Anshika Arya
National Institute Of Technology (NIT), Hamirpur
Anshika Arya has created this Calculator and 1000+ more calculators!
Saiju Shah
Jayawant Shikshan Prasarak Mandal (JSPM), Pune
Saiju Shah has verified this Calculator and 1000+ more calculators!

11 Other formulas that calculate the same Output

Shear force at the section
Shear Force=(Shear Stress*M.I of the area of section*Width of beam at considered level )/(Area of the section above considered level*Distance of the C.G of the area from N.A) Go
Shear force for the rectangular section
Shear Force=(Shear Stress*2*M.I of the area of section)/(((Length of rectangle^4)/4)-(Distance b/w considered and neutral layer^2)) Go
Shear force or viscous resistance in journal bearing
Shear Force=(viscosity of fluid*(pi^2)*(Diameter of shaft^2)*Mean speed in r.p.m*Length)/(Thickness) Go
Force along the shear force for given cutting force, thrust force, and shear angle
Shear Force=(Cutting Force*cos(Shear Angle))-(Axial thrust on the driven*sin(Shear Angle)) Go
Shear force on shear plane for given shear stress, width of cut, uncut chip thickness & shear angle
Shear Force=(Shear Stress*Width of cut*uncut chip thickness*(10^12))/sin(Shear Angle) Go
Shear force variation across neutral axis for rectangular section
Shear Force=(Shear Stress*Width of beam at considered level *Length of rectangle)/1.5 Go
Shear Load when Strain Energy in Shear is Given
Shear Force=sqrt(2*Strain Energy*Shear Area*Shear Modulus of Elasticity/Length) Go
Force along shear force for given force normal to shear force, shear, friction & normal rake angles
Shear Force=(Normal Force)/(tan(Shear Angle+friction angle-normal rake angle)) Go
Shear Force
Shear Force=Centripetal Force*cos(Theta)-Tangential Force*sin(Theta) Go
Shear force acting on shear plane for given shear stress & area of shear plane
Shear Force=Shear Stress*Area of shear plane Go
Shear force at the section if shear area is known
Shear Force=Shear Stress*Shear Area Go

Maximum shear force required for punching Formula

Shear Force=Area Sheared*Ultimate Shear Stress
Fs=A*τ<sub>u</sub>
More formulas
Accelerating torque on the rotating parts of the engine Go
Coefficient of Fluctuation of Energy Go
Mean linear velocity Go
Mean angular speed Go
Mean speed in r.p.m Go
Coefficient of Fluctuation of Speed for flywheel Go
Coefficient of Fluctuation of Speed for flywheel Go
Coefficient of Fluctuation of Speed for flywheel Go
Coefficient of Fluctuation of Speed for flywheel Go
Coefficient of Fluctuation of Speed for flywheel Go
Coefficient of Fluctuation of Speed for flywheel Go
Coefficient of steadiness Go
Coefficient of steadiness Go
Maximum Fluctuation of Energy Go
Hoop Stress in Flywheel Go
Centrifugal Stress Go
Work Done for Punching a Hole Go
Stroke of the Punch Go

Where shear force is maximum?

The shear force at a section of the beam will be a maximum with the head or tail of the load at that section.

How to Calculate Maximum shear force required for punching?

Maximum shear force required for punching calculator uses Shear Force=Area Sheared*Ultimate Shear Stress to calculate the Shear Force, Maximum shear force required for punching is a force applied perpendicular to a surface, in opposition to an offset force acting in the opposite direction. Shear Force and is denoted by Fs symbol.

How to calculate Maximum shear force required for punching using this online calculator? To use this online calculator for Maximum shear force required for punching, enter Area Sheared (A) and Ultimate Shear Stress u) and hit the calculate button. Here is how the Maximum shear force required for punching calculation can be explained with given input values -> 40 = 5E-06*8000000.

FAQ

What is Maximum shear force required for punching?
Maximum shear force required for punching is a force applied perpendicular to a surface, in opposition to an offset force acting in the opposite direction and is represented as Fs=A*τu or Shear Force=Area Sheared*Ultimate Shear Stress. Area sheared is the area that is caused by shear and Ultimate shear stress is force tending to cause deformation of a material by slippage along a plane or planes parallel to the imposed stress.
How to calculate Maximum shear force required for punching?
Maximum shear force required for punching is a force applied perpendicular to a surface, in opposition to an offset force acting in the opposite direction is calculated using Shear Force=Area Sheared*Ultimate Shear Stress. To calculate Maximum shear force required for punching, you need Area Sheared (A) and Ultimate Shear Stress u). With our tool, you need to enter the respective value for Area Sheared and Ultimate Shear 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 Shear Force?
In this formula, Shear Force uses Area Sheared and Ultimate Shear Stress. We can use 11 other way(s) to calculate the same, which is/are as follows -
  • Shear Force=Centripetal Force*cos(Theta)-Tangential Force*sin(Theta)
  • Shear Force=sqrt(2*Strain Energy*Shear Area*Shear Modulus of Elasticity/Length)
  • Shear Force=(Cutting Force*cos(Shear Angle))-(Axial thrust on the driven*sin(Shear Angle))
  • Shear Force=(Normal Force)/(tan(Shear Angle+friction angle-normal rake angle))
  • Shear Force=Shear Stress*Area of shear plane
  • Shear Force=(Shear Stress*Width of cut*uncut chip thickness*(10^12))/sin(Shear Angle)
  • Shear Force=Shear Stress*Shear Area
  • Shear Force=(Shear Stress*M.I of the area of section*Width of beam at considered level )/(Area of the section above considered level*Distance of the C.G of the area from N.A)
  • Shear Force=(Shear Stress*2*M.I of the area of section)/(((Length of rectangle^4)/4)-(Distance b/w considered and neutral layer^2))
  • Shear Force=(Shear Stress*Width of beam at considered level *Length of rectangle)/1.5
  • Shear Force=(viscosity of fluid*(pi^2)*(Diameter of shaft^2)*Mean speed in r.p.m*Length)/(Thickness)
Share Image
Let Others Know
Facebook
Twitter
Reddit
LinkedIn
Email
WhatsApp
Copied!