HCF calculator

Maximum Radial or Tensile Stress in Flywheel Calculator

Physics Chemistry Engineering Financial More >>

↳

Mechanical Aerospace Basic Physics Others and Extra

⤿

Design of Automobile Elements Automobile Design of Machine Elements Fluid Mechanics More >>

⤿

Design of Flywheel Design of Brakes Design of Chain Drives Design of Friction Clutches More >>

✖Mass Density of Flywheel is the measure of mass per unit volume of a flywheel, which affects its rotational inertia and overall performance.ⓘ Mass Density of Flywheel [ρ]			+10% -10%
✖Peripheral Speed of Flywheel is the linear velocity of the flywheel's rim, which is a critical parameter in designing and optimizing flywheel performance.ⓘ Peripheral Speed of Flywheel [V_p]			+10% -10%
✖Poisson Ratio for Flywheel is the ratio of lateral contraction to longitudinal extension of a material in the flywheel's rim and hub under different loads.ⓘ Poisson Ratio for Flywheel [u]			+10% -10%

✖Maximum Radial Tensile Stress in Flywheel is the maximum stress that occurs in the rim of a flywheel due to centrifugal force during rotation.ⓘ Maximum Radial or Tensile Stress in Flywheel [σ_t,max]

⎘ Copy

👎

Formula

LaTeX

Reset

👍

Download Design of Flywheel Formulas PDF PDF Image

Maximum Radial or Tensile Stress in Flywheel Solution

STEP 0: Pre-Calculation Summary

Formula Used

Maximum Radial Tensile Stress in Flywheel = Mass Density of Flywheel*Peripheral Speed of Flywheel^2*((3+Poisson Ratio for Flywheel)/8)
σ_t,max = ρ*V_p^2*((3+u)/8)
This formula uses 4 Variables

Variables Used

Maximum Radial Tensile Stress in Flywheel - (Measured in Pascal) - Maximum Radial Tensile Stress in Flywheel is the maximum stress that occurs in the rim of a flywheel due to centrifugal force during rotation.
Mass Density of Flywheel - (Measured in Kilogram per Cubic Meter) - Mass Density of Flywheel is the measure of mass per unit volume of a flywheel, which affects its rotational inertia and overall performance.
Peripheral Speed of Flywheel - (Measured in Meter per Second) - Peripheral Speed of Flywheel is the linear velocity of the flywheel's rim, which is a critical parameter in designing and optimizing flywheel performance.
Poisson Ratio for Flywheel - Poisson Ratio for Flywheel is the ratio of lateral contraction to longitudinal extension of a material in the flywheel's rim and hub under different loads.

STEP 1: Convert Input(s) to Base Unit

Mass Density of Flywheel: 7800 Kilogram per Cubic Meter --> 7800 Kilogram per Cubic Meter No Conversion Required
Peripheral Speed of Flywheel: 10.35 Meter per Second --> 10.35 Meter per Second No Conversion Required
Poisson Ratio for Flywheel: 0.3 --> No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

σ_t,max = ρ*V_p^2*((3+u)/8) --> 7800*10.35^2*((3+0.3)/8)

Evaluating ... ...

σ_t,max = 344666.64375

STEP 3: Convert Result to Output's Unit

344666.64375 Pascal -->0.34466664375 Newton per Square Millimeter (Check conversion here)

FINAL ANSWER

0.34466664375 ≈ 0.344667 Newton per Square Millimeter <-- Maximum Radial Tensile Stress in Flywheel

(Calculation completed in 00.004 seconds)

You are here -

Home » Physics » Design of Automobile Elements » Mechanical » Design of Flywheel » Maximum Radial or Tensile Stress in Flywheel

Credits

Created by Akshay Talbar

Vishwakarma University (VU), Pune

Akshay Talbar has created this Calculator and 25+ more calculators!

Verified by Anshika Arya

National Institute Of Technology (NIT), Hamirpur

Anshika Arya has verified this Calculator and 2500+ more calculators!

< Design of Flywheel Calculators

Coefficient of Fluctuation of Flywheel Speed given Mean Speed

LaTeX Go Coefficient of Fluctuation of Flywheel Speed = (Maximum Angular Speed of Flywheel-Minimum Angular Speed of Flywheel)/Mean Angular Speed of Flywheel

Energy Output from Flywheel

LaTeX Go Energy Output From Flywheel = Moment of Inertia of Flywheel*Mean Angular Speed of Flywheel^2*Coefficient of Fluctuation of Flywheel Speed

Moment of Inertia of Flywheel

LaTeX Go Moment of Inertia of Flywheel = (Driving Input Torque of Flywheel-Load Output Torque of Flywheel)/Angular Acceleration of Flywheel

Mean Angular Velocity of Flywheel

LaTeX Go Mean Angular Speed of Flywheel = (Maximum Angular Speed of Flywheel+Minimum Angular Speed of Flywheel)/2

Maximum Radial or Tensile Stress in Flywheel Formula

LaTeX Go

Maximum Radial Tensile Stress in Flywheel = Mass Density of Flywheel*Peripheral Speed of Flywheel^2*((3+Poisson Ratio for Flywheel)/8)
σ_t,max = ρ*V_p^2*((3+u)/8)

What is Tensile Stress in Flywheel ?

Tensile stress in a flywheel refers to the internal force per unit area experienced by the flywheel material as it rotates. This stress occurs due to the centrifugal forces acting on the flywheel, especially at high speeds, which try to pull the material outward. If the tensile stress exceeds the material's strength, it can lead to cracks or failure. Proper design and material selection help ensure the flywheel can withstand these stresses while maintaining structural integrity during operation.

How to Calculate Maximum Radial or Tensile Stress in Flywheel?

Maximum Radial or Tensile Stress in Flywheel calculator uses Maximum Radial Tensile Stress in Flywheel = Mass Density of Flywheel*Peripheral Speed of Flywheel^2*((3+Poisson Ratio for Flywheel)/8) to calculate the Maximum Radial Tensile Stress in Flywheel, Maximum Radial or Tensile Stress in Flywheel formula is defined as the maximum stress that occurs in a flywheel due to the rotation of the flywheel, which is a critical parameter in the design of flywheels to ensure their structural integrity and prevent failure. Maximum Radial Tensile Stress in Flywheel is denoted by σ_t,max symbol.

How to calculate Maximum Radial or Tensile Stress in Flywheel using this online calculator? To use this online calculator for Maximum Radial or Tensile Stress in Flywheel, enter Mass Density of Flywheel (ρ), Peripheral Speed of Flywheel (V_p) & Poisson Ratio for Flywheel (u) and hit the calculate button. Here is how the Maximum Radial or Tensile Stress in Flywheel calculation can be explained with given input values -> 3.4E-7 = 7800*10.35^2*((3+0.3)/8).

FAQ

What is Maximum Radial or Tensile Stress in Flywheel?

Maximum Radial or Tensile Stress in Flywheel formula is defined as the maximum stress that occurs in a flywheel due to the rotation of the flywheel, which is a critical parameter in the design of flywheels to ensure their structural integrity and prevent failure and is represented as σ_t,max = ρ*V_p^2*((3+u)/8) or Maximum Radial Tensile Stress in Flywheel = Mass Density of Flywheel*Peripheral Speed of Flywheel^2*((3+Poisson Ratio for Flywheel)/8). Mass Density of Flywheel is the measure of mass per unit volume of a flywheel, which affects its rotational inertia and overall performance, Peripheral Speed of Flywheel is the linear velocity of the flywheel's rim, which is a critical parameter in designing and optimizing flywheel performance & Poisson Ratio for Flywheel is the ratio of lateral contraction to longitudinal extension of a material in the flywheel's rim and hub under different loads.

How to calculate Maximum Radial or Tensile Stress in Flywheel?

Maximum Radial or Tensile Stress in Flywheel formula is defined as the maximum stress that occurs in a flywheel due to the rotation of the flywheel, which is a critical parameter in the design of flywheels to ensure their structural integrity and prevent failure is calculated using Maximum Radial Tensile Stress in Flywheel = Mass Density of Flywheel*Peripheral Speed of Flywheel^2*((3+Poisson Ratio for Flywheel)/8). To calculate Maximum Radial or Tensile Stress in Flywheel, you need Mass Density of Flywheel (ρ), Peripheral Speed of Flywheel (V_p) & Poisson Ratio for Flywheel (u). With our tool, you need to enter the respective value for Mass Density of Flywheel, Peripheral Speed of Flywheel & Poisson Ratio for Flywheel and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

Home

FREE PDFs

🔍 Search