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## Length of Minor Axis in terms of Torque Transmitted by the pulley and Bending Stress Solution

STEP 0: Pre-Calculation Summary
Formula Used
minor_axis = (16*Torque Transmitted by the Pulley/(pi*Number of arms*Bending Stress))^(1/3)
b = (16*Mt/(pi*A*𝛔b))^(1/3)
This formula uses 1 Constants, 3 Variables
Constants Used
pi - Archimedes' constant Value Taken As 3.14159265358979323846264338327950288
Variables Used
Torque Transmitted by the Pulley - Torque Transmitted by the Pulley is the amount of torque transmitted by the pulley. (Measured in Newton Millimeter)
Number of arms- Number of arms in rotary distributor assembly
Bending Stress - The Bending Stress is the normal stress that is induced at a point in a body subjected to loads that cause it to bend (Measured in Newton per Square Meter)
STEP 1: Convert Input(s) to Base Unit
Torque Transmitted by the Pulley: 100 Newton Millimeter --> 0.1 Newton Meter (Check conversion here)
Number of arms: 2 --> No Conversion Required
Bending Stress: 50 Newton per Square Meter --> 50 Pascal (Check conversion here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
b = (16*Mt/(pi*A*𝛔b))^(1/3) --> (16*0.1/(pi*2*50))^(1/3)
Evaluating ... ...
b = 0.17205080276562
STEP 3: Convert Result to Output's Unit
0.17205080276562 Meter -->17.205080276562 Centimeter (Check conversion here)
17.205080276562 Centimeter <-- Minor axis
(Calculation completed in 00.016 seconds)

## < 10+ Arms of Cast Iron Pulley Calculators

Radius of Rim When Torque Transmitted by the Pulley is Given
radius_of_rim = Torque Transmitted by the Pulley/(Tangential Force at the end of Each Arm*(Number of arms/2)) Go
Number of Arms of the Pulley When Torque Transmitted by the Pulley is Given
number_of_arms = 2*Torque Transmitted by the Pulley/(Tangential Force at the end of Each Arm*Radius of Rim) Go
Torque Transmitted by the Pulley
torque_transmitted_by_the_pulley = Tangential Force at the end of Each Arm*Radius of Rim*(Number of arms/2) Go
Tangential Force at the End of Each Arm When Torque Transmitted by the Pulley is Given
tangential_force_at_end_of_each_arm = Torque Transmitted by the Pulley/(Radius of Rim*(Number of arms/2)) Go
Radius of Rim When Bending Moment Acting on the Arm is Given
radius_of_rim = Bending moment/Tangential Force at the end of Each Arm Go
Bending Moment Acting on the arm
bending_moment = Tangential Force at the end of Each Arm*Radius of Rim Go
Tangential Force at the End of Each Arm When Bending Moment acting on the Arm is Given
tangential_force_at_end_of_each_arm = Bending moment/Radius of Rim Go
Torque Transmitted by the Pulley When Bending Moment acting on the Arm is Given
torque_transmitted_by_the_pulley = Bending moment*Number of arms/2 Go
Bending Moment acting on the Arm in terms of Torque Transmitted by the Pulley
bending_moment = 2*Torque Transmitted by the Pulley/Number of arms Go
Number of Arms When Bending Moment acting on the Arm is Given
number_of_arms = 2*Torque Transmitted by the Pulley/Bending moment Go

### Length of Minor Axis in terms of Torque Transmitted by the pulley and Bending Stress Formula

minor_axis = (16*Torque Transmitted by the Pulley/(pi*Number of arms*Bending Stress))^(1/3)
b = (16*Mt/(pi*A*𝛔b))^(1/3)

## Define Bending Stress?

Bending stress is the normal stress that an object encounters when it is subjected to a large load at a particular point that causes the object to bend and become fatigued. Bending stress occurs when operating industrial equipment and in concrete and metallic structures when they are subjected to a tensile load.

## How to Calculate Length of Minor Axis in terms of Torque Transmitted by the pulley and Bending Stress?

Length of Minor Axis in terms of Torque Transmitted by the pulley and Bending Stress calculator uses minor_axis = (16*Torque Transmitted by the Pulley/(pi*Number of arms*Bending Stress))^(1/3) to calculate the Minor axis, The Length of Minor Axis in terms of Torque Transmitted by the pulley and Bending Stress formula is defined as the shortest axis of the elliptical cross-section of the arms of the pulley which is perpendicular to major axis. Minor axis and is denoted by b symbol.

How to calculate Length of Minor Axis in terms of Torque Transmitted by the pulley and Bending Stress using this online calculator? To use this online calculator for Length of Minor Axis in terms of Torque Transmitted by the pulley and Bending Stress, enter Torque Transmitted by the Pulley (Mt), Number of arms (A) and Bending Stress (𝛔b) and hit the calculate button. Here is how the Length of Minor Axis in terms of Torque Transmitted by the pulley and Bending Stress calculation can be explained with given input values -> 17.20508 = (16*0.1/(pi*2*50))^(1/3).

### FAQ

What is Length of Minor Axis in terms of Torque Transmitted by the pulley and Bending Stress?
The Length of Minor Axis in terms of Torque Transmitted by the pulley and Bending Stress formula is defined as the shortest axis of the elliptical cross-section of the arms of the pulley which is perpendicular to major axis and is represented as b = (16*Mt/(pi*A*𝛔b))^(1/3) or minor_axis = (16*Torque Transmitted by the Pulley/(pi*Number of arms*Bending Stress))^(1/3). Torque Transmitted by the Pulley is the amount of torque transmitted by the pulley, Number of arms in rotary distributor assembly and The Bending Stress is the normal stress that is induced at a point in a body subjected to loads that cause it to bend.
How to calculate Length of Minor Axis in terms of Torque Transmitted by the pulley and Bending Stress?
The Length of Minor Axis in terms of Torque Transmitted by the pulley and Bending Stress formula is defined as the shortest axis of the elliptical cross-section of the arms of the pulley which is perpendicular to major axis is calculated using minor_axis = (16*Torque Transmitted by the Pulley/(pi*Number of arms*Bending Stress))^(1/3). To calculate Length of Minor Axis in terms of Torque Transmitted by the pulley and Bending Stress, you need Torque Transmitted by the Pulley (Mt), Number of arms (A) and Bending Stress (𝛔b). With our tool, you need to enter the respective value for Torque Transmitted by the Pulley, Number of arms and Bending Stress 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 Minor axis?
In this formula, Minor axis uses Torque Transmitted by the Pulley, Number of arms and Bending Stress. We can use 10 other way(s) to calculate the same, which is/are as follows -
• torque_transmitted_by_the_pulley = Tangential Force at the end of Each Arm*Radius of Rim*(Number of arms/2)
• tangential_force_at_end_of_each_arm = Torque Transmitted by the Pulley/(Radius of Rim*(Number of arms/2))
• radius_of_rim = Torque Transmitted by the Pulley/(Tangential Force at the end of Each Arm*(Number of arms/2))
• number_of_arms = 2*Torque Transmitted by the Pulley/(Tangential Force at the end of Each Arm*Radius of Rim)
• bending_moment = Tangential Force at the end of Each Arm*Radius of Rim
• tangential_force_at_end_of_each_arm = Bending moment/Radius of Rim
• radius_of_rim = Bending moment/Tangential Force at the end of Each Arm
• bending_moment = 2*Torque Transmitted by the Pulley/Number of arms
• number_of_arms = 2*Torque Transmitted by the Pulley/Bending moment
• torque_transmitted_by_the_pulley = Bending moment*Number of arms/2
Where is the Length of Minor Axis in terms of Torque Transmitted by the pulley and Bending Stress calculator used?
Among many, Length of Minor Axis in terms of Torque Transmitted by the pulley and Bending Stress calculator is widely used in real life applications like {FormulaUses}. Here are few more real life examples -
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