Allowable Bearing Stresses on Pins not Subject to Rotation for Bridges for LFD Solution

STEP 0: Pre-Calculation Summary
Formula Used
Allowable Bearing Stresses on Pins = 0.80*Yield Strength of Steel
Fp = 0.80*fy
This formula uses 2 Variables
Variables Used
Allowable Bearing Stresses on Pins - (Measured in Pascal) - Allowable Bearing Stresses on Pins is the maximum bearing stress that can be applied to the pins such that it is safe against instability due to shear failure.
Yield Strength of Steel - (Measured in Pascal) - Yield strength of steel is the level of stress that corresponds to the yield point.
STEP 1: Convert Input(s) to Base Unit
Yield Strength of Steel: 250 Megapascal --> 250000000 Pascal (Check conversion here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Fp = 0.80*fy --> 0.80*250000000
Evaluating ... ...
Fp = 200000000
STEP 3: Convert Result to Output's Unit
200000000 Pascal -->200 Megapascal (Check conversion here)
FINAL ANSWER
200 Megapascal <-- Allowable Bearing Stresses on Pins
(Calculation completed in 00.004 seconds)

Credits

Created by Rithik Agrawal
National Institute of Technology Karnataka (NITK), Surathkal
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14 Load-Factor Design for Bridge Beams Calculators

Maximum Unbraced Length for Symmetrical Flexural Compact Section for LFD of Bridges
Go Max Unbraced Length for Flexural Compact Section = ((3600-2200*(Smaller Moment/Maximum Bending Strength))*Radius of Gyration)/Yield Strength of Steel
Minimum Flange Thickness for Symmetrical Flexural Braced Non-Compact Section for LFD of Bridges
Go Flange Minimum Thickness = (Width of Projection of Flange*sqrt(Yield Strength of Steel))/69.6
Width of Projection of Flange for Compact Section for LFD given Minimum Flange Thickness
Go Width of Projection of Flange = (65*Flange Minimum Thickness)/(sqrt(Yield Strength of Steel))
Minimum Flange Thickness for Symmetrical Flexural Compact Section for LFD of Bridges
Go Flange Minimum Thickness = (Width of Projection of Flange*sqrt(Yield Strength of Steel))/65
Maximum Unbraced Length for Symmetrical Flexural Braced Non-Compact Section for LFD of Bridges
Go Maximum Unbraced Length = (20000*Flange Area)/(Yield Strength of Steel*Depth of Section)
Depth of Section for Braced Non-Compact Section for LFD given Maximum Unbraced Length
Go Depth of Section = (20000*Flange Area)/(Yield Strength of Steel*Maximum Unbraced Length)
Area of Flange for Braced Non-Compact Section for LFD
Go Flange Area = (Maximum Unbraced Length*Yield Strength of Steel*Depth of Section)/20000
Minimum Web Thickness for Symmetrical Flexural Compact Section for LFD of Bridges
Go Web Minimum Thickness = Depth of Section*sqrt(Yield Strength of Steel)/608
Maximum Bending Strength for Symmetrical Flexural Compact Section for LFD of Bridges
Go Maximum Bending Strength = Yield Strength of Steel*Plastic Section Modulus
Maximum Bending Strength for Symmetrical Flexural Braced Non-Compacted Section for LFD of Bridges
Go Maximum Bending Strength = Yield Strength of Steel*Section Modulus
Allowable Bearing Stresses on Pins not Subject to Rotation for Bridges for LFD
Go Allowable Bearing Stresses on Pins = 0.80*Yield Strength of Steel
Allowable Bearing Stresses on Pins Subject to Rotation for Bridges for LFD
Go Allowable Bearing Stresses on Pins = 0.40*Yield Strength of Steel
Minimum Web Thickness for Symmetrical Flexural Braced Non-Compact Section for LFD of Bridges
Go Web Minimum Thickness = Unsupported Distance between Flanges/150
Allowable Bearing Stresses on Pins for Buildings for LFD
Go Allowable Bearing Stresses on Pins = 0.9*Yield Strength of Steel

Allowable Bearing Stresses on Pins not Subject to Rotation for Bridges for LFD Formula

Allowable Bearing Stresses on Pins = 0.80*Yield Strength of Steel
Fp = 0.80*fy

What is Allowable Bearing Stress?

Allowable bearing stress is a value based on an arbitrary amount of deformation of a body subjected to a bearing pressure. The bearing stress criteria for aluminum alloys, if applied to heat-treated steel, would permit allowable stresses as much as 50 per cent greater than those used at present for steel.

How to Calculate Allowable Bearing Stresses on Pins not Subject to Rotation for Bridges for LFD?

Allowable Bearing Stresses on Pins not Subject to Rotation for Bridges for LFD calculator uses Allowable Bearing Stresses on Pins = 0.80*Yield Strength of Steel to calculate the Allowable Bearing Stresses on Pins, The Allowable Bearing Stresses on Pins not Subject to Rotation for Bridges for LFD formula is defined as the maximum working load for the member to sustain. Allowable Bearing Stresses on Pins is denoted by Fp symbol.

How to calculate Allowable Bearing Stresses on Pins not Subject to Rotation for Bridges for LFD using this online calculator? To use this online calculator for Allowable Bearing Stresses on Pins not Subject to Rotation for Bridges for LFD, enter Yield Strength of Steel (fy) and hit the calculate button. Here is how the Allowable Bearing Stresses on Pins not Subject to Rotation for Bridges for LFD calculation can be explained with given input values -> 0.0002 = 0.80*250000000.

FAQ

What is Allowable Bearing Stresses on Pins not Subject to Rotation for Bridges for LFD?
The Allowable Bearing Stresses on Pins not Subject to Rotation for Bridges for LFD formula is defined as the maximum working load for the member to sustain and is represented as Fp = 0.80*fy or Allowable Bearing Stresses on Pins = 0.80*Yield Strength of Steel. Yield strength of steel is the level of stress that corresponds to the yield point.
How to calculate Allowable Bearing Stresses on Pins not Subject to Rotation for Bridges for LFD?
The Allowable Bearing Stresses on Pins not Subject to Rotation for Bridges for LFD formula is defined as the maximum working load for the member to sustain is calculated using Allowable Bearing Stresses on Pins = 0.80*Yield Strength of Steel. To calculate Allowable Bearing Stresses on Pins not Subject to Rotation for Bridges for LFD, you need Yield Strength of Steel (fy). With our tool, you need to enter the respective value for Yield Strength of Steel 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 Allowable Bearing Stresses on Pins?
In this formula, Allowable Bearing Stresses on Pins uses Yield Strength of Steel. We can use 2 other way(s) to calculate the same, which is/are as follows -
  • Allowable Bearing Stresses on Pins = 0.9*Yield Strength of Steel
  • Allowable Bearing Stresses on Pins = 0.40*Yield Strength of Steel
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