Normal Force for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum (Anti Clock) Solution

STEP 0: Pre-Calculation Summary
Formula Used
Normal Force = (Force Applied at the End of the Lever*Distance b/w Fulcrum and End of Lever)/(Distance b/w Fulcrum and Axis of Wheel+Coefficient of Friction for Brake*Shift in Line of Action of Tangential Force)
Fn = (P*l)/(x+μbrake*ashift)
This formula uses 6 Variables
Variables Used
Normal Force - (Measured in Newton) - Normal Force is the force exerted by a surface against an object that is in contact with it, usually perpendicular to the surface.
Force Applied at the End of the Lever - (Measured in Newton) - Force Applied at the End of the Lever is the force exerted at the end of a lever, which is a rigid bar used to multiply force.
Distance b/w Fulcrum and End of Lever - (Measured in Meter) - Distance b/w Fulcrum and End of Lever is known as the lever arm or moment arm. It determines the lever's mechanical advantage by influencing the force required to lift or move an object.
Distance b/w Fulcrum and Axis of Wheel - (Measured in Meter) - Distance b/w Fulcrum and Axis of Wheel is the length of the line segment connecting the fulcrum and the axis of rotation of a wheel.
Coefficient of Friction for Brake - Coefficient of Friction for Brake is a dimensionless scalar value that characterizes the ratio of the frictional force to the normal force between two surfaces in contact.
Shift in Line of Action of Tangential Force - (Measured in Meter) - Shift in Line of Action of Tangential Force is the change in direction of the line of action of a tangential force acting on an object.
STEP 1: Convert Input(s) to Base Unit
Force Applied at the End of the Lever: 32 Newton --> 32 Newton No Conversion Required
Distance b/w Fulcrum and End of Lever: 1.1 Meter --> 1.1 Meter No Conversion Required
Distance b/w Fulcrum and Axis of Wheel: 2 Meter --> 2 Meter No Conversion Required
Coefficient of Friction for Brake: 0.35 --> No Conversion Required
Shift in Line of Action of Tangential Force: 3.5 Meter --> 3.5 Meter No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Fn = (P*l)/(x+μbrake*ashift) --> (32*1.1)/(2+0.35*3.5)
Evaluating ... ...
Fn = 10.9147286821705
STEP 3: Convert Result to Output's Unit
10.9147286821705 Newton --> No Conversion Required
FINAL ANSWER
10.9147286821705 10.91473 Newton <-- Normal Force
(Calculation completed in 00.004 seconds)

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Normal Force for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum (Anti Clock) Formula

​LaTeX ​Go
Normal Force = (Force Applied at the End of the Lever*Distance b/w Fulcrum and End of Lever)/(Distance b/w Fulcrum and Axis of Wheel+Coefficient of Friction for Brake*Shift in Line of Action of Tangential Force)
Fn = (P*l)/(x+μbrake*ashift)

What is Single Block or Shoe Brake?

A single block or shoe brake consists of a brake shoe that presses against a rotating wheel or drum to create friction and slow it down. It is a simple braking system, commonly used in applications like railway trains or industrial machines.






How to Calculate Normal Force for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum (Anti Clock)?

Normal Force for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum (Anti Clock) calculator uses Normal Force = (Force Applied at the End of the Lever*Distance b/w Fulcrum and End of Lever)/(Distance b/w Fulcrum and Axis of Wheel+Coefficient of Friction for Brake*Shift in Line of Action of Tangential Force) to calculate the Normal Force, Normal Force for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum (Anti Clock) formula is defined as the force exerted by the shoe brake on the wheel when the line of action of the tangential force passes above the fulcrum in an anticlockwise direction, which is essential in determining the braking efficiency of a vehicle. Normal Force is denoted by Fn symbol.

How to calculate Normal Force for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum (Anti Clock) using this online calculator? To use this online calculator for Normal Force for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum (Anti Clock), enter Force Applied at the End of the Lever (P), Distance b/w Fulcrum and End of Lever (l), Distance b/w Fulcrum and Axis of Wheel (x), Coefficient of Friction for Brake brake) & Shift in Line of Action of Tangential Force (ashift) and hit the calculate button. Here is how the Normal Force for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum (Anti Clock) calculation can be explained with given input values -> 10.91473 = (32*1.1)/(2+0.35*3.5).

FAQ

What is Normal Force for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum (Anti Clock)?
Normal Force for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum (Anti Clock) formula is defined as the force exerted by the shoe brake on the wheel when the line of action of the tangential force passes above the fulcrum in an anticlockwise direction, which is essential in determining the braking efficiency of a vehicle and is represented as Fn = (P*l)/(x+μbrake*ashift) or Normal Force = (Force Applied at the End of the Lever*Distance b/w Fulcrum and End of Lever)/(Distance b/w Fulcrum and Axis of Wheel+Coefficient of Friction for Brake*Shift in Line of Action of Tangential Force). Force Applied at the End of the Lever is the force exerted at the end of a lever, which is a rigid bar used to multiply force, Distance b/w Fulcrum and End of Lever is known as the lever arm or moment arm. It determines the lever's mechanical advantage by influencing the force required to lift or move an object, Distance b/w Fulcrum and Axis of Wheel is the length of the line segment connecting the fulcrum and the axis of rotation of a wheel, Coefficient of Friction for Brake is a dimensionless scalar value that characterizes the ratio of the frictional force to the normal force between two surfaces in contact & Shift in Line of Action of Tangential Force is the change in direction of the line of action of a tangential force acting on an object.
How to calculate Normal Force for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum (Anti Clock)?
Normal Force for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum (Anti Clock) formula is defined as the force exerted by the shoe brake on the wheel when the line of action of the tangential force passes above the fulcrum in an anticlockwise direction, which is essential in determining the braking efficiency of a vehicle is calculated using Normal Force = (Force Applied at the End of the Lever*Distance b/w Fulcrum and End of Lever)/(Distance b/w Fulcrum and Axis of Wheel+Coefficient of Friction for Brake*Shift in Line of Action of Tangential Force). To calculate Normal Force for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum (Anti Clock), you need Force Applied at the End of the Lever (P), Distance b/w Fulcrum and End of Lever (l), Distance b/w Fulcrum and Axis of Wheel (x), Coefficient of Friction for Brake brake) & Shift in Line of Action of Tangential Force (ashift). With our tool, you need to enter the respective value for Force Applied at the End of the Lever, Distance b/w Fulcrum and End of Lever, Distance b/w Fulcrum and Axis of Wheel, Coefficient of Friction for Brake & Shift in Line of Action of Tangential Force 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 Normal Force?
In this formula, Normal Force uses Force Applied at the End of the Lever, Distance b/w Fulcrum and End of Lever, Distance b/w Fulcrum and Axis of Wheel, Coefficient of Friction for Brake & Shift in Line of Action of Tangential Force. We can use 3 other way(s) to calculate the same, which is/are as follows -
  • Normal Force = (Force Applied at the End of the Lever*Distance b/w Fulcrum and End of Lever)/(Distance b/w Fulcrum and Axis of Wheel-Coefficient of Friction for Brake*Shift in Line of Action of Tangential Force)
  • Normal Force = (Force Applied at the End of the Lever*Distance b/w Fulcrum and End of Lever)/(Distance b/w Fulcrum and Axis of Wheel+Coefficient of Friction for Brake*Shift in Line of Action of Tangential Force)
  • Normal Force = (Force Applied at the End of the Lever*Distance b/w Fulcrum and End of Lever)/(Distance b/w Fulcrum and Axis of Wheel-Coefficient of Friction for Brake*Shift in Line of Action of Tangential Force)
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