Allowable Compressive Stress when Slenderness Ratio is Less than Cc Calculator

✖Effective Length Factor is the factor used for the members in the frame. It depends on the ratio of compression member stiffness to the end restraint stiffness.ⓘ Effective Length Factor [k]			+10% -10%
✖Effective Column Length of a column is the length of an equivalent pin-ended column that has the same load-carrying capacity and buckling behaviour as the actual column with different end conditions.ⓘ Effective Column Length [l]			+10% -10%
✖Radius of Gyration is the distance from the axis of rotation to a point where the total mass of any body is supposed to be concentrated.ⓘ Radius of Gyration [r]			+10% -10%
✖Factor for Allowable Stress Design is the usual term used to demarcate between inelastic and elastic member buckling.ⓘ Factor for Allowable Stress Design [C_c]			+10% -10%
✖Yield Stress of Steel is the stress at which the material begins to deform plastically, meaning it will not return to its original shape when the applied force is removed.ⓘ Yield Stress of Steel [F_y]			+10% -10%
✖Safety factor otherwise called as factor of safety expresses how much stronger a system is than it needs to be for an intended load.ⓘ Safety Factor [F_s]			+10% -10%

✖Allowable Compression Stress is the maximum stress (tensile, compressive or bending) that is allowed to be applied on a structural material.ⓘ Allowable Compressive Stress when Slenderness Ratio is Less than Cc [F_a]

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Allowable Compressive Stress when Slenderness Ratio is Less than Cc Solution

STEP 0: Pre-Calculation Summary

Formula Used

Allowable Compression Stress = ((1-((((Effective Length Factor*Effective Column Length)/Radius of Gyration)^2)/(2*Factor for Allowable Stress Design^2)))*Yield Stress of Steel)/Safety Factor
F_a = ((1-((((k*l)/r)^2)/(2*C_c^2)))*F_y)/F_s
This formula uses 7 Variables

Variables Used

Allowable Compression Stress - (Measured in Pascal) - Allowable Compression Stress is the maximum stress (tensile, compressive or bending) that is allowed to be applied on a structural material.
Effective Length Factor - Effective Length Factor is the factor used for the members in the frame. It depends on the ratio of compression member stiffness to the end restraint stiffness.
Effective Column Length - (Measured in Meter) - Effective Column Length of a column is the length of an equivalent pin-ended column that has the same load-carrying capacity and buckling behaviour as the actual column with different end conditions.
Radius of Gyration - (Measured in Meter) - Radius of Gyration is the distance from the axis of rotation to a point where the total mass of any body is supposed to be concentrated.
Factor for Allowable Stress Design - Factor for Allowable Stress Design is the usual term used to demarcate between inelastic and elastic member buckling.
Yield Stress of Steel - (Measured in Pascal) - Yield Stress of Steel is the stress at which the material begins to deform plastically, meaning it will not return to its original shape when the applied force is removed.
Safety Factor - Safety factor otherwise called as factor of safety expresses how much stronger a system is than it needs to be for an intended load.

STEP 1: Convert Input(s) to Base Unit

Effective Length Factor: 0.75 --> No Conversion Required
Effective Column Length: 3000 Millimeter --> 3 Meter (Check conversion here)
Radius of Gyration: 87 Millimeter --> 0.087 Meter (Check conversion here)
Factor for Allowable Stress Design: 125.66 --> No Conversion Required
Yield Stress of Steel: 250 Megapascal --> 250000000 Pascal (Check conversion here)
Safety Factor: 1.74 --> No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

F_a = ((1-((((k*l)/r)^2)/(2*C_c^2)))*F_y)/F_s --> ((1-((((0.75*3)/0.087)^2)/(2*125.66^2)))*250000000)/1.74

Evaluating ... ...

F_a = 140635222.350094

STEP 3: Convert Result to Output's Unit

140635222.350094 Pascal -->140.635222350094 Megapascal (Check conversion here)

FINAL ANSWER

140.635222350094 ≈ 140.6352 Megapascal <-- Allowable Compression Stress

(Calculation completed in 00.020 seconds)

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< Allowable Stress Design for Building Columns Calculators

Allowable Compressive Stress when Slenderness Ratio is Less than Cc

LaTeX Go Allowable Compression Stress = ((1-((((Effective Length Factor*Effective Column Length)/Radius of Gyration)^2)/(2*Factor for Allowable Stress Design^2)))*Yield Stress of Steel)/Safety Factor

Allowable Compressive Stress when Slenderness Ratio is Greater than Cc

LaTeX Go Allowable Compression Stress = (12*pi^2*Modulus of Elasticity of Steel)/(23*((Effective Length Factor*Effective Column Length)/Radius of Gyration)^2)

Slenderness Ratio Used for Separation

LaTeX Go Factor for Allowable Stress Design = sqrt((2*(pi^2)*Modulus of Elasticity of Steel)/Yield Stress of Steel)

Factor for Unbraced Segment of any Cross-Section

LaTeX Go Factor for Allowable Stress Design = 1986.66/sqrt(Yield Stress of Steel)

Allowable Compressive Stress when Slenderness Ratio is Less than Cc Formula

LaTeX Go

What is Allowable Stress Design or ASD?

In the Allowable Stress (or working stress) Design, member stresses computed under the action of service (or working) loads are compared to some predesignated stresses called allowable stresses. The allowable stresses are usually expressed as a function of the yield stress or tensile stress of the material.

Define Radius of Gyration & Slenderness Ratio.

The radius of gyration is defined as the imaginary distance from the centroid at which the area of the cross-section is imagined to be focused on a point to obtain the same moment of inertia. It is the perpendicular distance from point mass to the axis of rotation.
The slenderness ratio can also be defined as the ratio of the effective length of the column to the minimum radius of gyration1. It serves as a measure of the column’s ability to withstand buckling pressure. In structural engineering, slenderness is a measure of the propensity of a column to buckle.

How to Calculate Allowable Compressive Stress when Slenderness Ratio is Less than Cc?

Allowable Compressive Stress when Slenderness Ratio is Less than Cc calculator uses Allowable Compression Stress = ((1-((((Effective Length Factor*Effective Column Length)/Radius of Gyration)^2)/(2*Factor for Allowable Stress Design^2)))*Yield Stress of Steel)/Safety Factor to calculate the Allowable Compression Stress, The Allowable Compressive Stress when Slenderness Ratio is Less than Cc formula is defined as the maximum limit of compressive stress that can be taken by the section when the condition specified is satisfied when the unbraced segment factor is less than the slenderness ratio. Allowable Compression Stress is denoted by F_a symbol.

How to calculate Allowable Compressive Stress when Slenderness Ratio is Less than Cc using this online calculator? To use this online calculator for Allowable Compressive Stress when Slenderness Ratio is Less than Cc, enter Effective Length Factor (k), Effective Column Length (l), Radius of Gyration (r), Factor for Allowable Stress Design (C_c), Yield Stress of Steel (F_y) & Safety Factor (F_s) and hit the calculate button. Here is how the Allowable Compressive Stress when Slenderness Ratio is Less than Cc calculation can be explained with given input values -> 0.000141 = ((1-((((0.75*3)/0.087)^2)/(2*125.66^2)))*250000000)/1.74.

FAQ

What is Allowable Compressive Stress when Slenderness Ratio is Less than Cc?

The Allowable Compressive Stress when Slenderness Ratio is Less than Cc formula is defined as the maximum limit of compressive stress that can be taken by the section when the condition specified is satisfied when the unbraced segment factor is less than the slenderness ratio and is represented as F_a = ((1-((((k*l)/r)^2)/(2*C_c^2)))*F_y)/F_s or Allowable Compression Stress = ((1-((((Effective Length Factor*Effective Column Length)/Radius of Gyration)^2)/(2*Factor for Allowable Stress Design^2)))*Yield Stress of Steel)/Safety Factor. Effective Length Factor is the factor used for the members in the frame. It depends on the ratio of compression member stiffness to the end restraint stiffness, Effective Column Length of a column is the length of an equivalent pin-ended column that has the same load-carrying capacity and buckling behaviour as the actual column with different end conditions, Radius of Gyration is the distance from the axis of rotation to a point where the total mass of any body is supposed to be concentrated, Factor for Allowable Stress Design is the usual term used to demarcate between inelastic and elastic member buckling, Yield Stress of Steel is the stress at which the material begins to deform plastically, meaning it will not return to its original shape when the applied force is removed & Safety factor otherwise called as factor of safety expresses how much stronger a system is than it needs to be for an intended load.

How to calculate Allowable Compressive Stress when Slenderness Ratio is Less than Cc?

The Allowable Compressive Stress when Slenderness Ratio is Less than Cc formula is defined as the maximum limit of compressive stress that can be taken by the section when the condition specified is satisfied when the unbraced segment factor is less than the slenderness ratio is calculated using Allowable Compression Stress = ((1-((((Effective Length Factor*Effective Column Length)/Radius of Gyration)^2)/(2*Factor for Allowable Stress Design^2)))*Yield Stress of Steel)/Safety Factor. To calculate Allowable Compressive Stress when Slenderness Ratio is Less than Cc, you need Effective Length Factor (k), Effective Column Length (l), Radius of Gyration (r), Factor for Allowable Stress Design (C_c), Yield Stress of Steel (F_y) & Safety Factor (F_s). With our tool, you need to enter the respective value for Effective Length Factor, Effective Column Length, Radius of Gyration, Factor for Allowable Stress Design, Yield Stress of Steel & Safety 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 Allowable Compression Stress?

In this formula, Allowable Compression Stress uses Effective Length Factor, Effective Column Length, Radius of Gyration, Factor for Allowable Stress Design, Yield Stress of Steel & Safety Factor. We can use 1 other way(s) to calculate the same, which is/are as follows -

Allowable Compression Stress = (12*pi^2*Modulus of Elasticity of Steel)/(23*((Effective Length Factor*Effective Column Length)/Radius of Gyration)^2)

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