Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor Calculator

✖Tension in Main Spring at Maximum Speed is the maximum tension experienced by the main spring due to centrifugal force at the highest rotational velocity.ⓘ Tension in Main Spring at Maximum Speed [P₂]			+10% -10%
✖Mass on Sleeve is the amount of mass attached to the sleeve of a centrifuge, which experiences a centrifugal force when the centrifuge is spinning.ⓘ Mass on Sleeve [M]			+10% -10%
✖Acceleration due to Gravity is the downward force exerted on an object due to the gravitational attraction of a celestial body, such as the Earth.ⓘ Acceleration due to Gravity [g]			+10% -10%
✖Tension in Auxiliary Spring at Maximum Speed is the maximum tension experienced by the auxiliary spring due to centrifugal force at maximum rotational speed.ⓘ Tension in Auxiliary Spring at Maximum Speed [S₂]			+10% -10%
✖Distance of Auxiliary Spring from Mid of Lever is the length of the spring from the midpoint of the lever in a centrifugal force system.ⓘ Distance of Auxiliary Spring from Mid of Lever [b]			+10% -10%
✖Distance of Main Spring from Mid Point of Lever is the length of the main spring measured from the midpoint of the lever in a centrifugal force system.ⓘ Distance of Main Spring from Mid Point of Lever [a]			+10% -10%
✖Length of Sleeve Arm of Lever is the distance from the axis of rotation to the point where the centrifugal force is applied.ⓘ Length of Sleeve Arm of Lever [y]			+10% -10%
✖Length of Ball Arm of Lever is the distance from the axis of rotation to the point where the centrifugal force is applied.ⓘ Length of Ball Arm of Lever [x_{ball arm}]			+10% -10%

✖Centrifugal Force at Maximum Equilibrium Speed is the maximum force exerted on an object moving in a circular path at a constant velocity.ⓘ Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor [F_ec2]

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Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor Solution

STEP 0: Pre-Calculation Summary

Formula Used

Centrifugal Force at Maximum Equilibrium Speed = Tension in Main Spring at Maximum Speed+(Mass on Sleeve*Acceleration due to Gravity+(Tension in Auxiliary Spring at Maximum Speed*Distance of Auxiliary Spring from Mid of Lever)/Distance of Main Spring from Mid Point of Lever)*Length of Sleeve Arm of Lever/2*Length of Ball Arm of Lever
F_ec2 = P₂+(M*g+(S₂*b)/a)*y/2*x_{ball arm}
This formula uses 9 Variables

Variables Used

Centrifugal Force at Maximum Equilibrium Speed - (Measured in Newton) - Centrifugal Force at Maximum Equilibrium Speed is the maximum force exerted on an object moving in a circular path at a constant velocity.
Tension in Main Spring at Maximum Speed - (Measured in Newton) - Tension in Main Spring at Maximum Speed is the maximum tension experienced by the main spring due to centrifugal force at the highest rotational velocity.
Mass on Sleeve - (Measured in Kilogram) - Mass on Sleeve is the amount of mass attached to the sleeve of a centrifuge, which experiences a centrifugal force when the centrifuge is spinning.
Acceleration due to Gravity - (Measured in Meter per Square Second) - Acceleration due to Gravity is the downward force exerted on an object due to the gravitational attraction of a celestial body, such as the Earth.
Tension in Auxiliary Spring at Maximum Speed - (Measured in Newton) - Tension in Auxiliary Spring at Maximum Speed is the maximum tension experienced by the auxiliary spring due to centrifugal force at maximum rotational speed.
Distance of Auxiliary Spring from Mid of Lever - (Measured in Meter) - Distance of Auxiliary Spring from Mid of Lever is the length of the spring from the midpoint of the lever in a centrifugal force system.
Distance of Main Spring from Mid Point of Lever - (Measured in Meter) - Distance of Main Spring from Mid Point of Lever is the length of the main spring measured from the midpoint of the lever in a centrifugal force system.
Length of Sleeve Arm of Lever - (Measured in Meter) - Length of Sleeve Arm of Lever is the distance from the axis of rotation to the point where the centrifugal force is applied.
Length of Ball Arm of Lever - (Measured in Meter) - Length of Ball Arm of Lever is the distance from the axis of rotation to the point where the centrifugal force is applied.

STEP 1: Convert Input(s) to Base Unit

Tension in Main Spring at Maximum Speed: 12 Newton --> 12 Newton No Conversion Required
Mass on Sleeve: 2.67 Kilogram --> 2.67 Kilogram No Conversion Required
Acceleration due to Gravity: 9.8 Meter per Square Second --> 9.8 Meter per Square Second No Conversion Required
Tension in Auxiliary Spring at Maximum Speed: 28 Newton --> 28 Newton No Conversion Required
Distance of Auxiliary Spring from Mid of Lever: 3.26 Meter --> 3.26 Meter No Conversion Required
Distance of Main Spring from Mid Point of Lever: 0.2 Meter --> 0.2 Meter No Conversion Required
Length of Sleeve Arm of Lever: 1.2 Meter --> 1.2 Meter No Conversion Required
Length of Ball Arm of Lever: 0.6 Meter --> 0.6 Meter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

F_ec2 = P₂+(M*g+(S₂*b)/a)*y/2*x_{ball arm} --> 12+(2.67*9.8+(28*3.26)/0.2)*1.2/2*0.6

Evaluating ... ...

F_ec2 = 185.72376

STEP 3: Convert Result to Output's Unit

185.72376 Newton --> No Conversion Required

FINAL ANSWER

185.72376 ≈ 185.7238 Newton <-- Centrifugal Force at Maximum Equilibrium Speed

(Calculation completed in 00.004 seconds)

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< Centrifugal Force Calculators

Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor

LaTeX Go Centrifugal Force at Maximum Equilibrium Speed = Tension in Main Spring at Maximum Speed+(Mass on Sleeve*Acceleration due to Gravity+(Tension in Auxiliary Spring at Maximum Speed*Distance of Auxiliary Spring from Mid of Lever)/Distance of Main Spring from Mid Point of Lever)*Length of Sleeve Arm of Lever/2*Length of Ball Arm of Lever

Centrifugal Force at Minimum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor

LaTeX Go Centrifugal Force at Minimum Equilibrium Speed = Tension in Main Spring at Minimum Speed+(Mass on Sleeve*Acceleration due to Gravity+(Tension in Auxiliary Spring at Minimum Speed*Distance of Auxiliary Spring from Mid of Lever)/Distance of Main Spring from Mid Point of Lever)*Length of Sleeve Arm of Lever/2*Length of Ball Arm of Lever

Centrifugal Force at Maximum Radius of Rotation

LaTeX Go Centrifugal Force at Maximum Radius of Rotation = Mass of Ball*Angular Speed of Governor at Maximum Radius^2*Maximum Radius of Rotation

Centrifugal Force at Minimum Radius of Rotation

LaTeX Go Centrifugal Force at Minimum Radius of Rotation = Mass of Ball*Angular Speed of Governor at Minimum Radius^2*Minimum Radius of Rotation

Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor Formula

LaTeX Go

What is Equilibrium Speed?

Equilibrium speed is the constant speed at which a system remains balanced, with no net force or change in velocity. In this state, forces like friction, air resistance, or engine power are equal, resulting in steady motion without acceleration or deceleration. It's often used in the context of vehicles or mechanical systems.

How to Calculate Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor?

Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor calculator uses Centrifugal Force at Maximum Equilibrium Speed = Tension in Main Spring at Maximum Speed+(Mass on Sleeve*Acceleration due to Gravity+(Tension in Auxiliary Spring at Maximum Speed*Distance of Auxiliary Spring from Mid of Lever)/Distance of Main Spring from Mid Point of Lever)*Length of Sleeve Arm of Lever/2*Length of Ball Arm of Lever to calculate the Centrifugal Force at Maximum Equilibrium Speed, Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor formula is defined as the maximum force exerted on each ball of the governor at equilibrium speed, which is influenced by factors such as weight, ball arm length, and spring stiffness, playing a crucial role in the governor's stability and performance. Centrifugal Force at Maximum Equilibrium Speed is denoted by F_ec2 symbol.

How to calculate Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor using this online calculator? To use this online calculator for Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor, enter Tension in Main Spring at Maximum Speed (P₂), Mass on Sleeve (M), Acceleration due to Gravity (g), Tension in Auxiliary Spring at Maximum Speed (S₂), Distance of Auxiliary Spring from Mid of Lever (b), Distance of Main Spring from Mid Point of Lever (a), Length of Sleeve Arm of Lever (y) & Length of Ball Arm of Lever (x_{ball arm}) and hit the calculate button. Here is how the Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor calculation can be explained with given input values -> 191.5918 = 12+(2.67*9.8+(28*3.26)/0.2)*1.2/2*0.6.

FAQ

What is Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor?

Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor formula is defined as the maximum force exerted on each ball of the governor at equilibrium speed, which is influenced by factors such as weight, ball arm length, and spring stiffness, playing a crucial role in the governor's stability and performance and is represented as F_ec2 = P₂+(M*g+(S₂*b)/a)*y/2*x_{ball arm} or Centrifugal Force at Maximum Equilibrium Speed = Tension in Main Spring at Maximum Speed+(Mass on Sleeve*Acceleration due to Gravity+(Tension in Auxiliary Spring at Maximum Speed*Distance of Auxiliary Spring from Mid of Lever)/Distance of Main Spring from Mid Point of Lever)*Length of Sleeve Arm of Lever/2*Length of Ball Arm of Lever. Tension in Main Spring at Maximum Speed is the maximum tension experienced by the main spring due to centrifugal force at the highest rotational velocity, Mass on Sleeve is the amount of mass attached to the sleeve of a centrifuge, which experiences a centrifugal force when the centrifuge is spinning, Acceleration due to Gravity is the downward force exerted on an object due to the gravitational attraction of a celestial body, such as the Earth, Tension in Auxiliary Spring at Maximum Speed is the maximum tension experienced by the auxiliary spring due to centrifugal force at maximum rotational speed, Distance of Auxiliary Spring from Mid of Lever is the length of the spring from the midpoint of the lever in a centrifugal force system, Distance of Main Spring from Mid Point of Lever is the length of the main spring measured from the midpoint of the lever in a centrifugal force system, Length of Sleeve Arm of Lever is the distance from the axis of rotation to the point where the centrifugal force is applied & Length of Ball Arm of Lever is the distance from the axis of rotation to the point where the centrifugal force is applied.

How to calculate Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor?

Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor formula is defined as the maximum force exerted on each ball of the governor at equilibrium speed, which is influenced by factors such as weight, ball arm length, and spring stiffness, playing a crucial role in the governor's stability and performance is calculated using Centrifugal Force at Maximum Equilibrium Speed = Tension in Main Spring at Maximum Speed+(Mass on Sleeve*Acceleration due to Gravity+(Tension in Auxiliary Spring at Maximum Speed*Distance of Auxiliary Spring from Mid of Lever)/Distance of Main Spring from Mid Point of Lever)*Length of Sleeve Arm of Lever/2*Length of Ball Arm of Lever. To calculate Centrifugal Force at Maximum Equilibrium Speed on Each Ball for Wilson-Hartnell Governor, you need Tension in Main Spring at Maximum Speed (P₂), Mass on Sleeve (M), Acceleration due to Gravity (g), Tension in Auxiliary Spring at Maximum Speed (S₂), Distance of Auxiliary Spring from Mid of Lever (b), Distance of Main Spring from Mid Point of Lever (a), Length of Sleeve Arm of Lever (y) & Length of Ball Arm of Lever (x_{ball arm}). With our tool, you need to enter the respective value for Tension in Main Spring at Maximum Speed, Mass on Sleeve, Acceleration due to Gravity, Tension in Auxiliary Spring at Maximum Speed, Distance of Auxiliary Spring from Mid of Lever, Distance of Main Spring from Mid Point of Lever, Length of Sleeve Arm of Lever & Length of Ball Arm of Lever 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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