FormulaDen.com

Physics Chemistry Math Chemical Engineering Civil Electrical Electronics Electronics and Instrumentation Materials Science Mechanical Production Engineering Financial Health

Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 Formula

GoValue Obtained from Secant Formula given Allowable Axial Compression Stress Formula

Fx Copy

LaTeX Copy

Value obtained from secant formula is the stress value on the column of mild steel. Check FAQs

σ c' = \frac{F a}{1.2 - (\frac{L eff}{800 \cdot r least})}

σ_c' - Value obtained from Secant Formula?F_a - Allowable compression stress?L_eff - Effective Column Length?r_least - Least Radius of Gyration Column?

Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 Example

With values

With units

Only example

Here is how the Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 equation looks like with Values.

Here is how the Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 equation looks like with Units.

Here is how the Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 equation looks like.

8.9266 = \frac{10}{1.2 - (\frac{3000}{800 \cdot 47.02})}

8.9266MPa = \frac{10MPa}{1.2 - (\frac{3000mm}{800 \cdot 47.02mm})}

8.9266 = \frac{10}{1.2 - (\frac{3000}{800 \cdot 47.02})}

Tip: Use pencil ( Pencil

) icon above to edit Input Values and Units.

Calculate

Recalculate

Solution

Copy

Reset

You are here -

Home » Category

Physics » Category

Mechanical » Category

Strength of Materials » fx Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160

Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 Solution

Follow our step by step solution on how to calculate Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160?

FIRST Step Consider the formula

σ c' = \frac{F a}{1.2 - (\frac{L eff}{800 \cdot r least})}

Next Step Substitute values of Variables

∴

σ c' = \frac{10MPa}{1.2 - (\frac{3000mm}{800 \cdot 47.02mm})}

Next Step Convert Units

∴

σ c' = \frac{1E+7Pa}{1.2 - (\frac{3m}{800 \cdot 0.047m})}

Next Step Prepare to Evaluate

∴

σ c' = \frac{1E+7}{1.2 - (\frac{3}{800 \cdot 0.047})}

Next Step Evaluate

∴

σ c' = 8926605.15624407Pa

Next Step Convert to Output's Unit

∴

σ c' = 8.92660515624407MPa

LAST Step Rounding Answer

∴

σ c' = 8.9266MPa

Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 Formula Elements

Variables

Value obtained from Secant Formula

Value obtained from secant formula is the stress value on the column of mild steel.

Symbol: σ_c'

Measurement: PressureUnit: MPa

Note: Value should be greater than 0.

Formulas to find Value obtained from Secant Formula

Allowable compression stress

Allowable compression stress is the maximum stress (tensile, compressive or bending) that is allowed to be applied on a structural material.

Symbol: F_a

Measurement: PressureUnit: MPa

Note: Value can be positive or negative.

Formulas to find Allowable compression stress

Effective Column Length

Effective Column Length can be defined as the length of an equivalent pin-ended column having the same load-carrying capacity as the member under consideration.

Symbol: L_eff

Measurement: LengthUnit: mm

Note: Value can be positive or negative.

Formulas to find Effective Column Length

Least Radius of Gyration Column

Least Radius of Gyration Column is the smallest value of the radius of gyration is used for structural calculations.

Symbol: r_least

Measurement: LengthUnit: mm

Note: Value can be positive or negative.

Formulas to find Least Radius of Gyration Column

Other Formulas to find Value obtained from Secant Formula

Go Value Obtained from Secant Formula given Allowable Axial Compression Stress

σ c' = \frac{\frac{F yw}{f s}}{1 + (0.20 \cdot ((\frac{EAR}{r least}) \cdot (\sqrt{f s \cdot \frac{P compressive}{4 \cdot ε column}})))}

Other formulas in Formula By I.S. Code For Mild Steel category

Go Allowable Axial Compression Stress for Slenderness Ratio 0 to 160

F a = \frac{\frac{F yw}{f s}}{1 + (0.20 \cdot ((\frac{EAR}{r least}) \cdot (\sqrt{f s \cdot \frac{P compressive}{4 \cdot ε column}})))}

Go Minimum Yield Stress for Allowable Axial Compression Stress for Slenderness Ratio between 0 to 160

F yw = F a \cdot (1 + (0.20 \cdot ((\frac{EAR}{r least}) \cdot (\sqrt{f s \cdot \frac{P compressive}{4 \cdot ε column}})))) \cdot f s

Go Allowable Axial Compression Stress for Slenderness Ratio greater than 160

F a = σ c' \cdot (1.2 - (\frac{L eff}{800 \cdot r least}))

Go Effective Column Length given Allowable Axial Compression Stress

L eff = (\frac{(\frac{F yw}{f s \cdot F a}) - 1}{0.20 \cdot ((\sqrt{f s \cdot \frac{P compressive}{4 \cdot ε column}}))}) \cdot r least

How to Evaluate Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160?

Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 evaluator uses Value obtained from Secant Formula = Allowable compression stress/(1.2-(Effective Column Length/(800*Least Radius of Gyration Column))) to evaluate the Value obtained from Secant Formula, Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 formula is defined as a calculation that determines the critical buckling stress of a mild steel column under axial compression, considering the effective length and radius of the column. Value obtained from Secant Formula is denoted by σ_c' symbol.

How to evaluate Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 using this online evaluator? To use this online evaluator for Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160, enter Allowable compression stress (F_a), Effective Column Length (L_eff) & Least Radius of Gyration Column (r_least) and hit the calculate button.

FAQs on Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160

What is the formula to find Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160?

The formula of Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 is expressed as Value obtained from Secant Formula = Allowable compression stress/(1.2-(Effective Column Length/(800*Least Radius of Gyration Column))). Here is an example- 8.9E-6 = 10000000/(1.2-(3/(800*0.04702))).

How to calculate Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160?

With Allowable compression stress (F_a), Effective Column Length (L_eff) & Least Radius of Gyration Column (r_least) we can find Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 using the formula - Value obtained from Secant Formula = Allowable compression stress/(1.2-(Effective Column Length/(800*Least Radius of Gyration Column))).

What are the other ways to Calculate Value obtained from Secant Formula?

Here are the different ways to Calculate Value obtained from Secant Formula-

Value obtained from Secant Formula=(Specified minimum yield stress for column/Factor of Safety)/(1+(0.20*((Effective Interest Rate/Least Radius of Gyration Column)*(sqrt(Factor of Safety*Column Compressive load/(4*Modulus of Elasticity Column))))))

Can the Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 be negative?

No, the Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160, measured in Pressure cannot be negative.

Which unit is used to measure Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160?

Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 is usually measured using the Megapascal[MPa] for Pressure. Pascal[MPa], Kilopascal[MPa], Bar[MPa] are the few other units in which Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 can be measured.

Let Others Know

✖

Facebook

Twitter

Copied!

Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 Formula

​GoValue Obtained from Secant Formula given Allowable Axial Compression Stress Formula

Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 Example

Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 Solution

Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160 Formula Elements

Other Formulas to find Value obtained from Secant Formula

Other formulas in Formula By I.S. Code For Mild Steel category

How to Evaluate Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160?

FAQs on Value Obtained from Secant given Axial Compression Stress Slenderness Ratio Greater than 160

Variable Name

GoValue Obtained from Secant Formula given Allowable Axial Compression Stress Formula