Power Transmitted by Flat Belt for Design Purpose Solution

STEP 0: Pre-Calculation Summary
Formula Used
Design Power of Belt Drive = Power transmitted by belt*Load Correction Factor
Pd = Pt*Fa
This formula uses 3 Variables
Variables Used
Design Power of Belt Drive - (Measured in Watt) - Design Power of Belt Drive is defined as the power transmitted on the basis of the design.
Power transmitted by belt - (Measured in Watt) - Power transmitted by belt is the amount of power that is transmitted from the belt of a belt drive to the pulley.
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
Power transmitted by belt: 6.45 Kilowatt --> 6450 Watt (Check conversion here)
Load Correction Factor: 1.15 --> No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Pd = Pt*Fa --> 6450*1.15
Evaluating ... ...
Pd = 7417.5
STEP 3: Convert Result to Output's Unit
7417.5 Watt -->7.4175 Kilowatt (Check conversion here)
FINAL ANSWER
7.4175 Kilowatt <-- Design Power of Belt Drive
(Calculation completed in 00.004 seconds)

Credits

Created by Kethavath Srinath
Osmania University (OU), Hyderabad
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Vishwakarma Government Engineering College (VGEC), Ahmedabad
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21 Maximum Power Conditions Calculators

Optimum Velocity of Belt for Maximum Power Transmission
Go Optimum Velocity of Belt = sqrt(Initial Tension in Belt/(3*Mass of Meter Length of Belt))
Belt Velocity given Tension in Belt Due to Centrifugal Force
Go Belt Velocity = sqrt(Belt Tension due to Centrifugal Force/Mass of Meter Length of Belt)
Velocity of Belt for Maximum Power Transmission given Maximum Permissible tensile Stress
Go Optimum Velocity of Belt = sqrt(Maximum Tension in Belt/3*Mass of Meter Length of Belt)
Maximum Permissible Tensile Stress of Belt Material
Go Tensile Stress in Belt = Maximum Tension in Belt/(Width of Belt*Thickness of Belt)
Thickness of Belt given Maximum Belt Tension
Go Thickness of Belt = Maximum Tension in Belt/(Tensile Stress in Belt*Width of Belt)
Width of Belt given Maximum Belt Tension
Go Width of Belt = Maximum Tension in Belt/(Tensile Stress in Belt*Thickness of Belt)
Maximum Belt Tension
Go Maximum Tension in Belt = Tensile Stress in Belt*Width of Belt*Thickness of Belt
Mass of One Meter Length of Belt given Maximum Permissible Tensile Stress of Belt
Go Mass of Meter Length of Belt = Maximum Tension in Belt/(3*Optimum Velocity of Belt^2)
Mass of One Meter Length of Belt given Tension in Belt Due to Centrifugal Force
Go Mass of Meter Length of Belt = Belt Tension due to Centrifugal Force/Belt Velocity^2
Tension in Belt Due to Centrifugal Force
Go Belt Tension due to Centrifugal Force = Mass of Meter Length of Belt*Belt Velocity^2
Mass of One Meter Length of Belt given Velocity for Maximum Power Transmission
Go Mass of Meter Length of Belt = Initial Tension in Belt/3*Optimum Velocity of Belt^2
Initial Tension in Belt given Velocity of Belt for Maximum Power Transmission
Go Initial Tension in Belt = 3*Mass of Meter Length of Belt*Optimum Velocity of Belt^2
Initial Tension in Belt Drive
Go Initial Tension in Belt = (Belt Tension on Tight Side+Belt Tension on Loose Side)/2
Belt Tension in Tight Side of Belt given Initial Tension in Belt
Go Belt Tension on Tight Side = 2*Initial Tension in Belt-Belt Tension on Loose Side
Belt Tension in Loose Side of Belt given Initial Tension in Belt
Go Belt Tension on Loose Side = 2*Initial Tension in Belt-Belt Tension on Tight Side
Load Correction Factor given Power Transmitted by Flat Belt for Design Purpose
Go Load Correction Factor = Design Power of Belt Drive/Power transmitted by belt
Actual Power Transmitted given Power Transmitted by Flat for Design Purpose
Go Power transmitted by belt = Design Power of Belt Drive/Load Correction Factor
Power Transmitted by Flat Belt for Design Purpose
Go Design Power of Belt Drive = Power transmitted by belt*Load Correction Factor
Belt Tension in Tight Side of Belt given Tension due to Centrifugal Force
Go Belt Tension on Tight Side = 2*Belt Tension due to Centrifugal Force
Tension in Belt Due to Centrifugal Force given Permissible Tensile Stress of Belt Material
Go Belt Tension due to Centrifugal Force = Maximum Tension in Belt/3
Maximum Belt Tension given Tension Due to Centrifugal Force
Go Maximum Tension in Belt = 3*Belt Tension due to Centrifugal Force

Power Transmitted by Flat Belt for Design Purpose Formula

Design Power of Belt Drive = Power transmitted by belt*Load Correction Factor
Pd = Pt*Fa

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 Flat Belt for Design Purpose?

Power Transmitted by Flat Belt for Design Purpose calculator uses Design Power of Belt Drive = Power transmitted by belt*Load Correction Factor to calculate the Design Power of Belt Drive, The Power Transmitted by Flat Belt for Design Purpose formula is defined as the power transmitted by the flat belt for only design purposes. Design Power of Belt Drive is denoted by Pd symbol.

How to calculate Power Transmitted by Flat Belt for Design Purpose using this online calculator? To use this online calculator for Power Transmitted by Flat Belt for Design Purpose, enter Power transmitted by belt (Pt) & Load Correction Factor (Fa) and hit the calculate button. Here is how the Power Transmitted by Flat Belt for Design Purpose calculation can be explained with given input values -> 0.007417 = 6450*1.15.

FAQ

What is Power Transmitted by Flat Belt for Design Purpose?
The Power Transmitted by Flat Belt for Design Purpose formula is defined as the power transmitted by the flat belt for only design purposes and is represented as Pd = Pt*Fa or Design Power of Belt Drive = Power transmitted by belt*Load Correction Factor. Power transmitted by belt is the amount of power that is transmitted from the belt of a belt drive to the pulley & 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 Flat Belt for Design Purpose?
The Power Transmitted by Flat Belt for Design Purpose formula is defined as the power transmitted by the flat belt for only design purposes is calculated using Design Power of Belt Drive = Power transmitted by belt*Load Correction Factor. To calculate Power Transmitted by Flat Belt for Design Purpose, you need Power transmitted by belt (Pt) & Load Correction Factor (Fa). With our tool, you need to enter the respective value for Power transmitted by belt & Load Correction Factor 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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