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Tensile Stress in Spokes of Rimmed Flywheel Calculator

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✖Tensile Force in Flywheel Rim is the maximum stress that a flywheel rim can withstand without breaking or deforming during its operation.ⓘ Tensile Force in Flywheel Rim [P]			+10% -10%
✖Width of Rim of Flywheel is the diameter of the rim of a flywheel, which is a heavy wheel attached to a rotating shaft.ⓘ Width of Rim of Flywheel [b_rim]			+10% -10%
✖Thickness of Rim of Flywheel is the distance from the outer edge of the rim to the inner edge of the rim of a flywheel.ⓘ Thickness of Rim of Flywheel [t_r]			+10% -10%
✖Bending moment in flywheel spokes is the rotational force that causes the flywheel to bend or deform, affecting its overall performance and stability.ⓘ Bending Moment in Flywheel Spokes [M]			+10% -10%

✖Tensile Stress in Spokes of Flywheel is the maximum stress that a spoke in a flywheel can withstand without breaking or deforming under various loads.ⓘ Tensile Stress in Spokes of Rimmed Flywheel [σt_s]

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Tensile Stress in Spokes of Rimmed Flywheel Solution

STEP 0: Pre-Calculation Summary

Formula Used

Tensile Stress in Spokes of Flywheel = Tensile Force in Flywheel Rim/(Width of Rim of Flywheel*Thickness of Rim of Flywheel)+(6*Bending Moment in Flywheel Spokes)/(Width of Rim of Flywheel*Thickness of Rim of Flywheel^2)
σt_s = P/(b_rim*t_r)+(6*M)/(b_rim*t_r^2)
This formula uses 5 Variables

Variables Used

Tensile Stress in Spokes of Flywheel - (Measured in Pascal) - Tensile Stress in Spokes of Flywheel is the maximum stress that a spoke in a flywheel can withstand without breaking or deforming under various loads.
Tensile Force in Flywheel Rim - (Measured in Newton) - Tensile Force in Flywheel Rim is the maximum stress that a flywheel rim can withstand without breaking or deforming during its operation.
Width of Rim of Flywheel - (Measured in Meter) - Width of Rim of Flywheel is the diameter of the rim of a flywheel, which is a heavy wheel attached to a rotating shaft.
Thickness of Rim of Flywheel - (Measured in Meter) - Thickness of Rim of Flywheel is the distance from the outer edge of the rim to the inner edge of the rim of a flywheel.
Bending Moment in Flywheel Spokes - (Measured in Newton Meter) - Bending moment in flywheel spokes is the rotational force that causes the flywheel to bend or deform, affecting its overall performance and stability.

STEP 1: Convert Input(s) to Base Unit

Tensile Force in Flywheel Rim: 1500 Newton --> 1500 Newton No Conversion Required
Width of Rim of Flywheel: 15 Millimeter --> 0.015 Meter (Check conversion here)
Thickness of Rim of Flywheel: 16 Millimeter --> 0.016 Meter (Check conversion here)
Bending Moment in Flywheel Spokes: 12000 Newton Millimeter --> 12 Newton Meter (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

σt_s = P/(b_rim*t_r)+(6*M)/(b_rim*t_r^2) --> 1500/(0.015*0.016)+(6*12)/(0.015*0.016^2)

Evaluating ... ...

σt_s = 25000000

STEP 3: Convert Result to Output's Unit

25000000 Pascal -->25 Newton per Square Millimeter (Check conversion here)

FINAL ANSWER

25 Newton per Square Millimeter <-- Tensile Stress in Spokes of Flywheel

(Calculation completed in 00.020 seconds)

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< 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

Tensile Stress in Spokes of Rimmed Flywheel Formula

LaTeX Go

What is Tensile Stress in Flywheel?

Tensile stress in a flywheel is the internal stress experienced by the material as it undergoes tension during rotation. This stress arises from the centrifugal forces generated when the flywheel spins, which tend to pull the material outward from the center. Tensile stress is critical in assessing the flywheel's structural integrity, as excessive tensile stress can lead to material failure or cracking. Proper design and material selection are essential to ensure that the flywheel can withstand these stresses while maintaining safe and efficient operation during its cycle.

How to Calculate Tensile Stress in Spokes of Rimmed Flywheel?

Tensile Stress in Spokes of Rimmed Flywheel calculator uses Tensile Stress in Spokes of Flywheel = Tensile Force in Flywheel Rim/(Width of Rim of Flywheel*Thickness of Rim of Flywheel)+(6*Bending Moment in Flywheel Spokes)/(Width of Rim of Flywheel*Thickness of Rim of Flywheel^2) to calculate the Tensile Stress in Spokes of Flywheel, Tensile Stress in Spokes of Rimmed Flywheel formula is defined as a measure of the maximum stress that the spokes of a rimmed flywheel can withstand without undergoing deformation or failure, which is critical in the design of flywheels to ensure their structural integrity and reliability. Tensile Stress in Spokes of Flywheel is denoted by σt_s symbol.

How to calculate Tensile Stress in Spokes of Rimmed Flywheel using this online calculator? To use this online calculator for Tensile Stress in Spokes of Rimmed Flywheel, enter Tensile Force in Flywheel Rim (P), Width of Rim of Flywheel (b_rim), Thickness of Rim of Flywheel (t_r) & Bending Moment in Flywheel Spokes (M) and hit the calculate button. Here is how the Tensile Stress in Spokes of Rimmed Flywheel calculation can be explained with given input values -> 2.5E-5 = 1500/(0.015*0.016)+(6*12)/(0.015*0.016^2).

FAQ

What is Tensile Stress in Spokes of Rimmed Flywheel?

Tensile Stress in Spokes of Rimmed Flywheel formula is defined as a measure of the maximum stress that the spokes of a rimmed flywheel can withstand without undergoing deformation or failure, which is critical in the design of flywheels to ensure their structural integrity and reliability and is represented as σt_s = P/(b_rim*t_r)+(6*M)/(b_rim*t_r^2) or Tensile Stress in Spokes of Flywheel = Tensile Force in Flywheel Rim/(Width of Rim of Flywheel*Thickness of Rim of Flywheel)+(6*Bending Moment in Flywheel Spokes)/(Width of Rim of Flywheel*Thickness of Rim of Flywheel^2). Tensile Force in Flywheel Rim is the maximum stress that a flywheel rim can withstand without breaking or deforming during its operation, Width of Rim of Flywheel is the diameter of the rim of a flywheel, which is a heavy wheel attached to a rotating shaft, Thickness of Rim of Flywheel is the distance from the outer edge of the rim to the inner edge of the rim of a flywheel & Bending moment in flywheel spokes is the rotational force that causes the flywheel to bend or deform, affecting its overall performance and stability.

How to calculate Tensile Stress in Spokes of Rimmed Flywheel?

Tensile Stress in Spokes of Rimmed Flywheel formula is defined as a measure of the maximum stress that the spokes of a rimmed flywheel can withstand without undergoing deformation or failure, which is critical in the design of flywheels to ensure their structural integrity and reliability is calculated using Tensile Stress in Spokes of Flywheel = Tensile Force in Flywheel Rim/(Width of Rim of Flywheel*Thickness of Rim of Flywheel)+(6*Bending Moment in Flywheel Spokes)/(Width of Rim of Flywheel*Thickness of Rim of Flywheel^2). To calculate Tensile Stress in Spokes of Rimmed Flywheel, you need Tensile Force in Flywheel Rim (P), Width of Rim of Flywheel (b_rim), Thickness of Rim of Flywheel (t_r) & Bending Moment in Flywheel Spokes (M). With our tool, you need to enter the respective value for Tensile Force in Flywheel Rim, Width of Rim of Flywheel, Thickness of Rim of Flywheel & Bending Moment in Flywheel Spokes 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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