(External diameter)^2

Coefficient of Thermal Expansion given Elongation in Pipes

Go Thermal Expansion Coefficient = Elongation/(Initial Length*Change in Temperature)

Coefficient of Expansion of Material given Stress in Pipe

Go Coefficient of Thermal Expansion = Stress/(Change in Temperature*Elastic Modulus)

Change in Temperature given Elongation in Pipes

Go Change in Temperature = Elongation/(Initial Length*Thermal Expansion Coefficient)

Change in Temperature given Stress in Pipe

Go Change in Temperature = Stress/(Coefficient of Thermal Expansion*Elastic Modulus)

Load Per Unit Length for Pipes given Compressive Stress

Go Load per unit Length = (Compressive Stress*Thickness)-Total Load per Unit Length

Compressive Stress Produced when Pipe is Empty

Go Compressive Stress = (Load per unit Length+Total Load per Unit Length)/Thickness

Thickness of Pipes given Compressive Stress

Go Thickness = (Total Load per Unit Length+Load per unit Length)/Compressive Stress

Elongation in Pipes given Change in Temperature

Go Elongation = Initial Length*Thermal Expansion Coefficient*Change in Temperature

Compressive Stress Produced when Pipe is Empty Formula

Compressive Stress = (Load per unit Length+Total Load per Unit Length)/Thickness
σ_c = (W+W^')/t

What is compressive stress.

Compressive stress is the force that is responsible for the deformation of the material such that the volume of the material reduces. It is the stress experienced by a material which leads to a smaller volume.

How to Calculate Compressive Stress Produced when Pipe is Empty?

Compressive Stress Produced when Pipe is Empty calculator uses Compressive Stress = (Load per unit Length+Total Load per Unit Length)/Thickness to calculate the Compressive Stress, The Compressive Stress Produced when Pipe is Empty defined as the stress component perpendicular to a given surface, such as a fault plane, that results from forces applied perpendicular to the surface. Compressive Stress is denoted by σ_c symbol.

How to calculate Compressive Stress Produced when Pipe is Empty using this online calculator? To use this online calculator for Compressive Stress Produced when Pipe is Empty, enter Load per unit Length (W), Total Load per Unit Length (W^') & Thickness (t) and hit the calculate button. Here is how the Compressive Stress Produced when Pipe is Empty calculation can be explained with given input values -> 0.023333 = (22000+6000)/1.2.

FAQ

What is Compressive Stress Produced when Pipe is Empty?

The Compressive Stress Produced when Pipe is Empty defined as the stress component perpendicular to a given surface, such as a fault plane, that results from forces applied perpendicular to the surface and is represented as σ_c = (W+W^')/t or Compressive Stress = (Load per unit Length+Total Load per Unit Length)/Thickness. Load per unit length is defined as load applied per unit length of the pipe, Total Load per Unit Length means the sum of all load applied per unit length of the pipe & Thickness is the distance through an object.

How to calculate Compressive Stress Produced when Pipe is Empty?

The Compressive Stress Produced when Pipe is Empty defined as the stress component perpendicular to a given surface, such as a fault plane, that results from forces applied perpendicular to the surface is calculated using Compressive Stress = (Load per unit Length+Total Load per Unit Length)/Thickness. To calculate Compressive Stress Produced when Pipe is Empty, you need Load per unit Length (W), Total Load per Unit Length (W^') & Thickness (t). With our tool, you need to enter the respective value for Load per unit Length, Total Load per Unit Length & Thickness and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

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