Total Percentage Slip in Belt Solution

STEP 0: Pre-Calculation Summary
Formula Used
Total Percentage of Slip = Slip between Driver and Belt+Slip between Belt and Follower
s = s1+s2
This formula uses 3 Variables
Variables Used
Total Percentage of Slip - Total percentage of slip is defined as insufficient frictional grip between pulley (driver/driven) and belt. Slip is the difference between the linear velocities of pulley (driver/driven) and belt.
Slip between Driver and Belt - Slip between driver and belt is defined as insufficient frictional grip between pulley (driver/driven) and belt.
Slip between Belt and Follower - Slip between belt and follower is defined as insufficient frictional grip between pulley (driver/driven) and belt.
STEP 1: Convert Input(s) to Base Unit
Slip between Driver and Belt: 0.5 --> No Conversion Required
Slip between Belt and Follower: 0.2 --> No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
s = s1+s2 --> 0.5+0.2
Evaluating ... ...
s = 0.7
STEP 3: Convert Result to Output's Unit
0.7 --> No Conversion Required
FINAL ANSWER
0.7 <-- Total Percentage of Slip
(Calculation completed in 00.004 seconds)

Credits

Created by Anshika Arya
National Institute Of Technology (NIT), Hamirpur
Anshika Arya has created this Calculator and 2000+ more calculators!
Verified by Team Softusvista
Softusvista Office (Pune), India
Team Softusvista has verified this Calculator and 1100+ more calculators!

20 Belt Drive Calculators

Length of Open Belt Drive
Go Total Length of Belt = pi*(Radii of Smaller Pulley+Radii of Larger Pulley)+2*Distance Between Centers of Two Pulleys+((Radii of Larger Pulley-Radii of Smaller Pulley)^2)/Distance Between Centers of Two Pulleys
Cross Belt Drive Length
Go Length Belt Drive = pi*(Radii of Smaller Pulley+Radii of Larger Pulley)+2*Distance Between Centers of Two Pulleys+(Radii of Smaller Pulley+Radii of Larger Pulley)^2/Distance Between Centers of Two Pulleys
Frictional Force in V Belt Drive
Go Force of Friction = Coefficient of Friction b/w Belt & Sides of Groove*Total Reaction in Plane of Groove*cosec(Angle of Groove/2)
Relation between Pitch and Pitch Circle Diameter of Chain Drive
Go Pitch Circle Diameter of Gear = Pitch of Chain Drive*cosec((180*pi/180)/Number of Teeth on Sprocket)
Angle Made by Belt with Vertical Axis for Cross Belt Drive
Go Angle made by Belt with Vertical Axis = (Radii of Smaller Pulley+Radii of Larger Pulley)/Distance Between Centers of Two Pulleys
Angle Made by Belt with Vertical Axis for Open Belt Drive
Go Angle made by Belt with Vertical Axis = (Radii of Larger Pulley-Radii of Smaller Pulley)/Distance Between Centers of Two Pulleys
Initial Tension in Belt
Go Initial Tension of Belt = (Tension in Tight Side of Belt+Tension in Slack Side of Belt+2*Centrifugal Tension of Belt)/2
Normal Reaction between Belt and Sides of Groove
Go Normal Reaction between Belt and Sides of Groove = Total Reaction in Plane of Groove/(2*sin(Angle of Groove/2))
Torque Exerted on Driven Pulley
Go Torque Exerted on Pulley = (Tension in Tight Side of Belt-Tension in Slack Side of Belt)*Diameter of Follower/2
Torque Exerted on Driving Pulley
Go Torque Exerted on Pulley = (Tension in Tight Side of Belt-Tension in Slack Side of Belt)*Diameter of Driver/2
Power Transmitted by Belt
Go Power Transmitted = (Tension in Tight Side of Belt-Tension in Slack Side of Belt)*Velocity of Belt
Velocity for Transmission of Maximum Power by Belt
Go Velocity of Belt = sqrt(Maximum Tension of Belt/(3*Mass of Belt per Unit Length))
Length of Belt that Passes over Follower
Go Length of Belt over Follower = pi*Speed of Follower*Diameter of Follower Pulley
Length of Belt that Passes over Driver
Go Length of Belt over Driver = pi*Diameter of Driver Pulley*Speed of Driver
Maximum Tension of Belt
Go Maximum Tension of Belt = Maximum Safe Stress*Belt Width*Belt Thickness
Total Percentage Slip in Belt
Go Total Percentage of Slip = Slip between Driver and Belt+Slip between Belt and Follower
Centrifugal Tension in Belt
Go Centrifugal Tension of Belt = Mass of Belt per Unit Length*Velocity of Belt
Angle of Contact for Cross Belt Drive
Go Angle of Contact = 180*pi/180+2*Angle made by Belt with Vertical Axis
Angle of Contact for Open Belt Drive
Go Angle of Contact = 180*pi/180-2*Angle made by Belt with Vertical Axis
Maximum Tension for Transmission of Maximum Power by Belt
Go Maximum Tension of Belt = 3*Centrifugal Tension of Belt

Total Percentage Slip in Belt Formula

Total Percentage of Slip = Slip between Driver and Belt+Slip between Belt and Follower
s = s1+s2

What is slip in belt drives?

Slip is defined as insufficient frictional grip between pulley (driver/driven) and belt. Slip is the difference between the linear velocities of pulley (driver/driven) and belt.

What is a belt drive used for?

Belt drive, in machinery, a pair of pulleys attached to usually parallel shafts and connected by an encircling flexible belt (band) that can serve to transmit and modify rotary motion from one shaft to the other.

How to Calculate Total Percentage Slip in Belt?

Total Percentage Slip in Belt calculator uses Total Percentage of Slip = Slip between Driver and Belt+Slip between Belt and Follower to calculate the Total Percentage of Slip, Total percentage slip in belt is defined as insufficient frictional grip between pulley (driver/driven) and belt. Total Percentage of Slip is denoted by s symbol.

How to calculate Total Percentage Slip in Belt using this online calculator? To use this online calculator for Total Percentage Slip in Belt, enter Slip between Driver and Belt (s1) & Slip between Belt and Follower (s2) and hit the calculate button. Here is how the Total Percentage Slip in Belt calculation can be explained with given input values -> 0.7 = 0.5+0.2.

FAQ

What is Total Percentage Slip in Belt?
Total percentage slip in belt is defined as insufficient frictional grip between pulley (driver/driven) and belt and is represented as s = s1+s2 or Total Percentage of Slip = Slip between Driver and Belt+Slip between Belt and Follower. Slip between driver and belt is defined as insufficient frictional grip between pulley (driver/driven) and belt & Slip between belt and follower is defined as insufficient frictional grip between pulley (driver/driven) and belt.
How to calculate Total Percentage Slip in Belt?
Total percentage slip in belt is defined as insufficient frictional grip between pulley (driver/driven) and belt is calculated using Total Percentage of Slip = Slip between Driver and Belt+Slip between Belt and Follower. To calculate Total Percentage Slip in Belt, you need Slip between Driver and Belt (s1) & Slip between Belt and Follower (s2). With our tool, you need to enter the respective value for Slip between Driver and Belt & Slip between Belt and Follower 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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