M Naveen
National Institute of Technology (NIT), Warangal
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Mridul Sharma
Indian Institute of Information Technology (IIIT), Bhopal
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11 Other formulas that you can solve using the same Inputs

Maximum and Center Deflection of Cantilever Beam carrying Point Load at any point
Deflection=(Point Load acting on the Beam*(Distance from end A^2)*(3*Length-Distance from end A))/(6*Modulus Of Elasticity*Area Moment of Inertia) GO
Maximum and Center Deflection of Simply Supported Beam carrying UDL over its entire Length
Deflection=(5*Uniformly Distributed Load*(Length^4))/(384*Modulus Of Elasticity*Area Moment of Inertia) GO
Maximum and Center Deflection of Simply Supported Beam carrying Point Load at Center
Deflection=(Point Load acting on the Beam*(Length^3))/(48*Modulus Of Elasticity*Area Moment of Inertia) GO
Maximum and Center Deflection of Cantilever Beam carrying Point Load at Free End
Deflection=(Point Load acting on the Beam*(Length^3))/(3*Modulus Of Elasticity*Area Moment of Inertia) GO
Maximum and Center Deflection of Cantilever Beam with Couple Moment at Free End
Deflection=(Couple Moment*(Length^2))/(2*Modulus Of Elasticity*Area Moment of Inertia) GO
Bending Moment when Strain Energy in Bending is Given
Bending moment=sqrt(Strain Energy*(2*Modulus Of Elasticity*Moment of Inertia)/Length) GO
Length over which Deformation Takes Place when Strain Energy in Bending is Given
Length=Strain Energy*(2*Modulus Of Elasticity*Moment of Inertia)/(Bending moment^2) GO
Moment of Inertia when Strain Energy in Bending is Given
Moment of Inertia=Length*(Bending moment^2)/(2*Strain Energy*Modulus Of Elasticity) GO
Strain Energy in Bending
Strain Energy=(Bending moment^2)*Length/(2*Modulus Of Elasticity*Moment of Inertia) GO
Slenderness Ratio
Slenderness Ratio=Effective Length/Least Radius of Gyration GO
Stress using Hook's Law
Stress=Modulus Of Elasticity*Engineering strain GO

2 Other formulas that calculate the same Output

Pipe diamter when bulking stress is given
Pipe Diameter=(-sqrt((Bulking stress-45000)/1.406)*Least Radius of Gyration)/Soil stiffness factor GO
Pipe diameter when flexibility factor is given
Pipe Diameter= sqrt(Flexibility factor*Modulus Of Elasticity*Moment of Inertia) GO

Pipe diameter when Bulking stress For diameters greater than 126.5r/K is given Formula

Pipe Diameter=(sqrt(12*Modulus Of Elasticity/Bulking stress)*Least Radius of Gyration)/Soil stiffness factor
PD=(sqrt(12*E/F<sub>c</sub>)*r)/K<sub>
More formulas
Thrust of structure GO
Span diameter when thrust is given GO
Live load pressure when thrust is given GO
Dead load pressure when thrust is given GO
Flexibility factor GO
Pipe diameter when flexibility factor is given GO
Modulus of elasticity when flexibility factor is given GO
Moment of inertia when flexibility factor is given GO
Bulking stress GO
Soil stiffness factor when bulking stress is given GO
Pipe diamter when bulking stress is given GO
Radius of gyration when bulking stress is given GO
Bulking stress For diameters greater than 126.5r/K GO
modulus of elasticity when Bulking stress For diameters greater than 126.5r/K is given GO
soil stiffness factor when Bulking stress For diameters greater than 126.5r/K is given GO
Radius of gyration when Bulking stress For diameters greater than 126.5r/K is given GO

What is modulus of elasticity?

Modulus of elasticity is defined as the mechanical property of a material to withstand the compression or the elongation with respect to its length.

How to Calculate Pipe diameter when Bulking stress For diameters greater than 126.5r/K is given?

Pipe diameter when Bulking stress For diameters greater than 126.5r/K is given calculator uses Pipe Diameter=(sqrt(12*Modulus Of Elasticity/Bulking stress)*Least Radius of Gyration)/Soil stiffness factor to calculate the Pipe Diameter, The Pipe diameter when Bulking stress For diameters greater than 126.5r/K is given can be defined as a straight line joining a point from one end of the pipe to a point on the other end of the pipe. Pipe Diameter and is denoted by PD symbol.

How to calculate Pipe diameter when Bulking stress For diameters greater than 126.5r/K is given using this online calculator? To use this online calculator for Pipe diameter when Bulking stress For diameters greater than 126.5r/K is given, enter Modulus Of Elasticity (E), Bulking stress (Fc), Least Radius of Gyration (r) and Soil stiffness factor (K and hit the calculate button. Here is how the Pipe diameter when Bulking stress For diameters greater than 126.5r/K is given calculation can be explained with given input values -> 0.002828 = (sqrt(12*10000/150000000)*50)/500.

FAQ

What is Pipe diameter when Bulking stress For diameters greater than 126.5r/K is given?
The Pipe diameter when Bulking stress For diameters greater than 126.5r/K is given can be defined as a straight line joining a point from one end of the pipe to a point on the other end of the pipe and is represented as PD=(sqrt(12*E/Fc)*r)/K or Pipe Diameter=(sqrt(12*Modulus Of Elasticity/Bulking stress)*Least Radius of Gyration)/Soil stiffness factor. Modulus Of Elasticity is a quantity that measures an object or substance's resistance to being deformed elastically when a stress is applied to it, Bulking stress can be described as the highest value of the compressive stress, The Least Radius of Gyration is the smallest value of the radius of gyration is used for structural calculations and Soil stiffness factor can be described as the parameter for compacting the soil.
How to calculate Pipe diameter when Bulking stress For diameters greater than 126.5r/K is given?
The Pipe diameter when Bulking stress For diameters greater than 126.5r/K is given can be defined as a straight line joining a point from one end of the pipe to a point on the other end of the pipe is calculated using Pipe Diameter=(sqrt(12*Modulus Of Elasticity/Bulking stress)*Least Radius of Gyration)/Soil stiffness factor. To calculate Pipe diameter when Bulking stress For diameters greater than 126.5r/K is given, you need Modulus Of Elasticity (E), Bulking stress (Fc), Least Radius of Gyration (r) and Soil stiffness factor (K. With our tool, you need to enter the respective value for Modulus Of Elasticity, Bulking stress, Least Radius of Gyration and Soil stiffness factor 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 Pipe Diameter?
In this formula, Pipe Diameter uses Modulus Of Elasticity, Bulking stress, Least Radius of Gyration and Soil stiffness factor. We can use 2 other way(s) to calculate the same, which is/are as follows -
  • Pipe Diameter= sqrt(Flexibility factor*Modulus Of Elasticity*Moment of Inertia)
  • Pipe Diameter=(-sqrt((Bulking stress-45000)/1.406)*Least Radius of Gyration)/Soil stiffness factor
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