Maximum Combined Stress on Short Column Solution

STEP 0: Pre-Calculation Summary
Formula Used
Maximum Combined Stress = ((Axial Compressive Load on Column/(Number of Columns*Cross Sectional Area of Column))+((Axial Compressive Load on Column*Eccentricity for Vessel Support)/(Number of Columns*Section Modulus of Vessel Support)))
f = ((PColumn/(NColumn*AColumn))+((PColumn*e)/(NColumn*Z)))
This formula uses 6 Variables
Variables Used
Maximum Combined Stress - (Measured in Pascal) - Maximum Combined Stress is the highest stress that occurs at any point in the material or structure, taking into account the effects of all types of loading.
Axial Compressive Load on Column - (Measured in Newton) - Axial Compressive Load on Column is a type of force that is applied along the axis, or central line, of a structural element such as a column.
Number of Columns - Number of Columns in a structure refers to the total number of vertical load-bearing members that support the weight of the structure and transfer it to the foundation.
Cross Sectional Area of Column - (Measured in Square Meter) - Cross sectional area of column is the area of the two-dimensional space that is obtained when the column is cut or sliced perpendicular to its longitudinal axis.
Eccentricity for Vessel Support - (Measured in Meter) - Eccentricity for Vessel Support is a non-negative real number that uniquely characterizes its shape.
Section Modulus of Vessel Support - (Measured in Cubic Meter) - Section Modulus of Vessel Support is a measure of its strength and ability to resist bending stress.
STEP 1: Convert Input(s) to Base Unit
Axial Compressive Load on Column: 5580 Newton --> 5580 Newton No Conversion Required
Number of Columns: 4 --> No Conversion Required
Cross Sectional Area of Column: 389 Square Millimeter --> 0.000389 Square Meter (Check conversion ​here)
Eccentricity for Vessel Support: 52 Millimeter --> 0.052 Meter (Check conversion ​here)
Section Modulus of Vessel Support: 22000 Cubic Millimeter --> 2.2E-05 Cubic Meter (Check conversion ​here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
f = ((PColumn/(NColumn*AColumn))+((PColumn*e)/(NColumn*Z))) --> ((5580/(4*0.000389))+((5580*0.052)/(4*2.2E-05)))
Evaluating ... ...
f = 6883390.97920075
STEP 3: Convert Result to Output's Unit
6883390.97920075 Pascal -->6.88339097920075 Newton per Square Millimeter (Check conversion ​here)
FINAL ANSWER
6.88339097920075 6.883391 Newton per Square Millimeter <-- Maximum Combined Stress
(Calculation completed in 00.004 seconds)

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​ LaTeX ​ Go Thickness of Horizontal Plate = ((0.7)*(Maximum Pressure on Horizontal Plate)*((Length of Horizontal Plate)^(2)/(Maximum Stress in Horizontal Plate fixed at Edges))*((Effective Width of Horizontal Plate)^(4)/((Length of Horizontal Plate)^(4)+(Effective Width of Horizontal Plate)^(4))))^(0.5)
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Maximum Compressive Stress Parallel to Edge of Gusset Plate
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Maximum Combined Stress on Short Column Formula

​LaTeX ​Go
Maximum Combined Stress = ((Axial Compressive Load on Column/(Number of Columns*Cross Sectional Area of Column))+((Axial Compressive Load on Column*Eccentricity for Vessel Support)/(Number of Columns*Section Modulus of Vessel Support)))
f = ((PColumn/(NColumn*AColumn))+((PColumn*e)/(NColumn*Z)))

What is Design Stress?

Design stress is a term used in engineering and structural design to describe the maximum allowable stress that a material or structure can sustain under specific loading conditions, while still maintaining an acceptable level of safety and reliability. The design stress is typically calculated using various factors such as safety factors, load factors, and material properties. The design stress is typically compared to the material's yield strength, which is the stress at which permanent deformation or yielding occurs, to ensure that the material or structure does not fail due to excessive stress. The design stress is also compared to various codes and standards, such as building codes or industry-specific standards, to ensure that the design meets regulatory and safety requirements.

How to Calculate Maximum Combined Stress on Short Column?

Maximum Combined Stress on Short Column calculator uses Maximum Combined Stress = ((Axial Compressive Load on Column/(Number of Columns*Cross Sectional Area of Column))+((Axial Compressive Load on Column*Eccentricity for Vessel Support)/(Number of Columns*Section Modulus of Vessel Support))) to calculate the Maximum Combined Stress, The Maximum Combined Stress on Short Column formula is defined as the highest stress that occurs at any point in the Short Column, taking into account the effects of all types of loading. Maximum Combined Stress is denoted by f symbol.

How to calculate Maximum Combined Stress on Short Column using this online calculator? To use this online calculator for Maximum Combined Stress on Short Column, enter Axial Compressive Load on Column (PColumn), Number of Columns (NColumn), Cross Sectional Area of Column (AColumn), Eccentricity for Vessel Support (e) & Section Modulus of Vessel Support (Z) and hit the calculate button. Here is how the Maximum Combined Stress on Short Column calculation can be explained with given input values -> 6.9E-6 = ((5580/(4*0.000389))+((5580*0.052)/(4*2.2E-05))).

FAQ

What is Maximum Combined Stress on Short Column?
The Maximum Combined Stress on Short Column formula is defined as the highest stress that occurs at any point in the Short Column, taking into account the effects of all types of loading and is represented as f = ((PColumn/(NColumn*AColumn))+((PColumn*e)/(NColumn*Z))) or Maximum Combined Stress = ((Axial Compressive Load on Column/(Number of Columns*Cross Sectional Area of Column))+((Axial Compressive Load on Column*Eccentricity for Vessel Support)/(Number of Columns*Section Modulus of Vessel Support))). Axial Compressive Load on Column is a type of force that is applied along the axis, or central line, of a structural element such as a column, Number of Columns in a structure refers to the total number of vertical load-bearing members that support the weight of the structure and transfer it to the foundation, Cross sectional area of column is the area of the two-dimensional space that is obtained when the column is cut or sliced perpendicular to its longitudinal axis, Eccentricity for Vessel Support is a non-negative real number that uniquely characterizes its shape & Section Modulus of Vessel Support is a measure of its strength and ability to resist bending stress.
How to calculate Maximum Combined Stress on Short Column?
The Maximum Combined Stress on Short Column formula is defined as the highest stress that occurs at any point in the Short Column, taking into account the effects of all types of loading is calculated using Maximum Combined Stress = ((Axial Compressive Load on Column/(Number of Columns*Cross Sectional Area of Column))+((Axial Compressive Load on Column*Eccentricity for Vessel Support)/(Number of Columns*Section Modulus of Vessel Support))). To calculate Maximum Combined Stress on Short Column, you need Axial Compressive Load on Column (PColumn), Number of Columns (NColumn), Cross Sectional Area of Column (AColumn), Eccentricity for Vessel Support (e) & Section Modulus of Vessel Support (Z). With our tool, you need to enter the respective value for Axial Compressive Load on Column, Number of Columns, Cross Sectional Area of Column, Eccentricity for Vessel Support & Section Modulus of Vessel Support 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 Maximum Combined Stress?
In this formula, Maximum Combined Stress uses Axial Compressive Load on Column, Number of Columns, Cross Sectional Area of Column, Eccentricity for Vessel Support & Section Modulus of Vessel Support. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Maximum Combined Stress = ((Axial Compressive Load on Column/(Number of Columns*Cross Sectional Area of Column))*(1+(1/7500)*(Column Effective Length/Radius of Gyration of Column)^(2))+((Axial Compressive Load on Column*Eccentricity for Vessel Support)/(Number of Columns*Section Modulus of Vessel Support)))
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