Transverse Shear force given Maximum Longitudinal Shear Stress in Web for I beam Solution

STEP 0: Pre-Calculation Summary
Formula Used
Shear Force = (Maximum Longitudinal Shear Stress*Width of Web*8*Area Moment of Inertia)/((Width of Flange*(Overall Depth of I Beam^2-Depth of Web^2))+(Width of Web*(Depth of Web^2)))
V = (τmaxlongitudinal*bw*8*I)/((bf*(D^2-dw^2))+(bw*(dw^2)))
This formula uses 7 Variables
Variables Used
Shear Force - (Measured in Newton) - Shear Force is the force which causes shear deformation to occur in the shear plane.
Maximum Longitudinal Shear Stress - (Measured in Pascal) - Maximum Longitudinal Shear Stress is the greatest extent a shear force can be concentrated in a small area.
Width of Web - (Measured in Meter) - Width of Web (bw) is the effective width of the member for flanged section.
Area Moment of Inertia - (Measured in Meter⁴) - Area Moment of Inertia is a moment about the centroidal axis without considering mass.
Width of Flange - (Measured in Meter) - Width of Flange is the dimension of the flange measured parallel to the neutral axis.
Overall Depth of I Beam - (Measured in Meter) - Overall Depth of I Beam is the total height or depth of the I-section from the top fiber of the top flange to the bottom fiber of the bottom flange.
Depth of Web - (Measured in Meter) - Depth of Web is the dimension of the web measured perpendicular to the neutral axis.
STEP 1: Convert Input(s) to Base Unit
Maximum Longitudinal Shear Stress: 250.01 Megapascal --> 250010000 Pascal (Check conversion ​here)
Width of Web: 0.04 Meter --> 0.04 Meter No Conversion Required
Area Moment of Inertia: 36000000 Millimeter⁴ --> 3.6E-05 Meter⁴ (Check conversion ​here)
Width of Flange: 250 Millimeter --> 0.25 Meter (Check conversion ​here)
Overall Depth of I Beam: 800 Millimeter --> 0.8 Meter (Check conversion ​here)
Depth of Web: 15 Millimeter --> 0.015 Meter (Check conversion ​here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
V = (τmaxlongitudinal*bw*8*I)/((bf*(D^2-dw^2))+(bw*(dw^2))) --> (250010000*0.04*8*3.6E-05)/((0.25*(0.8^2-0.015^2))+(0.04*(0.015^2)))
Evaluating ... ...
V = 18006.037407922
STEP 3: Convert Result to Output's Unit
18006.037407922 Newton -->18.006037407922 Kilonewton (Check conversion ​here)
FINAL ANSWER
18.006037407922 18.00604 Kilonewton <-- Shear Force
(Calculation completed in 00.004 seconds)

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I Beam Calculators

Moment of Inertia given Longitudinal Shear Stress in Web for I beam
​ LaTeX ​ Go Area Moment of Inertia = ((Width of Flange*Shear Force)/(8*Shear Stress*Width of Web))*(Overall Depth of I Beam^2-Depth of Web^2)
Moment of Inertia given Longitudinal Shear Stress at lower edge in Flange of I beam
​ LaTeX ​ Go Area Moment of Inertia = (Shear Force/(8*Shear Stress))*(Overall Depth of I Beam^2-Depth of Web^2)
Longitudinal Shear Stress in Flange at Lower Depth of I beam
​ LaTeX ​ Go Shear Stress = (Shear Force/(8*Area Moment of Inertia))*(Overall Depth of I Beam^2-Depth of Web^2)
Transverse Shear given Longitudinal Shear Stress in Flange for I beam
​ LaTeX ​ Go Shear Force = (8*Area Moment of Inertia*Shear Stress)/(Overall Depth of I Beam^2-Depth of Web^2)

Transverse Shear force given Maximum Longitudinal Shear Stress in Web for I beam Formula

​LaTeX ​Go
Shear Force = (Maximum Longitudinal Shear Stress*Width of Web*8*Area Moment of Inertia)/((Width of Flange*(Overall Depth of I Beam^2-Depth of Web^2))+(Width of Web*(Depth of Web^2)))
V = (τmaxlongitudinal*bw*8*I)/((bf*(D^2-dw^2))+(bw*(dw^2)))

What is Longitudinal Shear Stress?

The longitudinal shear stress in a beam occurs along the longitudinal axis and is visualized by a slip in the layers of the beam. In addition to the transverse shear force, a longitudinal shear force also exists in the beam. This load produces a shear stress called the longitudinal (or horizontal) shear stress.

What is Transverse shear stress?

The shear stress due to bending is often referred to as transverse shear. Unlike normal stress, the highest stress value occurs at the neutral axis, while there is no stress on the walls.

How to Calculate Transverse Shear force given Maximum Longitudinal Shear Stress in Web for I beam?

Transverse Shear force given Maximum Longitudinal Shear Stress in Web for I beam calculator uses Shear Force = (Maximum Longitudinal Shear Stress*Width of Web*8*Area Moment of Inertia)/((Width of Flange*(Overall Depth of I Beam^2-Depth of Web^2))+(Width of Web*(Depth of Web^2))) to calculate the Shear Force, The Transverse Shear force given Maximum Longitudinal Shear Stress in Web for I beam is defined as the shear force that causes both longitudinal and transverse shear stresses in the I-beam. When a transverse shear force is applied, it tends to cause warping of the cross section. Shear Force is denoted by V symbol.

How to calculate Transverse Shear force given Maximum Longitudinal Shear Stress in Web for I beam using this online calculator? To use this online calculator for Transverse Shear force given Maximum Longitudinal Shear Stress in Web for I beam, enter Maximum Longitudinal Shear Stress maxlongitudinal), Width of Web (bw), Area Moment of Inertia (I), Width of Flange (bf), Overall Depth of I Beam (D) & Depth of Web (dw) and hit the calculate button. Here is how the Transverse Shear force given Maximum Longitudinal Shear Stress in Web for I beam calculation can be explained with given input values -> 0.018005 = (250010000*0.04*8*3.6E-05)/((0.25*(0.8^2-0.015^2))+(0.04*(0.015^2))).

FAQ

What is Transverse Shear force given Maximum Longitudinal Shear Stress in Web for I beam?
The Transverse Shear force given Maximum Longitudinal Shear Stress in Web for I beam is defined as the shear force that causes both longitudinal and transverse shear stresses in the I-beam. When a transverse shear force is applied, it tends to cause warping of the cross section and is represented as V = (τmaxlongitudinal*bw*8*I)/((bf*(D^2-dw^2))+(bw*(dw^2))) or Shear Force = (Maximum Longitudinal Shear Stress*Width of Web*8*Area Moment of Inertia)/((Width of Flange*(Overall Depth of I Beam^2-Depth of Web^2))+(Width of Web*(Depth of Web^2))). Maximum Longitudinal Shear Stress is the greatest extent a shear force can be concentrated in a small area, Width of Web (bw) is the effective width of the member for flanged section, Area Moment of Inertia is a moment about the centroidal axis without considering mass, Width of Flange is the dimension of the flange measured parallel to the neutral axis, Overall Depth of I Beam is the total height or depth of the I-section from the top fiber of the top flange to the bottom fiber of the bottom flange & Depth of Web is the dimension of the web measured perpendicular to the neutral axis.
How to calculate Transverse Shear force given Maximum Longitudinal Shear Stress in Web for I beam?
The Transverse Shear force given Maximum Longitudinal Shear Stress in Web for I beam is defined as the shear force that causes both longitudinal and transverse shear stresses in the I-beam. When a transverse shear force is applied, it tends to cause warping of the cross section is calculated using Shear Force = (Maximum Longitudinal Shear Stress*Width of Web*8*Area Moment of Inertia)/((Width of Flange*(Overall Depth of I Beam^2-Depth of Web^2))+(Width of Web*(Depth of Web^2))). To calculate Transverse Shear force given Maximum Longitudinal Shear Stress in Web for I beam, you need Maximum Longitudinal Shear Stress maxlongitudinal), Width of Web (bw), Area Moment of Inertia (I), Width of Flange (bf), Overall Depth of I Beam (D) & Depth of Web (dw). With our tool, you need to enter the respective value for Maximum Longitudinal Shear Stress, Width of Web, Area Moment of Inertia, Width of Flange, Overall Depth of I Beam & Depth of Web 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 Maximum Longitudinal Shear Stress, Width of Web, Area Moment of Inertia, Width of Flange, Overall Depth of I Beam & Depth of Web. We can use 2 other way(s) to calculate the same, which is/are as follows -
  • Shear Force = (8*Area Moment of Inertia*Shear Stress)/(Overall Depth of I Beam^2-Depth of Web^2)
  • Shear Force = (8*Area Moment of Inertia*Shear Stress*Width of Web)/(Width of Flange*(Overall Depth of I Beam^2-Depth of Web^2))
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