Braking Torque for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum Anti Clock Solution

STEP 0: Pre-Calculation Summary
Formula Used
Braking or Fixing Torque on Fixed Member = (Coefficient of Friction For Brake*Radius of Wheel*Force Applied at The End of The Lever*Distance Between Fulcrum And End of Lever)/(Distance Between Fulcrum And Axis of Wheel+Coefficient of Friction For Brake*Shift in Line of Action of Tangential Force)
Mt = (μb*rw*P*l)/(x+μb*as)
This formula uses 7 Variables
Variables Used
Braking or Fixing Torque on Fixed Member - (Measured in Newton Meter) - Braking or Fixing Torque on Fixed Member is the measure of the force that can cause an object to rotate about an axis.
Coefficient of Friction For Brake - Coefficient of Friction For Brake is the ratio defining the force that resists the motion of one body in relation to another body in contact with it.
Radius of Wheel - (Measured in Meter) - The Radius of Wheel is any of the line segments from its center to its perimeter, and in more modern usage, it is also their length.
Force Applied at The End of The Lever - (Measured in Newton) - Force Applied at The End of The Lever is any interaction that, when unopposed, will change the motion of an object.
Distance Between Fulcrum And End of Lever - (Measured in Meter) - Distance Between Fulcrum And End of Lever is a numerical measurement of how far apart objects or points are.
Distance Between Fulcrum And Axis of Wheel - (Measured in Meter) - Distance Between Fulcrum And Axis of Wheel is the distance between fulcrum and the vertical axis passing through mid of wheel.
Shift in Line of Action of Tangential Force - (Measured in Meter) - Shift in Line of Action of Tangential Force is the distance moved by line of action of tangential braking force above/below fulcrum.
STEP 1: Convert Input(s) to Base Unit
Coefficient of Friction For Brake: 0.35 --> No Conversion Required
Radius of Wheel: 1.89 Meter --> 1.89 Meter No Conversion Required
Force Applied at The End of The Lever: 16 Newton --> 16 Newton No Conversion Required
Distance Between Fulcrum And End of Lever: 1.1 Meter --> 1.1 Meter No Conversion Required
Distance Between Fulcrum And Axis of Wheel: 5 Meter --> 5 Meter 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
Mt = (μb*rw*P*l)/(x+μb*as) --> (0.35*1.89*16*1.1)/(5+0.35*3.5)
Evaluating ... ...
Mt = 1.87026506024096
STEP 3: Convert Result to Output's Unit
1.87026506024096 Newton Meter --> No Conversion Required
FINAL ANSWER
1.87026506024096 1.870265 Newton Meter <-- Braking or Fixing Torque on Fixed Member
(Calculation completed in 00.004 seconds)

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Braking Torque Calculators

Braking Torque for Pivoted Block or Shoe Brake
​ LaTeX ​ Go Braking or Fixing Torque on Fixed Member = Equivalent Coefficient of Friction*Normal Force Pressing The Brake Block on The Wheel*Radius of Wheel
Braking Torque for Band and Block Brake, Considering Thickness of Band
​ LaTeX ​ Go Braking or Fixing Torque on Fixed Member = (Tension in Tight Side of The Band-Tension in The Slack Side of Band)*Effective Radius of The Drum
Braking Torque for Band and Block Brake, Neglecting Thickness of Band
​ LaTeX ​ Go Braking or Fixing Torque on Fixed Member = (Tension in Tight Side of The Band-Tension in The Slack Side of Band)*Radius of The Drum
Braking Torque for Double Block or Shoe Brake
​ LaTeX ​ Go Braking or Fixing Torque on Fixed Member = (Braking Forces on The Block 1+Braking Forces on The Block 2)*Radius of Wheel

Braking Torque for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum Anti Clock Formula

​LaTeX ​Go
Braking or Fixing Torque on Fixed Member = (Coefficient of Friction For Brake*Radius of Wheel*Force Applied at The End of The Lever*Distance Between Fulcrum And End of Lever)/(Distance Between Fulcrum And Axis of Wheel+Coefficient of Friction For Brake*Shift in Line of Action of Tangential Force)
Mt = (μb*rw*P*l)/(x+μb*as)

What is single block or shoe brake?

A single block or shoe brake consists of a block or shoe which is pressed against the rim of a revolving brake wheel drum. The block is made of a softer material than the rim of the wheel.

How to Calculate Braking Torque for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum Anti Clock?

Braking Torque for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum Anti Clock calculator uses Braking or Fixing Torque on Fixed Member = (Coefficient of Friction For Brake*Radius of Wheel*Force Applied at The End of The Lever*Distance Between Fulcrum And End of Lever)/(Distance Between Fulcrum And Axis of Wheel+Coefficient of Friction For Brake*Shift in Line of Action of Tangential Force) to calculate the Braking or Fixing Torque on Fixed Member, Braking Torque for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum Anti Clock formula is defined as the rotational force that slows or stops the motion of a wheel or gear in a mechanical system, typically used in vehicle braking systems to convert kinetic energy into heat energy. Braking or Fixing Torque on Fixed Member is denoted by Mt symbol.

How to calculate Braking Torque 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 Braking Torque for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum Anti Clock, enter Coefficient of Friction For Brake b), Radius of Wheel (rw), Force Applied at The End of The Lever (P), Distance Between Fulcrum And End of Lever (l), Distance Between Fulcrum And Axis of Wheel (x) & Shift in Line of Action of Tangential Force (as) and hit the calculate button. Here is how the Braking Torque for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum Anti Clock calculation can be explained with given input values -> 1.870265 = (0.35*1.89*16*1.1)/(5+0.35*3.5).

FAQ

What is Braking Torque for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum Anti Clock?
Braking Torque for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum Anti Clock formula is defined as the rotational force that slows or stops the motion of a wheel or gear in a mechanical system, typically used in vehicle braking systems to convert kinetic energy into heat energy and is represented as Mt = (μb*rw*P*l)/(x+μb*as) or Braking or Fixing Torque on Fixed Member = (Coefficient of Friction For Brake*Radius of Wheel*Force Applied at The End of The Lever*Distance Between Fulcrum And End of Lever)/(Distance Between Fulcrum And Axis of Wheel+Coefficient of Friction For Brake*Shift in Line of Action of Tangential Force). Coefficient of Friction For Brake is the ratio defining the force that resists the motion of one body in relation to another body in contact with it, The Radius of Wheel is any of the line segments from its center to its perimeter, and in more modern usage, it is also their length, Force Applied at The End of The Lever is any interaction that, when unopposed, will change the motion of an object, Distance Between Fulcrum And End of Lever is a numerical measurement of how far apart objects or points are, Distance Between Fulcrum And Axis of Wheel is the distance between fulcrum and the vertical axis passing through mid of wheel & Shift in Line of Action of Tangential Force is the distance moved by line of action of tangential braking force above/below fulcrum.
How to calculate Braking Torque for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum Anti Clock?
Braking Torque for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum Anti Clock formula is defined as the rotational force that slows or stops the motion of a wheel or gear in a mechanical system, typically used in vehicle braking systems to convert kinetic energy into heat energy is calculated using Braking or Fixing Torque on Fixed Member = (Coefficient of Friction For Brake*Radius of Wheel*Force Applied at The End of The Lever*Distance Between Fulcrum And End of Lever)/(Distance Between Fulcrum And Axis of Wheel+Coefficient of Friction For Brake*Shift in Line of Action of Tangential Force). To calculate Braking Torque for Shoe Brake if Line of Action of Tangential Force Passes above Fulcrum Anti Clock, you need Coefficient of Friction For Brake b), Radius of Wheel (rw), Force Applied at The End of The Lever (P), Distance Between Fulcrum And End of Lever (l), Distance Between Fulcrum And Axis of Wheel (x) & Shift in Line of Action of Tangential Force (as). With our tool, you need to enter the respective value for Coefficient of Friction For Brake, Radius of Wheel, Force Applied at The End of The Lever, Distance Between Fulcrum And End of Lever, Distance Between Fulcrum And Axis of Wheel & 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 Braking or Fixing Torque on Fixed Member?
In this formula, Braking or Fixing Torque on Fixed Member uses Coefficient of Friction For Brake, Radius of Wheel, Force Applied at The End of The Lever, Distance Between Fulcrum And End of Lever, Distance Between Fulcrum And Axis of Wheel & Shift in Line of Action of Tangential Force. We can use 3 other way(s) to calculate the same, which is/are as follows -
  • Braking or Fixing Torque on Fixed Member = (Braking Forces on The Block 1+Braking Forces on The Block 2)*Radius of Wheel
  • Braking or Fixing Torque on Fixed Member = Equivalent Coefficient of Friction*Normal Force Pressing The Brake Block on The Wheel*Radius of Wheel
  • Braking or Fixing Torque on Fixed Member = (Tension in Tight Side of The Band-Tension in The Slack Side of Band)*Effective Radius of The Drum
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