Kethavath Srinath
Osmania University (OU), Hyderabad
Kethavath Srinath has created this Calculator and 400+ more calculators!
Mridul Sharma
Indian Institute of Information Technology (IIIT), Bhopal
Mridul Sharma has verified this Calculator and 200+ more calculators!

11 Other formulas that you can solve using the same Inputs

Deflection for Hollow Rectangle When Load in Middle
Deflection of Beam=(Greatest Safe Load*Length of the Beam^3)/(32*(Sectional Area*(Depth of the Beam^2)-Interior Cross-Sectional Area of Beam*(Interior Depth of the Beam^2))) GO
Deflection for Hollow Rectangle When Load is Distributed
Deflection of Beam=Greatest Safe Load*(Length of the Beam^3)/(52*(Sectional Area*Depth of the Beam^-Interior Cross-Sectional Area of Beam*Interior Depth of the Beam^2)) GO
Greatest Safe Load for Hollow Rectangle When Load is Distributed
Greatest Safe Load=1780*(Sectional Area*Depth of the Beam-Interior Cross-Sectional Area of Beam*Interior Depth of the Beam)/Distance between Supports GO
Greatest Safe Load for Hollow Rectangle When Load in Middle
Greatest Safe Load=(890*(Sectional Area*Depth of the Beam-Interior Cross-Sectional Area of Beam*Interior Depth of the Beam))/Length of the Beam GO
Deflection for Solid Rectangle When Load is Distributed
Deflection of Beam=(Greatest safe distributed load*Length of the Beam^3)/(52*Sectional Area*Depth of the Beam^2) GO
Deflection for Solid Rectangle When Load in Middle
Deflection of Beam=(Greatest Safe Load*Length of the Beam^3)/(32*Sectional Area*Depth of the Beam^2) GO
Greatest Safe Load for Solid Rectangle When Load is Distributed
Greatest safe distributed load=1780*Sectional Area*Depth of the Beam/Length of the Beam GO
Greatest Safe Load for Solid Cylinder When Load is Distributed
Greatest Safe Load=1333*(Sectional Area*Depth of the Beam)/Length of the Beam GO
Greatest Safe Load for Solid Cylinder When Load in Middle
Greatest Safe Load=(667*Sectional Area*Depth of the Beam)/Length of the Beam GO
Greatest Safe Load for Solid Rectangle When Load in Middle
Greatest Safe Load=890*Sectional Area*Depth of the Beam/Length of the Beam GO
Stress in Concrete
Stress=2*Bending moment/(Ratio k*Ratio j*Beam Width*Depth of the Beam^2) GO

1 Other formulas that calculate the same Output

Nominal Unit Shear Stress
Shearing Unit Stress=Total Shear/(Beam Width*Distance from Compression to Centroid Reinforcment) GO

Shearing Unit Stress in a Reinforced Concrete Beam Formula

Shearing Unit Stress=Total Shear/(Beam Width*Depth of the Beam)
v=V/(b*D)
More formulas
Total Shear when Shearing Unit Stress in a Reinforced Concrete Beam is Given GO
Width of Beam when Shearing Unit Stress in a Reinforced Concrete Beam is Given GO
Effective Depth of Beam when Shearing Unit Stress in a Reinforced Concrete Beam is Given GO
Cross-Sectional Area of Web Reinforcement GO
Total Shear when Cross-Sectional Area of Web Reinforcement is Given GO
Shear Carried by Concrete when Cross-Sectional Area of Web Reinforcement is Given GO
Effective Depth when Cross-Sectional Area of Web Reinforcement is Given GO
Stirrups Spacing when Cross-Sectional Area of Web Reinforcement is Given GO

Define Shearing Stress?

Shear stress, often denoted by τ, is the component of stress coplanar with a material cross section. It arises from the shear force, the component of force vector parallel to the material cross section.

How to Calculate Shearing Unit Stress in a Reinforced Concrete Beam?

Shearing Unit Stress in a Reinforced Concrete Beam calculator uses Shearing Unit Stress=Total Shear/(Beam Width*Depth of the Beam) to calculate the Shearing Unit Stress, The Shearing Unit Stress in a Reinforced Concrete Beam formula is defined as the total shear force acting on a unit area of the body. Shearing Unit Stress and is denoted by v symbol.

How to calculate Shearing Unit Stress in a Reinforced Concrete Beam using this online calculator? To use this online calculator for Shearing Unit Stress in a Reinforced Concrete Beam, enter Total Shear (V), Beam Width (b) and Depth of the Beam (D) and hit the calculate button. Here is how the Shearing Unit Stress in a Reinforced Concrete Beam calculation can be explained with given input values -> 0.03937 = 100/(0.01*0.254000000001016).

FAQ

What is Shearing Unit Stress in a Reinforced Concrete Beam?
The Shearing Unit Stress in a Reinforced Concrete Beam formula is defined as the total shear force acting on a unit area of the body and is represented as v=V/(b*D) or Shearing Unit Stress=Total Shear/(Beam Width*Depth of the Beam). Total Shear is defined as the total shear force acting on the body, Beam Width is defined as the shortest/least measurement of the beam and Depth of the Beam is the overall depth of the cross section of the beam perpendicular to the axis of the beam.
How to calculate Shearing Unit Stress in a Reinforced Concrete Beam?
The Shearing Unit Stress in a Reinforced Concrete Beam formula is defined as the total shear force acting on a unit area of the body is calculated using Shearing Unit Stress=Total Shear/(Beam Width*Depth of the Beam). To calculate Shearing Unit Stress in a Reinforced Concrete Beam, you need Total Shear (V), Beam Width (b) and Depth of the Beam (D). With our tool, you need to enter the respective value for Total Shear, Beam Width and Depth of the Beam 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 Shearing Unit Stress?
In this formula, Shearing Unit Stress uses Total Shear, Beam Width and Depth of the Beam. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Shearing Unit Stress=Total Shear/(Beam Width*Distance from Compression to Centroid Reinforcment)
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