Tensile Strength of Connected Part using Allowable Bearing Stress Solution

STEP 0: Pre-Calculation Summary
Formula Used
Tensile Strength MPA = Allowable Bearing Stress/1.2
TS = Fp/1.2
This formula uses 2 Variables
Variables Used
Tensile Strength MPA - (Measured in Pascal) - Tensile Strength MPA is the stress at the maximum on the engineering stress-strain curve in Megapascal.
Allowable Bearing Stress - (Measured in Pascal) - Allowable Bearing Stress is the maximum bearing stress that can be applied to a material or a structural element without causing failure.
STEP 1: Convert Input(s) to Base Unit
Allowable Bearing Stress: 9.8 Megapascal --> 9800000 Pascal (Check conversion here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
TS = Fp/1.2 --> 9800000/1.2
Evaluating ... ...
TS = 8166666.66666667
STEP 3: Convert Result to Output's Unit
8166666.66666667 Pascal -->8.16666666666667 Megapascal (Check conversion here)
FINAL ANSWER
8.16666666666667 8.166667 Megapascal <-- Tensile Strength MPA
(Calculation completed in 00.004 seconds)

Credits

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National Institute of Technology (NIT), Warangal
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12 Design of Stiffeners under Loads Calculators

Distance between Outer Face of Column Flange and Web Toe given Cross-Sectional Area
Go Distance Between Flange and Web = (((Computed Force-(Cross Sectional Plate Area*Stiffener Yield Stress))/(Column Yield Stress*Column Web Thickness))-Flange Thickness)/5
Thickness of Column Web given Cross-Sectional Area of Column Web Stiffeners
Go Column Web Thickness = (Computed Force-(Cross Sectional Plate Area*Stiffener Yield Stress))/(Column Yield Stress*(Flange Thickness+5*Distance Between Flange and Web))
Column Yield Stress given Cross-Sectional Area of Column Web Stiffeners
Go Column Yield Stress = (Computed Force-(Cross Sectional Plate Area*Stiffener Yield Stress))/(Column Web Thickness*(Flange Thickness+5*Distance Between Flange and Web))
Stiffener Yield Stress given Cross Sectional Area of Column Web Stiffeners
Go Stiffener Yield Stress = (Computed Force-Column Yield Stress*Column Web Thickness*(Flange Thickness+5*Distance Between Flange and Web))/Cross Sectional Plate Area
Computed Load given Cross-Sectional Area of Column Web Stiffeners
Go Computed Force = (Cross Sectional Plate Area*Stiffener Yield Stress)+(Column Yield Stress*Column Web Thickness*(Flange Thickness+5*Distance Between Flange and Web))
Cross sectional area of Column Web Stiffeners
Go Cross Sectional Plate Area = (Computed Force-Column Yield Stress*Column Web Thickness*(Flange Thickness+5*Distance Between Flange and Web))/Stiffener Yield Stress
Thickness of Column Web given Column Web Depth Clear of Fillets
Go Column Web Thickness = ((Web Depth*Computed Force)/(4100*sqrt(Column Yield Stress)))^(1/3)
Computed Force for Column-Web Depth of Fillets
Go Computed Force = (4100*Column Web Thickness^3*sqrt(Column Yield Stress))/Web Depth
Column-Web Depth Clear of Fillets
Go Web Depth = (4100*Column Web Thickness^3*sqrt(Column Yield Stress))/Computed Force
Thickness of Column Flange
Go Flange Thickness = 0.4*sqrt(Computed Force/Column Yield Stress)
Tensile Strength of Connected Part using Allowable Bearing Stress
Go Tensile Strength MPA = Allowable Bearing Stress/1.2
Allowable Bearing Stress on Projected Area of Fasteners
Go Allowable Bearing Stress = 1.2*Tensile Strength MPA

Tensile Strength of Connected Part using Allowable Bearing Stress Formula

Tensile Strength MPA = Allowable Bearing Stress/1.2
TS = Fp/1.2

What is Computed Force?

The Computed Force is defined as the force delivered by a flange of the moment connection plate when the stiffeners are under load.

What is Allowable Bearing Stress?

The Allowable Bearing Stress is defined as the maximum load that the footing can support without failure with appropriate factors of safety.

How to Calculate Tensile Strength of Connected Part using Allowable Bearing Stress?

Tensile Strength of Connected Part using Allowable Bearing Stress calculator uses Tensile Strength MPA = Allowable Bearing Stress/1.2 to calculate the Tensile Strength MPA, The Tensile Strength of Connected Part using Allowable Bearing Stress formula is defined as the maximum load that a material can support without fracture when being stretched. Tensile Strength MPA is denoted by TS symbol.

How to calculate Tensile Strength of Connected Part using Allowable Bearing Stress using this online calculator? To use this online calculator for Tensile Strength of Connected Part using Allowable Bearing Stress, enter Allowable Bearing Stress (Fp) and hit the calculate button. Here is how the Tensile Strength of Connected Part using Allowable Bearing Stress calculation can be explained with given input values -> 8.2E-6 = 9800000/1.2.

FAQ

What is Tensile Strength of Connected Part using Allowable Bearing Stress?
The Tensile Strength of Connected Part using Allowable Bearing Stress formula is defined as the maximum load that a material can support without fracture when being stretched and is represented as TS = Fp/1.2 or Tensile Strength MPA = Allowable Bearing Stress/1.2. Allowable Bearing Stress is the maximum bearing stress that can be applied to a material or a structural element without causing failure.
How to calculate Tensile Strength of Connected Part using Allowable Bearing Stress?
The Tensile Strength of Connected Part using Allowable Bearing Stress formula is defined as the maximum load that a material can support without fracture when being stretched is calculated using Tensile Strength MPA = Allowable Bearing Stress/1.2. To calculate Tensile Strength of Connected Part using Allowable Bearing Stress, you need Allowable Bearing Stress (Fp). With our tool, you need to enter the respective value for Allowable Bearing Stress and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
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