Principle Shear Stress Maximum Shear Stress Theory of Failure Solution

STEP 0: Pre-Calculation Summary
Formula Used
Maximum Shear Stress in Shaft From ASME = 16/(pi*Diameter of Shaft From ASME^3)*sqrt((Torsional Moment in Shaft*Combined Shock Fatigue Factor of Torsion Moment)^2+(Combined Shock Fatigue Factor of Bending Moment*Bending Moment in Shaft)^2)
𝜏'max = 16/(pi*d'^3)*sqrt((M's*kt')^2+(kb'*Ms)^2)
This formula uses 1 Constants, 1 Functions, 6 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
Maximum Shear Stress in Shaft From ASME - (Measured in Pascal) - Maximum Shear Stress in Shaft From ASME is the maximum amount of shear stress arising due to shear forces and is calculated using ASME code for shaft design.
Diameter of Shaft From ASME - (Measured in Meter) - Diameter of Shaft From ASME is the required diameter of the shaft according to the American Society of Mechanical Engineers Code for shaft design.
Torsional Moment in Shaft - (Measured in Newton Meter) - Torsional Moment in Shaft is the reaction induced in a structural shaft element when an external force or moment is applied to the element, causing the element to twist.
Combined Shock Fatigue Factor of Torsion Moment - Combined Shock Fatigue Factor of Torsion Moment is a factor accounting for the combined shock and fatigue load applied with torsion moment.
Combined Shock Fatigue Factor of Bending Moment - Combined Shock Fatigue Factor of Bending Moment is a factor accounting for the combined shock and fatigue load applied with bending moment.
Bending Moment in Shaft - (Measured in Newton Meter) - Bending Moment in Shaft is the reaction induced in a structural shaft element when an external force or moment is applied to the element, causing the element to bend.
STEP 1: Convert Input(s) to Base Unit
Diameter of Shaft From ASME: 48 Millimeter --> 0.048 Meter (Check conversion ​here)
Torsional Moment in Shaft: 330000 Newton Millimeter --> 330 Newton Meter (Check conversion ​here)
Combined Shock Fatigue Factor of Torsion Moment: 1.3 --> No Conversion Required
Combined Shock Fatigue Factor of Bending Moment: 1.8 --> No Conversion Required
Bending Moment in Shaft: 1800000 Newton Millimeter --> 1800 Newton Meter (Check conversion ​here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
𝜏'max = 16/(pi*d'^3)*sqrt((M's*kt')^2+(kb'*Ms)^2) --> 16/(pi*0.048^3)*sqrt((330*1.3)^2+(1.8*1800)^2)
Evaluating ... ...
𝜏'max = 150510010.712373
STEP 3: Convert Result to Output's Unit
150510010.712373 Pascal -->150.510010712373 Newton per Square Millimeter (Check conversion ​here)
FINAL ANSWER
150.510010712373 150.51 Newton per Square Millimeter <-- Maximum Shear Stress in Shaft From ASME
(Calculation completed in 00.020 seconds)

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Osmania University (OU), Hyderabad
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ASME Code for Shaft Desgin Calculators

Equivalent Bending Moment when Shaft is Subjected to Fluctuating Loads
​ LaTeX ​ Go Equivalent Bending Moment For Fluctuating Load = Combined Shock Fatigue Factor of Bending Moment*Bending Moment in Shaft+sqrt((Torsional Moment in Shaft*Combined Shock Fatigue Factor of Torsion Moment)^2+(Combined Shock Fatigue Factor of Bending Moment*Bending Moment in Shaft)^2)
Diameter of Shaft given Principle Shear Stress
​ LaTeX ​ Go Diameter of Shaft From ASME = (16/(pi*Maximum Shear Stress in Shaft From ASME)*sqrt((Torsional Moment in Shaft*Combined Shock Fatigue Factor of Torsion Moment)^2+(Combined Shock Fatigue Factor of Bending Moment*Bending Moment in Shaft)^2))^(1/3)
Principle Shear Stress Maximum Shear Stress Theory of Failure
​ LaTeX ​ Go Maximum Shear Stress in Shaft From ASME = 16/(pi*Diameter of Shaft From ASME^3)*sqrt((Torsional Moment in Shaft*Combined Shock Fatigue Factor of Torsion Moment)^2+(Combined Shock Fatigue Factor of Bending Moment*Bending Moment in Shaft)^2)
Equivalent Torsional Moment when Shaft is Subjected to Fluctuating Loads
​ LaTeX ​ Go Equivalent Torsion Moment For Fluctuating Load = sqrt((Torsional Moment in Shaft*Combined Shock Fatigue Factor of Torsion Moment)^2+(Combined Shock Fatigue Factor of Bending Moment*Bending Moment in Shaft)^2)

Principle Shear Stress Maximum Shear Stress Theory of Failure Formula

​LaTeX ​Go
Maximum Shear Stress in Shaft From ASME = 16/(pi*Diameter of Shaft From ASME^3)*sqrt((Torsional Moment in Shaft*Combined Shock Fatigue Factor of Torsion Moment)^2+(Combined Shock Fatigue Factor of Bending Moment*Bending Moment in Shaft)^2)
𝜏'max = 16/(pi*d'^3)*sqrt((M's*kt')^2+(kb'*Ms)^2)

Define Maximum Shear Stress Theory of Failure

The Maximum Shear Stress theory states that failure occurs when the maximum shear stress from a combination of principal stresses equals or exceeds the value obtained for the shear stress at yielding in the uniaxial tensile test.

How to Calculate Principle Shear Stress Maximum Shear Stress Theory of Failure?

Principle Shear Stress Maximum Shear Stress Theory of Failure calculator uses Maximum Shear Stress in Shaft From ASME = 16/(pi*Diameter of Shaft From ASME^3)*sqrt((Torsional Moment in Shaft*Combined Shock Fatigue Factor of Torsion Moment)^2+(Combined Shock Fatigue Factor of Bending Moment*Bending Moment in Shaft)^2) to calculate the Maximum Shear Stress in Shaft From ASME, Principle Shear Stress Maximum Shear Stress Theory of Failure formula is defined as a method to determine the maximum shear stress in a shaft according to the ASME Code for Shaft Design, considering the torque and bending moment acting on the shaft, and providing a safe design criterion to prevent failure. Maximum Shear Stress in Shaft From ASME is denoted by 𝜏'max symbol.

How to calculate Principle Shear Stress Maximum Shear Stress Theory of Failure using this online calculator? To use this online calculator for Principle Shear Stress Maximum Shear Stress Theory of Failure, enter Diameter of Shaft From ASME (d'), Torsional Moment in Shaft (M's), Combined Shock Fatigue Factor of Torsion Moment (kt'), Combined Shock Fatigue Factor of Bending Moment (kb') & Bending Moment in Shaft (Ms) and hit the calculate button. Here is how the Principle Shear Stress Maximum Shear Stress Theory of Failure calculation can be explained with given input values -> 0.000151 = 16/(pi*0.048^3)*sqrt((330*1.3)^2+(1.8*1800)^2).

FAQ

What is Principle Shear Stress Maximum Shear Stress Theory of Failure?
Principle Shear Stress Maximum Shear Stress Theory of Failure formula is defined as a method to determine the maximum shear stress in a shaft according to the ASME Code for Shaft Design, considering the torque and bending moment acting on the shaft, and providing a safe design criterion to prevent failure and is represented as 𝜏'max = 16/(pi*d'^3)*sqrt((M's*kt')^2+(kb'*Ms)^2) or Maximum Shear Stress in Shaft From ASME = 16/(pi*Diameter of Shaft From ASME^3)*sqrt((Torsional Moment in Shaft*Combined Shock Fatigue Factor of Torsion Moment)^2+(Combined Shock Fatigue Factor of Bending Moment*Bending Moment in Shaft)^2). Diameter of Shaft From ASME is the required diameter of the shaft according to the American Society of Mechanical Engineers Code for shaft design, Torsional Moment in Shaft is the reaction induced in a structural shaft element when an external force or moment is applied to the element, causing the element to twist, Combined Shock Fatigue Factor of Torsion Moment is a factor accounting for the combined shock and fatigue load applied with torsion moment, Combined Shock Fatigue Factor of Bending Moment is a factor accounting for the combined shock and fatigue load applied with bending moment & Bending Moment in Shaft is the reaction induced in a structural shaft element when an external force or moment is applied to the element, causing the element to bend.
How to calculate Principle Shear Stress Maximum Shear Stress Theory of Failure?
Principle Shear Stress Maximum Shear Stress Theory of Failure formula is defined as a method to determine the maximum shear stress in a shaft according to the ASME Code for Shaft Design, considering the torque and bending moment acting on the shaft, and providing a safe design criterion to prevent failure is calculated using Maximum Shear Stress in Shaft From ASME = 16/(pi*Diameter of Shaft From ASME^3)*sqrt((Torsional Moment in Shaft*Combined Shock Fatigue Factor of Torsion Moment)^2+(Combined Shock Fatigue Factor of Bending Moment*Bending Moment in Shaft)^2). To calculate Principle Shear Stress Maximum Shear Stress Theory of Failure, you need Diameter of Shaft From ASME (d'), Torsional Moment in Shaft (M's), Combined Shock Fatigue Factor of Torsion Moment (kt'), Combined Shock Fatigue Factor of Bending Moment (kb') & Bending Moment in Shaft (Ms). With our tool, you need to enter the respective value for Diameter of Shaft From ASME, Torsional Moment in Shaft, Combined Shock Fatigue Factor of Torsion Moment, Combined Shock Fatigue Factor of Bending Moment & Bending Moment in Shaft 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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