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## Credits

Osmania University (OU), Hyderabad
Kethavath Srinath has created this Calculator and 500+ more calculators!
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## Power Transmitted by the Flat Belt for Design Purpose Solution

STEP 0: Pre-Calculation Summary
Formula Used
power_transmitted_for_design_purpose = Actual Power Transmitted in given Application*Load Correction Factor
kWmax = kW*Far
This formula uses 2 Variables
Variables Used
Actual Power Transmitted in given Application - Actual Power Transmitted in given Application is defined as the actual power transmitted by the belt in a given application. (Measured in Kilowatt)
Load Correction Factor- Load Correction Factor increases the power factor of a load, improving efficiency for the distribution system to which it is attached.
STEP 1: Convert Input(s) to Base Unit
Actual Power Transmitted in given Application: 80 Kilowatt --> 80000 Watt (Check conversion here)
Load Correction Factor: 1 --> No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
kWmax = kW*Far --> 80000*1
Evaluating ... ...
kWmax = 80000
STEP 3: Convert Result to Output's Unit
80000 Watt -->80 Kilowatt (Check conversion here)
FINAL ANSWER
80 Kilowatt <-- Power Transmitted for Design Purpose
(Calculation completed in 00.010 seconds)

## < 10+ Design of Belt Drives Calculators

Belt Tension in the Tight Side
belt_tension_in_tight_side = (e^Coefficient of Friction*Angle of Wrap)*(Belt Tension in loose Side-Mass of Meter Length of Belt*Belt Velocity^2)+Mass of Meter Length of Belt*Belt Velocity^2 Go
Length of the Belt
belt_length = 2*Center Distance+(pi*(Diameter of Big Pulley+Diameter of Small Pulley)/2)+((Diameter of Big Pulley-Diameter of Small Pulley)^2/4*Center Distance) Go
Center Distance from Small Pulley to Big Pulley When Wrap Angle of Small Pulley is Given
center_distance = (Diameter of Big Pulley-Diameter of Small Pulley)/(2*sin((3.14-Wrap Angle for Small Pulley)/2)) Go
Center Distance from Small Pulley to Big Pulley When Wrap Angle of Big Pulley is Given
center_distance = (Diameter of Big Pulley-Diameter of Small Pulley)/(2*sin((Wrap Angle for Small Pulley-3.14)/2)) Go
Wrap Angle for the Small Pulley
wrap_angle_for_small_pulley = 3.14-2*asin((Diameter of Big Pulley-Diameter of Small Pulley)/2*Center Distance) Go
Diameter of Small Pully When Wrap Angle of the Big Pulley is Given
diameter_of_small_pulley = Diameter of Big Pulley-2*Center Distance*sin((Wrap Angle for Small Pulley-3.14)/2) Go
Diameter of Big Pulley When Wrap Angle for the Big Pulley is Given
diameter_of_big_pulley = Diameter of Small Pulley+2*Center Distance*sin((Wrap Angle for Small Pulley-3.14)/2) Go
Diameter of Small Pulley When Wrap Angle of Small Pulley is Given
diameter_of_small_pulley = Diameter of Big Pulley-2*Center Distance*sin((3.14-Wrap Angle for Small Pulley)/2) Go
Diameter of Big Pulley When Wrap Angle of Small Pulley is Given
diameter_of_big_pulley = Diameter of Small Pulley+2*Center Distance*sin((3.14-Wrap Angle for Small Pulley)/2) Go
Wrap Angle for the Big Pulley
wrap_angle_for_big_pulley = 3.14+2*asin((Diameter of Big Pulley-Diameter of Small Pulley)/2*Center Distance) Go

### Power Transmitted by the Flat Belt for Design Purpose Formula

power_transmitted_for_design_purpose = Actual Power Transmitted in given Application*Load Correction Factor
kWmax = kW*Far

## Define Flat Belts?

A flat belt is a belt with a flat surface, usually evenly textured on both sides, used in a pulley system. In conveyer belt construction, the flat belt can be used as a single broad belt on an assembly line or as part of an array of webbed belts.

## How to Calculate Power Transmitted by the Flat Belt for Design Purpose?

Power Transmitted by the Flat Belt for Design Purpose calculator uses power_transmitted_for_design_purpose = Actual Power Transmitted in given Application*Load Correction Factor to calculate the Power Transmitted for Design Purpose, The Power Transmitted by the Flat Belt for Design Purpose formula is defined as the power transmitted by the flat belt for only design purposes. Power Transmitted for Design Purpose and is denoted by kWmax symbol.

How to calculate Power Transmitted by the Flat Belt for Design Purpose using this online calculator? To use this online calculator for Power Transmitted by the Flat Belt for Design Purpose, enter Actual Power Transmitted in given Application (kW) and Load Correction Factor (Far) and hit the calculate button. Here is how the Power Transmitted by the Flat Belt for Design Purpose calculation can be explained with given input values -> 80 = 80000*1.

### FAQ

What is Power Transmitted by the Flat Belt for Design Purpose?
The Power Transmitted by the Flat Belt for Design Purpose formula is defined as the power transmitted by the flat belt for only design purposes and is represented as kWmax = kW*Far or power_transmitted_for_design_purpose = Actual Power Transmitted in given Application*Load Correction Factor. Actual Power Transmitted in given Application is defined as the actual power transmitted by the belt in a given application and Load Correction Factor increases the power factor of a load, improving efficiency for the distribution system to which it is attached.
How to calculate Power Transmitted by the Flat Belt for Design Purpose?
The Power Transmitted by the Flat Belt for Design Purpose formula is defined as the power transmitted by the flat belt for only design purposes is calculated using power_transmitted_for_design_purpose = Actual Power Transmitted in given Application*Load Correction Factor. To calculate Power Transmitted by the Flat Belt for Design Purpose, you need Actual Power Transmitted in given Application (kW) and Load Correction Factor (Far). With our tool, you need to enter the respective value for Actual Power Transmitted in given Application and Load Correction Factor 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 Power Transmitted for Design Purpose?
In this formula, Power Transmitted for Design Purpose uses Actual Power Transmitted in given Application and Load Correction Factor. We can use 10 other way(s) to calculate the same, which is/are as follows -
• wrap_angle_for_small_pulley = 3.14-2*asin((Diameter of Big Pulley-Diameter of Small Pulley)/2*Center Distance)
• center_distance = (Diameter of Big Pulley-Diameter of Small Pulley)/(2*sin((3.14-Wrap Angle for Small Pulley)/2))
• diameter_of_small_pulley = Diameter of Big Pulley-2*Center Distance*sin((3.14-Wrap Angle for Small Pulley)/2)
• diameter_of_big_pulley = Diameter of Small Pulley+2*Center Distance*sin((3.14-Wrap Angle for Small Pulley)/2)
• wrap_angle_for_big_pulley = 3.14+2*asin((Diameter of Big Pulley-Diameter of Small Pulley)/2*Center Distance)
• center_distance = (Diameter of Big Pulley-Diameter of Small Pulley)/(2*sin((Wrap Angle for Small Pulley-3.14)/2))
• diameter_of_small_pulley = Diameter of Big Pulley-2*Center Distance*sin((Wrap Angle for Small Pulley-3.14)/2)
• diameter_of_big_pulley = Diameter of Small Pulley+2*Center Distance*sin((Wrap Angle for Small Pulley-3.14)/2)
• belt_length = 2*Center Distance+(pi*(Diameter of Big Pulley+Diameter of Small Pulley)/2)+((Diameter of Big Pulley-Diameter of Small Pulley)^2/4*Center Distance)
• belt_tension_in_tight_side = (e^Coefficient of Friction*Angle of Wrap)*(Belt Tension in loose Side-Mass of Meter Length of Belt*Belt Velocity^2)+Mass of Meter Length of Belt*Belt Velocity^2
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