Effort in terms of leverage and load Calculator

Category	Physics ↺
Physics	Machine Design ↺
Machine-Design	Design of Machine Elements ↺
Design-Of-Machine-Elements	Design of lever ↺

✖Force is the instantaneous load applied perpendicular to the specimen cross section.ⓘ Force [F]			+10% -10%
✖The leverage value for a leverⓘ leverage [l]			+10% -10%

✖Effort is the force required to overcome the resistance to get the work done by the machine. ⓘ Effort in terms of leverage and load [P]

⎘ Copy

👎 Report Issue!

👍 Share Now!

You are here:

Vaibhav Malani

National Institute of Technology (NIT), Tiruchirapalli

Vaibhav Malani has created this Calculator and 200+ more calculators!

Sagar S Kulkarni

Dayananda Sagar College of Engineering (DSCE), Bengaluru

Sagar S Kulkarni has verified this Calculator and 200+ more calculators!

< 11 Other formulas that you can solve using the same Inputs

Brinell Hardness Number

Brinell Hardness Number=Force/((0.5*pi*Diameter of the ball indentor)*(Diameter of the ball indentor-((Diameter of the ball indentor^2)-(Diameter of indentation^2))^0.5)) GO

Deflection of the center of the leaf spring in pickering governor

Deflection of the centre of the leaf spring=(Force*Distance between the fixed ends of the spring^3)/(192*Young’s modulus of the material of the spring*Moment of Inertia) GO

Stress due to impact loading

Stress=Force*(1+sqrt(1+2*Original cross sectional area*Elastic Modulus*Height at which load falls/Force*Length))/Original cross sectional area GO

Elongation circular tapered bar

Elongation=4*Force*Length/(pi*Diameter of bigger end*Diameter of smaller end *Elastic Modulus) GO

Thermal Stress in tapered bar

Stress=(4*Force*Length)/(pi*Diameter of bigger end*Diameter of smaller end *Elastic Modulus) GO

Elongation of prismatic bar due to its own weight

Elongation=2*Force*Length of Rod/(Area*Elastic Modulus) GO

Engineering stress

Engineering stress=Force/Original cross sectional area GO

Hooke's law

Young's Modulus=Force*Elongation/(Area*Initial length) GO

Axial elongation of prismatic bar due to external load

Elongation=Force*Length of Rod/(Area*Elastic Modulus) GO

Strain Energy if applied tension load is given

Strain Energy=Force^2*Length/(2*Area*Young's Modulus) GO

Positive Moment for End Spans if Discontinuous End is Unrestrained

moment=(Force*Length of Span^2)/11 GO

< 9 Other formulas that calculate the same Output

Effort Required in Lifting a Load with Acme Thread

Effort=Force*((Coefficient of Friction*sec((14.5*pi/180))+tan(Helix Angle*pi/180))/(1-Coefficient of Friction*sec((14.5*pi/180))*tan(Helix Angle*pi/180))) GO

Effort Required in Lowering a Load

Effort=Force*((Coefficient of Friction*sec((14.5*pi/180))-tan(Helix Angle*pi/180))/(1+Coefficient of Friction*sec((14.5*pi/180))*tan(Helix Angle*pi/180))) GO

Effort Required in Lowering Load using Trapezoidal Threaded Screw

Effort=Force*((Coefficient of Friction*sec((15*pi/180))-tan(Helix Angle*pi/180))/(1+Coefficient of Friction*sec((15*pi/180))*tan(Helix Angle*pi/180))) GO

Effort Required in Lifting a Load with Trapezoidal Screw Thread

Effort=Force*((Coefficient of Friction*sec((15*pi/180))+tan(Helix Angle))/(1-Coefficient of Friction*sec((15*pi/180))*tan(Helix Angle))) GO

Effort Required in Lifting a load using Screw

Effort=Force*((Coefficient of Friction+tan(Helix Angle))/(1-Coefficient of Friction*tan(Helix Angle))) GO

Effort Required in Lowering a Load

Effort=Force*((Coefficient of Friction-tan(Helix Angle))/(1+Coefficient of Friction*tan(Helix Angle))) GO

Effort in terms of length and load

Effort=Length of load arm*Force/Length of effort arm GO

Effort When Torque is Given

Effort=2*Torque/Mean diameter of screw GO

Effort required by machine to overcome resistance to get work done

Effort=Force/Mechanical advantage GO

Effort in terms of leverage and load Formula

Effort=Force/leverage
P=F/l

More formulas

Mechanical advantage GO

Leverage GO

Load in terms of lengths and effort GO

Effort in terms of length and load GO

Load in terms of leverage and effort GO

Length of effort arm in terms of load and effort GO

length of load arm in terms of load and effort GO

Length of load arm in terms of mechanical advantage GO

Length of effort arm in terms of mechanical advantage GO

What is lever?

A lever is defined as a mechanical device in the form of a rigid bar pivoted about the fulcrum to multiply or transfer the force.

How to Calculate Effort in terms of leverage and load?

Effort in terms of leverage and load calculator uses Effort=Force/leverage to calculate the Effort, The Effort in terms of leverage and load formula is defined as the ratio of load and leverage. It is measured in Newton. Effort and is denoted by P symbol.

How to calculate Effort in terms of leverage and load using this online calculator? To use this online calculator for Effort in terms of leverage and load, enter Force (F) and leverage (l) and hit the calculate button. Here is how the Effort in terms of leverage and load calculation can be explained with given input values -> 100 = 1000/10.

FAQ

What is Effort in terms of leverage and load?

The Effort in terms of leverage and load formula is defined as the ratio of load and leverage. It is measured in Newton and is represented as P=F/l or Effort=Force/leverage. Force is the instantaneous load applied perpendicular to the specimen cross section and The leverage value for a lever.

How to calculate Effort in terms of leverage and load?

The Effort in terms of leverage and load formula is defined as the ratio of load and leverage. It is measured in Newton is calculated using Effort=Force/leverage. To calculate Effort in terms of leverage and load, you need Force (F) and leverage (l). With our tool, you need to enter the respective value for Force and leverage 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 Effort?

In this formula, Effort uses Force and leverage. We can use 9 other way(s) to calculate the same, which is/are as follows -

Effort=Force/Mechanical advantage
Effort=Force*((Coefficient of Friction+tan(Helix Angle))/(1-Coefficient of Friction*tan(Helix Angle)))
Effort=2*Torque/Mean diameter of screw
Effort=Force*((Coefficient of Friction-tan(Helix Angle))/(1+Coefficient of Friction*tan(Helix Angle)))
Effort=Force*((Coefficient of Friction*sec((15*pi/180))+tan(Helix Angle))/(1-Coefficient of Friction*sec((15*pi/180))*tan(Helix Angle)))
Effort=Force*((Coefficient of Friction*sec((14.5*pi/180))+tan(Helix Angle*pi/180))/(1-Coefficient of Friction*sec((14.5*pi/180))*tan(Helix Angle*pi/180)))
Effort=Length of load arm*Force/Length of effort arm
Effort=Force*((Coefficient of Friction*sec((15*pi/180))-tan(Helix Angle*pi/180))/(1+Coefficient of Friction*sec((15*pi/180))*tan(Helix Angle*pi/180)))
Effort=Force*((Coefficient of Friction*sec((14.5*pi/180))-tan(Helix Angle*pi/180))/(1+Coefficient of Friction*sec((14.5*pi/180))*tan(Helix Angle*pi/180)))

Facebook
Twitter
WhatsApp
Reddit
LinkedIn
E-Mail

Let Others Know

✖

Facebook

Twitter

Copied!