LCM of two numbers

Axial Moment at Balanced Condition Calculator

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Short Columns Estimation of Effective Length of Columns

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Design Under Axial Compression with Biaxial Bending Design of Short Column in Compression with Uniaxial Bending Design of Short Column under Axial Compression Slender Columns

✖Axial load at balanced condition is the load when the eccentricity e is equal to permissible eccentricity eb.ⓘ Axial Load at Balanced Condition [N_b]			+10% -10%
✖Maximum Permissible Eccentricity is the maximum permissible amount by which elliptical orbit deviates from a circle.ⓘ Maximum Permissible Eccentricity [e_b]			+10% -10%

✖Moment at Balanced Condition is the moment when the eccentricity e is equal to permissible eccentricity eb.ⓘ Axial Moment at Balanced Condition [M_b]

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Axial Moment at Balanced Condition Solution

STEP 0: Pre-Calculation Summary

Formula Used

Moment at Balanced Condition = Axial Load at Balanced Condition*Maximum Permissible Eccentricity
M_b = N_b*e_b
This formula uses 3 Variables

Variables Used

Moment at Balanced Condition - (Measured in Newton Meter) - Moment at Balanced Condition is the moment when the eccentricity e is equal to permissible eccentricity eb.
Axial Load at Balanced Condition - (Measured in Newton) - Axial load at balanced condition is the load when the eccentricity e is equal to permissible eccentricity eb.
Maximum Permissible Eccentricity - (Measured in Meter) - Maximum Permissible Eccentricity is the maximum permissible amount by which elliptical orbit deviates from a circle.

STEP 1: Convert Input(s) to Base Unit

Axial Load at Balanced Condition: 0.66 Newton --> 0.66 Newton No Conversion Required
Maximum Permissible Eccentricity: 15 Meter --> 15 Meter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

M_b = N_b*e_b --> 0.66*15

Evaluating ... ...

M_b = 9.9

STEP 3: Convert Result to Output's Unit

9.9 Newton Meter --> No Conversion Required

FINAL ANSWER

9.9 Newton Meter <-- Moment at Balanced Condition

(Calculation completed in 00.004 seconds)

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Meerut Institute of Engineering and Technology (MIET), Meerut

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< Design Under Axial Compression with Biaxial Bending Calculators

Maximum Permissible Eccentricity for Tied Columns

LaTeX Go Maximum Permissible Eccentricity = (0.67*Area Ratio of Cross Sectional Area to Gross Area*Force Ratio of Strengths of Reinforcements*Column Diameter+0.17)*Distance from Compression to Tensile Reinforcement

Circle Diameter given Maximum Permissible Eccentricity for Spiral Columns

LaTeX Go Column Diameter = (Maximum Permissible Eccentricity-0.14*Overall Depth of Column)/(0.43*Area Ratio of Cross Sectional Area to Gross Area*Force Ratio of Strengths of Reinforcements)

Column Diameter given Maximum Permissible Eccentricity for Spiral Columns

LaTeX Go Overall Depth of Column = (Maximum Permissible Eccentricity-0.43*Area Ratio of Cross Sectional Area to Gross Area*Force Ratio of Strengths of Reinforcements*Column Diameter)/0.14

Maximum Permissible Eccentricity for Spiral Columns

LaTeX Go Maximum Permissible Eccentricity = 0.43*Area Ratio of Cross Sectional Area to Gross Area*Force Ratio of Strengths of Reinforcements*Column Diameter+0.14*Overall Depth of Column

Axial Moment at Balanced Condition Formula

LaTeX Go

Moment at Balanced Condition = Axial Load at Balanced Condition*Maximum Permissible Eccentricity
M_b = N_b*e_b

What is Axial Moment?

The axial moment is the moment that is applied in the plane perpendicular to the axis of the structure.

How to Calculate Axial Moment at Balanced Condition?

Axial Moment at Balanced Condition calculator uses Moment at Balanced Condition = Axial Load at Balanced Condition*Maximum Permissible Eccentricity to calculate the Moment at Balanced Condition, The Axial Moment at Balanced Condition is defined as the moment of the column when its eccentricity reaches the maximum permissible eccentricity. Moment at Balanced Condition is denoted by M_b symbol.

How to calculate Axial Moment at Balanced Condition using this online calculator? To use this online calculator for Axial Moment at Balanced Condition, enter Axial Load at Balanced Condition (N_b) & Maximum Permissible Eccentricity (e_b) and hit the calculate button. Here is how the Axial Moment at Balanced Condition calculation can be explained with given input values -> 9.9 = 0.66*15.

FAQ

What is Axial Moment at Balanced Condition?

The Axial Moment at Balanced Condition is defined as the moment of the column when its eccentricity reaches the maximum permissible eccentricity and is represented as M_b = N_b*e_b or Moment at Balanced Condition = Axial Load at Balanced Condition*Maximum Permissible Eccentricity. Axial load at balanced condition is the load when the eccentricity e is equal to permissible eccentricity eb & Maximum Permissible Eccentricity is the maximum permissible amount by which elliptical orbit deviates from a circle.

How to calculate Axial Moment at Balanced Condition?

The Axial Moment at Balanced Condition is defined as the moment of the column when its eccentricity reaches the maximum permissible eccentricity is calculated using Moment at Balanced Condition = Axial Load at Balanced Condition*Maximum Permissible Eccentricity. To calculate Axial Moment at Balanced Condition, you need Axial Load at Balanced Condition (N_b) & Maximum Permissible Eccentricity (e_b). With our tool, you need to enter the respective value for Axial Load at Balanced Condition & Maximum Permissible Eccentricity and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

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