Adjusted Design Value for End Grain in Bearing Parallel to Grain Solution

STEP 0: Pre-Calculation Summary
Formula Used
Adjusted Design Value = Design Value for Bearing*Load Duration Factor*Temperature Factor
F' = Fg*CD*Ct
This formula uses 4 Variables
Variables Used
Adjusted Design Value - (Measured in Pascal) - Adjusted design value is the value either in bending, compression, tension or shear by using other factors.
Design Value for Bearing - (Measured in Pascal) - Design value for bearing is the actual value.
Load Duration Factor - Load Duration Factor is based on the ability of wood to recover after a reasonable load has been applied for a given time.
Temperature Factor - Temperature factor is the factor used for wood that is expected to be exposed to high temperatures for long periods of time.
STEP 1: Convert Input(s) to Base Unit
Design Value for Bearing: 17 Megapascal --> 17000000 Pascal (Check conversion ​here)
Load Duration Factor: 0.74 --> No Conversion Required
Temperature Factor: 0.8 --> No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
F' = Fg*CD*Ct --> 17000000*0.74*0.8
Evaluating ... ...
F' = 10064000
STEP 3: Convert Result to Output's Unit
10064000 Pascal -->10.064 Megapascal (Check conversion ​here)
FINAL ANSWER
10.064 Megapascal <-- Adjusted Design Value
(Calculation completed in 00.020 seconds)

Credits

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Created by Suraj Kumar
Birsa Institute of Technology (BIT), Sindri
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Adjustment Factors for Design Values Calculators

Adjusted Design Value for Compression Parallel to Grain
​ LaTeX ​ Go Adjusted Design Value = (Design Value for Parallel Compression*Load Duration Factor*Wet Service Factor*Temperature Factor*Size Factor*Column Stability Factor)
Adjusted Design Value for Shear
​ LaTeX ​ Go Adjusted Design Value = Design Value for Shear*Load Duration Factor*Wet Service Factor*Temperature Factor*Shear Stress Factor
Adjusted Design Value for Tension
​ LaTeX ​ Go Adjusted Design Value = (Design Value for Tension*Load Duration Factor*Wet Service Factor*Temperature Factor*Size Factor)
Adjusted Design Value for Compression Perpendicular to Grain
​ LaTeX ​ Go Adjusted Design Value = Design Value for Compression Perpendicular*Wet Service Factor*Temperature Factor*Bearing Area Factor

Adjusted Design Value for End Grain in Bearing Parallel to Grain Formula

​LaTeX ​Go
Adjusted Design Value = Design Value for Bearing*Load Duration Factor*Temperature Factor
F' = Fg*CD*Ct

What is Adjusted Design Value?

Application of the required adjustment is necessary as there is always some variation in the design values calculated in timber.

What is Column Stability Factor?

The column stability factor is to ensure that weak-axis buckling or torsional buckling does not occur over non-laterally supported lengths. Note that this is similar to the beam stability factor except it deals with columns in compression, vs. beams in flexure.

How to Calculate Adjusted Design Value for End Grain in Bearing Parallel to Grain?

Adjusted Design Value for End Grain in Bearing Parallel to Grain calculator uses Adjusted Design Value = Design Value for Bearing*Load Duration Factor*Temperature Factor to calculate the Adjusted Design Value, The Adjusted Design Value for End Grain in Bearing Parallel to Grain formula is defined by taking some factors into consideration such as load-duration factor, size factor and design value for compression parallel to the grain. Adjusted Design Value is denoted by F' symbol.

How to calculate Adjusted Design Value for End Grain in Bearing Parallel to Grain using this online calculator? To use this online calculator for Adjusted Design Value for End Grain in Bearing Parallel to Grain, enter Design Value for Bearing (Fg), Load Duration Factor (CD) & Temperature Factor (Ct) and hit the calculate button. Here is how the Adjusted Design Value for End Grain in Bearing Parallel to Grain calculation can be explained with given input values -> 1E-5 = 17000000*0.74*0.8.

FAQ

What is Adjusted Design Value for End Grain in Bearing Parallel to Grain?
The Adjusted Design Value for End Grain in Bearing Parallel to Grain formula is defined by taking some factors into consideration such as load-duration factor, size factor and design value for compression parallel to the grain and is represented as F' = Fg*CD*Ct or Adjusted Design Value = Design Value for Bearing*Load Duration Factor*Temperature Factor. Design value for bearing is the actual value, Load Duration Factor is based on the ability of wood to recover after a reasonable load has been applied for a given time & Temperature factor is the factor used for wood that is expected to be exposed to high temperatures for long periods of time.
How to calculate Adjusted Design Value for End Grain in Bearing Parallel to Grain?
The Adjusted Design Value for End Grain in Bearing Parallel to Grain formula is defined by taking some factors into consideration such as load-duration factor, size factor and design value for compression parallel to the grain is calculated using Adjusted Design Value = Design Value for Bearing*Load Duration Factor*Temperature Factor. To calculate Adjusted Design Value for End Grain in Bearing Parallel to Grain, you need Design Value for Bearing (Fg), Load Duration Factor (CD) & Temperature Factor (Ct). With our tool, you need to enter the respective value for Design Value for Bearing, Load Duration Factor & Temperature Factor 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 Adjusted Design Value?
In this formula, Adjusted Design Value uses Design Value for Bearing, Load Duration Factor & Temperature Factor. We can use 3 other way(s) to calculate the same, which is/are as follows -
  • Adjusted Design Value = (Design Value for Tension*Load Duration Factor*Wet Service Factor*Temperature Factor*Size Factor)
  • Adjusted Design Value = Design Value for Shear*Load Duration Factor*Wet Service Factor*Temperature Factor*Shear Stress Factor
  • Adjusted Design Value = Design Value for Compression Perpendicular*Wet Service Factor*Temperature Factor*Bearing Area Factor
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