Anshika Arya
National Institute Of Technology (NIT), Hamirpur
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Payal Priya
Birsa Institute of Technology (BIT), Sindri
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11 Other formulas that calculate the same Output

Moment of Inertia when Strain Energy in Bending is Given
Moment of Inertia=Length*(Bending moment^2)/(2*Strain Energy*Modulus Of Elasticity) Go
Smallest Moment of Inertia Allowable at Worst Section for Low Carbon Steel
Moment of Inertia=Allowable Load*(Length of column^2) Go
Smallest Moment of Inertia Allowable at Worst Section for Cast Iron
Moment of Inertia=Allowable Load*(Length of column^2) Go
Moment of inertia of bob of pendulum, about an axis through the point of suspension
Moment of Inertia=Mass*(Length of the string^2) Go
Moment of Inertia of a rod about an axis through its center of mass and perpendicular to rod
Moment of Inertia=(Mass*(Length of rod^2))/12 Go
Moment of Inertia of a solid sphere about its diameter
Moment of Inertia=2*(Mass*(Radius 1^2))/5 Go
Moment of inertia of a circular disc about an axis through its center and perpendicular to its plane
Moment of Inertia=(Mass*(Radius 1^2))/2 Go
Moment of Inertia of a right circular solid cylinder about its symmetry axis
Moment of Inertia=(Mass*(Radius 1^2))/2 Go
Moment of Inertia of a spherical shell about its diameter
Moment of Inertia=2*(Mass*(Radius 1))/3 Go
Moment of Inertia of a right circular hollow cylinder about its axis
Moment of Inertia=(Mass*(Radius 1)^2) Go
Moment of inertia of a circular ring about an axis through its center and perpendicular to its plane
Moment of Inertia=Mass*(Radius 1^2) Go

Moment of inertia of pickering governor cross-section about the neutral axis Formula

Moment of Inertia=(Width of spring*Thickness of spring^3)/12
I=(b*t^3)/12
More formulas
Height of the watt governor Go
Force in the arm (porter governor) when weight of central load and ball are given Go
Force in the arm (porter governor) when mass of central load and ball are given Go
Force in the arm (porter governor) when force in the link is known Go
Force in the link (porter governor) when mass of central load is known Go
Force in the link (porter governor) when weight of central load is known Go
Force in the arm (porter governor) when centrifugal force on ball is given Go
Angle of inclination of the arm to the vertical (porter governor) Go
Ratio of length of arm to the length of link Go
Height of the governor (porter governor, q=1) Go
Height of the governor (porter governor) Go
Speed of the ball in rpm (porter governor) when the length of arms are equal to the length of links Go
Lift of the sleeve at minimum radius of rotation(Hartnell governor) Go
Lift of the sleeve at maximum radius of rotation(Hartnell governor) Go
Total lift of the sleeve(Hartnell governor) when maximum and the minimum lift is known Go
Total lift of the sleeve(Hartnell governor) Go
Stiffness of the spring (Hartnell governor) when the total lift is given Go
Stiffness of the spring or the force required to compress the spring by one mm(Hartnell governor) Go
Stiffness of the spring when centrifugal force when min and max radius is known(Hartnell governor) Go
Stiffness of the spring when centrifugal force at minimum radius is known(Hartnell governor) Go
Stiffness of the spring when centrifugal force at maximum radius is known(Hartnell governor) Go
Centrifugal force at minimum radius of rotation Go
Centrifugal force at maximum radius of rotation Go
The centrifugal force for any intermediate position (Hartnell governor) Go
The centrifugal force for any intermediate position (Hartnell governor) Go
Centrifugal force for Hartung governor Go
Total downward force on the sleeve in wilson-hartnell governor Go
Centrifugal force on each ball for wilson-hartnell governor Go
Centrifugal force at minimum equilibrium speed on each ball for wilson-hartnell governor Go
Centrifugal force at maximum equilibrium speed on each ball for wilson-hartnell governor Go
Stiffness of each ball spring Go
Deflection of the center of the leaf spring in pickering governor Go
Deflection of the center of the leaf spring in pickering governor Go
Lift of the sleeve corresponding to the deflection Go
Centrifugal force for pickering governor Go
Sensitiveness of the governor when angular speed in r.p.m is given Go
Sensitiveness of the governor when angular speed in r.p.m is given Go
Sensitiveness of the governor when angular speed is given Go
Sensitiveness of the governor when angular speed is given Go
Effort of a porter governor(if angle made by upper and lower arms are equal) Go
Power of a porter governor(if angle made by upper and lower arms are equal) Go
Power of a porter governor(if angle made by upper and lower arms are not equal) Go
Controlling force for porter governor Go
Controlling force for porter governor Go
Speed of the rotation in rpm Go
Angle b/w the axis of radius of rotation and line joining a point on the curve to the origin O Go
Net increase in speed of porter governor Go
Sleeve load for increase in speed value (taking friction into account) Go
Sleeve load for decrease in speed value (taking friction into account) Go
Value of Controlling force for decrease in speed Go
Value of Controlling force for increase in speed Go
Corresponding radial force required at each ball for the porter governor Go
Corresponding radial force required at each ball for spring loaded governors Go
Coefficient of insensitiveness Go
Coefficient of insensitiveness Go
Coefficient of insensitiveness when lower arm is not attached on the governor axis(Porter governor) Go
Coefficient of insensitiveness when all the arms of porter governor are attached to governor axis Go
Coefficient of insensitiveness for porter governor(if angle made by upper and lower arm are equal) Go
Coefficient of insensitiveness for porter governor(if angle made by upper & lower arm aren't equal) Go
Coefficient of insensitiveness for the Hartnell governor Go
Mean equilibrium angular speed Go
Mean equilibrium speed in r.p.m Go
Lift of the sleeve for porter governor (if angle made by upper and lower arms are not equal) Go
Governor power Go
Increased speed Go
Effort of a porter governor(if angle made by upper and lower arms are not equal) Go
Lift of the sleeve for porter governor (if angle made by upper and lower arms are equal) Go
Angle b/w the axis of radius of rotation and line joining a point on the curve to the origin O Go
The relation between the controlling force and the radius of rotation for isochronous governors Go
The relation b/w controlling force and radius of rotation for stability of governor Go
The relation b/w controlling force and radius of rotation for the unstability of governor Go

What is inertia and moment of inertia?

The moment of inertia is a physical quantity that describes how easily a body can be rotated about a given axis. Inertia is the property of matter which resists change in its state of motion. Inertia is a measure of the force that keeps a stationary object stationary, or a moving object moving at its current speed.

How to Calculate Moment of inertia of pickering governor cross-section about the neutral axis?

Moment of inertia of pickering governor cross-section about the neutral axis calculator uses Moment of Inertia=(Width of spring*Thickness of spring^3)/12 to calculate the Moment of Inertia, The Moment of inertia of pickering governor cross-section about the neutral axis formula is defined as the quantity expressed by the body resisting angular acceleration which is the sum of the product of the mass of every particle with its square of a distance from the axis of rotation. Moment of Inertia and is denoted by I symbol.

How to calculate Moment of inertia of pickering governor cross-section about the neutral axis using this online calculator? To use this online calculator for Moment of inertia of pickering governor cross-section about the neutral axis, enter Width of spring (b) and Thickness of spring (t) and hit the calculate button. Here is how the Moment of inertia of pickering governor cross-section about the neutral axis calculation can be explained with given input values -> 2.667E-12 = (0.004*0.002^3)/12.

FAQ

What is Moment of inertia of pickering governor cross-section about the neutral axis?
The Moment of inertia of pickering governor cross-section about the neutral axis formula is defined as the quantity expressed by the body resisting angular acceleration which is the sum of the product of the mass of every particle with its square of a distance from the axis of rotation and is represented as I=(b*t^3)/12 or Moment of Inertia=(Width of spring*Thickness of spring^3)/12. Width of spring is the measurement or extent of something from side to side. and Thickness of spring is the distance through an object, as distinct from width or height.
How to calculate Moment of inertia of pickering governor cross-section about the neutral axis?
The Moment of inertia of pickering governor cross-section about the neutral axis formula is defined as the quantity expressed by the body resisting angular acceleration which is the sum of the product of the mass of every particle with its square of a distance from the axis of rotation is calculated using Moment of Inertia=(Width of spring*Thickness of spring^3)/12. To calculate Moment of inertia of pickering governor cross-section about the neutral axis, you need Width of spring (b) and Thickness of spring (t). With our tool, you need to enter the respective value for Width of spring and Thickness of spring 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 Moment of Inertia?
In this formula, Moment of Inertia uses Width of spring and Thickness of spring. We can use 11 other way(s) to calculate the same, which is/are as follows -
  • Moment of Inertia=(Mass*(Length of rod^2))/12
  • Moment of Inertia=Mass*(Radius 1^2)
  • Moment of Inertia=(Mass*(Radius 1^2))/2
  • Moment of Inertia=(Mass*(Radius 1^2))/2
  • Moment of Inertia=(Mass*(Radius 1)^2)
  • Moment of Inertia=2*(Mass*(Radius 1^2))/5
  • Moment of Inertia=2*(Mass*(Radius 1))/3
  • Moment of Inertia=Mass*(Length of the string^2)
  • Moment of Inertia=Length*(Bending moment^2)/(2*Strain Energy*Modulus Of Elasticity)
  • Moment of Inertia=Allowable Load*(Length of column^2)
  • Moment of Inertia=Allowable Load*(Length of column^2)
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