Shear stress at surface of shaft given shear strain energy in ring of radius 'r' Solution

STEP 0: Pre-Calculation Summary
Formula Used
Shear stress on surface of shaft = sqrt((Strain Energy in body*(2*Modulus of rigidity of Shaft*(Radius of Shaft^2)))/(2*pi*Length of Shaft*(Radius 'r' from Center Of Shaft^3)*Length of Small Element))
𝜏 = sqrt((U*(2*G*(rshaft^2)))/(2*pi*L*(rcenter^3)*δx))
This formula uses 1 Constants, 1 Functions, 7 Variables
Constants Used
pi - Archimedes' constant Value Taken As 3.14159265358979323846264338327950288
Functions Used
sqrt - A square root function is a function that takes a non-negative number as an input and returns the square root of the given input number., sqrt(Number)
Variables Used
Shear stress on surface of shaft - (Measured in Pascal) - Shear stress on surface of shaft is force tending to cause deformation of a material by slippage along a plane or planes parallel to the imposed stress.
Strain Energy in body - (Measured in Joule) - Strain Energy in body is defined as the energy stored in a body due to deformation.
Modulus of rigidity of Shaft - (Measured in Pascal) - Modulus of rigidity of Shaft is the elastic coefficient when a shear force is applied resulting in lateral deformation. It gives us a measure of how rigid a body is.
Radius of Shaft - (Measured in Meter) - The Radius of Shaft is the radius of the shaft subjected under torsion.
Length of Shaft - (Measured in Meter) - The Length of Shaft is the distance between two ends of shaft.
Radius 'r' from Center Of Shaft - (Measured in Meter) - Radius 'r' from Center Of Shaft is a radial line from the focus to any point of a curve.
Length of Small Element - (Measured in Meter) - Length of Small Element is a measure of distance.
STEP 1: Convert Input(s) to Base Unit
Strain Energy in body: 50 Kilojoule --> 50000 Joule (Check conversion ​here)
Modulus of rigidity of Shaft: 4E-05 Megapascal --> 40 Pascal (Check conversion ​here)
Radius of Shaft: 2000 Millimeter --> 2 Meter (Check conversion ​here)
Length of Shaft: 7000 Millimeter --> 7 Meter (Check conversion ​here)
Radius 'r' from Center Of Shaft: 1500 Millimeter --> 1.5 Meter (Check conversion ​here)
Length of Small Element: 43.36 Millimeter --> 0.04336 Meter (Check conversion ​here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
𝜏 = sqrt((U*(2*G*(rshaft^2)))/(2*pi*L*(rcenter^3)*δx)) --> sqrt((50000*(2*40*(2^2)))/(2*pi*7*(1.5^3)*0.04336))
Evaluating ... ...
𝜏 = 1576.66530807717
STEP 3: Convert Result to Output's Unit
1576.66530807717 Pascal -->0.00157666530807717 Megapascal (Check conversion ​here)
FINAL ANSWER
0.00157666530807717 0.001577 Megapascal <-- Shear stress on surface of shaft
(Calculation completed in 00.020 seconds)

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Expression for Strain Energy stored in a Body Due to Torsion Calculators

Value of radius 'r' given shear stress at radius 'r' from center
​ LaTeX ​ Go Radius 'r' from Center Of Shaft = (Shear stress at radius 'r' from shaft*Radius of Shaft)/Shear stress on surface of shaft
Radius of shaft given shear stress at radius r from center
​ LaTeX ​ Go Radius of Shaft = (Radius 'r' from Center Of Shaft/Shear stress at radius 'r' from shaft)*Shear stress on surface of shaft
Modulus of rigidity given shear strain energy
​ LaTeX ​ Go Modulus of rigidity of Shaft = (Shear stress on surface of shaft^2)*(Volume of Shaft)/(2*Strain Energy in body)
Shear strain energy
​ LaTeX ​ Go Strain Energy in body = (Shear stress on surface of shaft^2)*(Volume of Shaft)/(2*Modulus of rigidity of Shaft)

Shear stress at surface of shaft given shear strain energy in ring of radius 'r' Formula

​LaTeX ​Go
Shear stress on surface of shaft = sqrt((Strain Energy in body*(2*Modulus of rigidity of Shaft*(Radius of Shaft^2)))/(2*pi*Length of Shaft*(Radius 'r' from Center Of Shaft^3)*Length of Small Element))
𝜏 = sqrt((U*(2*G*(rshaft^2)))/(2*pi*L*(rcenter^3)*δx))

Is strain energy a material property?

The strain energy (i.e. the amount of potential energy stored due to the deformation) is equal to the work expended in deforming the material. The total strain energy corresponds to the area under the load-deflection curve and has units of in-lbf in US Customary units and N-m in SI units.

How to Calculate Shear stress at surface of shaft given shear strain energy in ring of radius 'r'?

Shear stress at surface of shaft given shear strain energy in ring of radius 'r' calculator uses Shear stress on surface of shaft = sqrt((Strain Energy in body*(2*Modulus of rigidity of Shaft*(Radius of Shaft^2)))/(2*pi*Length of Shaft*(Radius 'r' from Center Of Shaft^3)*Length of Small Element)) to calculate the Shear stress on surface of shaft, Shear stress at surface of shaft given shear strain energy in ring of radius 'r' is a force tending to cause deformation of a material by slippage along a plane or planes parallel to the imposed stress. Shear stress on surface of shaft is denoted by 𝜏 symbol.

How to calculate Shear stress at surface of shaft given shear strain energy in ring of radius 'r' using this online calculator? To use this online calculator for Shear stress at surface of shaft given shear strain energy in ring of radius 'r', enter Strain Energy in body (U), Modulus of rigidity of Shaft (G), Radius of Shaft (rshaft), Length of Shaft (L), Radius 'r' from Center Of Shaft (rcenter) & Length of Small Element (δx) and hit the calculate button. Here is how the Shear stress at surface of shaft given shear strain energy in ring of radius 'r' calculation can be explained with given input values -> 6.3E-9 = sqrt((50000*(2*40*(2^2)))/(2*pi*7*(1.5^3)*0.04336)).

FAQ

What is Shear stress at surface of shaft given shear strain energy in ring of radius 'r'?
Shear stress at surface of shaft given shear strain energy in ring of radius 'r' is a force tending to cause deformation of a material by slippage along a plane or planes parallel to the imposed stress and is represented as 𝜏 = sqrt((U*(2*G*(rshaft^2)))/(2*pi*L*(rcenter^3)*δx)) or Shear stress on surface of shaft = sqrt((Strain Energy in body*(2*Modulus of rigidity of Shaft*(Radius of Shaft^2)))/(2*pi*Length of Shaft*(Radius 'r' from Center Of Shaft^3)*Length of Small Element)). Strain Energy in body is defined as the energy stored in a body due to deformation, Modulus of rigidity of Shaft is the elastic coefficient when a shear force is applied resulting in lateral deformation. It gives us a measure of how rigid a body is, The Radius of Shaft is the radius of the shaft subjected under torsion, The Length of Shaft is the distance between two ends of shaft, Radius 'r' from Center Of Shaft is a radial line from the focus to any point of a curve & Length of Small Element is a measure of distance.
How to calculate Shear stress at surface of shaft given shear strain energy in ring of radius 'r'?
Shear stress at surface of shaft given shear strain energy in ring of radius 'r' is a force tending to cause deformation of a material by slippage along a plane or planes parallel to the imposed stress is calculated using Shear stress on surface of shaft = sqrt((Strain Energy in body*(2*Modulus of rigidity of Shaft*(Radius of Shaft^2)))/(2*pi*Length of Shaft*(Radius 'r' from Center Of Shaft^3)*Length of Small Element)). To calculate Shear stress at surface of shaft given shear strain energy in ring of radius 'r', you need Strain Energy in body (U), Modulus of rigidity of Shaft (G), Radius of Shaft (rshaft), Length of Shaft (L), Radius 'r' from Center Of Shaft (rcenter) & Length of Small Element (δx). With our tool, you need to enter the respective value for Strain Energy in body, Modulus of rigidity of Shaft, Radius of Shaft, Length of Shaft, Radius 'r' from Center Of Shaft & Length of Small Element 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 Shear stress on surface of shaft?
In this formula, Shear stress on surface of shaft uses Strain Energy in body, Modulus of rigidity of Shaft, Radius of Shaft, Length of Shaft, Radius 'r' from Center Of Shaft & Length of Small Element. We can use 3 other way(s) to calculate the same, which is/are as follows -
  • Shear stress on surface of shaft = Shear stress at radius 'r' from shaft/(Radius 'r' from Center Of Shaft/Radius of Shaft)
  • Shear stress on surface of shaft = sqrt((Strain Energy in body*2*Modulus of rigidity of Shaft)/Volume of Shaft)
  • Shear stress on surface of shaft = sqrt((Strain Energy in body*(2*Modulus of rigidity of Shaft*(Radius of Shaft^2)))/(Length of Shaft*Polar Moment of Inertia of shaft))
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