Rudrani Tidke
Cummins College of Engineering for Women (CCEW), Pune
Rudrani Tidke has created this Calculator and 100+ more calculators!
Alithea Fernandes
Don Bosco College of Engineering (DBCE), Goa
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11 Other formulas that you can solve using the same Inputs

Surface Area of a Rectangular Prism
Surface Area=2*(Length*Width+Length*Height+Width*Height) GO
Perimeter of a rectangle when diagonal and length are given
Perimeter=2*(Length+sqrt((Diagonal)^2-(Length)^2)) GO
Magnetic Flux
Magnetic Flux=Magnetic Field*Length*Breadth*cos(θ) GO
Diagonal of a Rectangle when length and area are given
Diagonal=sqrt(((Area)^2/(Length)^2)+(Length)^2) GO
Area of a Rectangle when length and diagonal are given
Area=Length*(sqrt((Diagonal)^2-(Length)^2)) GO
Diagonal of a Rectangle when length and breadth are given
Diagonal=sqrt(Length^2+Breadth^2) GO
Strain
Strain=Change In Length/Length GO
Surface Tension
Surface Tension=Force/Length GO
Perimeter of a rectangle when length and width are given
Perimeter=2*Length+2*Width GO
Volume of a Rectangular Prism
Volume=Width*Height*Length GO
Area of a Rectangle when length and breadth are given
Area=Length*Breadth GO

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
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
Maximum shear force required for punching
Shear Force=Area Sheared*Ultimate Shear Stress 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

Shear Load when Strain Energy in Shear is Given Formula

Shear Force=sqrt(2*Strain Energy*Shear Area*Shear Modulus of Elasticity/Length)
Fs=sqrt(2*U*A*G/l)
More formulas
Stress using Hook's Law GO
Strain Energy in Shear GO
Length over which Deformation Takes Place when Strain Energy in Shear is Given GO
Shear Area when Strain Energy in Shear is Given GO
Shear Modulus of Elasticity when Strain Energy in Shear is Given GO
Strain Energy in Shear when Shear Deformation is Given GO
Strain Energy in Torsion GO
Torque when Strain Energy in Torsion is Given GO
Length over which Deformation Takes Place when Strain Energy in Torsion is Given GO
Polar Moment of Inertia when Strain Energy in Torsion is Given GO
Shear Modulus of Elasticity when Strain Energy in Torsion is Given GO
Strain Energy in Torsion when Angle of Twist is Given GO
Strain Energy in Bending GO
Bending Moment when Strain Energy in Bending is Given GO
Length over which Deformation Takes Place when Strain Energy in Bending is Given GO
Modulus of Elasticity when Strain Energy in Bending is Given GO
Moment of Inertia when Strain Energy in Bending is Given GO
Strain Energy in Bending when Angle Through which One Beam Rotates wrt Other End is Given GO

What is meant by shear load?

Shear loads are defined as forces applied to a specimen tangent to the loading axis, but not through the center of the sample.

How to Calculate Shear Load when Strain Energy in Shear is Given?

Shear Load when Strain Energy in Shear is Given calculator uses Shear Force=sqrt(2*Strain Energy*Shear Area*Shear Modulus of Elasticity/Length) to calculate the Shear Force, The Shear Load when Strain Energy in Shear is Given formula is defined as a force that tends to produce a sliding failure on a material along a plane that is parallel to the direction of the force. Shear Force and is denoted by Fs symbol.

How to calculate Shear Load when Strain Energy in Shear is Given using this online calculator? To use this online calculator for Shear Load when Strain Energy in Shear is Given, enter Strain Energy (U), Shear Area (A), Shear Modulus of Elasticity (G) and Length (l) and hit the calculate button. Here is how the Shear Load when Strain Energy in Shear is Given calculation can be explained with given input values -> 115.4701 = sqrt(2*50*4*100/3).

FAQ

What is Shear Load when Strain Energy in Shear is Given?
The Shear Load when Strain Energy in Shear is Given formula is defined as a force that tends to produce a sliding failure on a material along a plane that is parallel to the direction of the force and is represented as Fs=sqrt(2*U*A*G/l) or Shear Force=sqrt(2*Strain Energy*Shear Area*Shear Modulus of Elasticity/Length). The Strain energy is defined as the energy stored in a body due to deformation. , The shear area represents the area of the cross section that is effective in resisting shear deformation, Shear Modulus of Elasticity is one of the measures of mechanical properties of solids. Other elastic moduli are Young's modulus and bulk modulus and Length is the measurement or extent of something from end to end.
How to calculate Shear Load when Strain Energy in Shear is Given?
The Shear Load when Strain Energy in Shear is Given formula is defined as a force that tends to produce a sliding failure on a material along a plane that is parallel to the direction of the force is calculated using Shear Force=sqrt(2*Strain Energy*Shear Area*Shear Modulus of Elasticity/Length). To calculate Shear Load when Strain Energy in Shear is Given, you need Strain Energy (U), Shear Area (A), Shear Modulus of Elasticity (G) and Length (l). With our tool, you need to enter the respective value for Strain Energy, Shear Area, Shear Modulus of Elasticity and Length 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 Strain Energy, Shear Area, Shear Modulus of Elasticity and Length. 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=Area Sheared*Ultimate Shear Stress
  • 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)
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