Moment Resistance of Concrete when Compressive Stress is Given Calculator

Category	Engineering ↺
Engineering	Civil ↺
Civil	Concrete ↺
Concrete	Working Stress Design of Tension Reinforced Rectangular Beams ↺
Working-Stress-Design-Of-Tension-Reinforced-Rectangular-Beams	Allowable Bending Moment ↺

✖Compressive Stress in Extreme Surface of Concrete assuming, fcⓘ Compressive Stress in Extreme Surface of Concrete [f_c]			+10% -10%
✖Ratio of depth is the ratio of depth of compression area to the effective depth of a section.ⓘ Ratio of depth [k]			+10% -10%
✖Ratio of Distance between centroids of Compression and Tension to depth dⓘ Ratio of Distance between centroids [j]			+10% -10%
✖Beam Width is defined as the shortest/least measurement of the beam.ⓘ Beam Width [b]			+10% -10%
✖Effective depth of beam is described as distance from the centroid of tension Steel to theoutermost face of compression fibre.ⓘ Effective depth of beam [d]			+10% -10%

✖Moment Resistance of Concrete is the couple produced by the internal forces in a sectional member subjected to bending under the maximum permissible stress.ⓘ Moment Resistance of Concrete when Compressive Stress is Given [M_c]

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Mithila Muthamma PA

Coorg Institute of Technology (CIT), Coorg

Mithila Muthamma PA has created this Calculator and 400+ more calculators!

Himanshi Sharma

Bhilai Institute of Technology (BIT), Raipur

Himanshi Sharma has verified this Calculator and 500+ more calculators!

< 11 Other formulas that you can solve using the same Inputs

Moment of Inertia of Transformed Beam Section

Moment of Inertia Transformed Beam=(0.5*Beam Width*(Distance Neutral to face of Concrete ^2))+2*(Elasticity Ratio of Steel to Concrete-1)*Area of Compressive Reinforcement*(Distance Neutral to Compressive Reinforcing Steel^2)+Elasticity Ratio of Steel to Concrete*(Distance Neutral to Tensile Reinforcing Steel^2)*Tensile Reinforcement Area GO

Tensile Reinforcing Bars Perimeters Sum when Bond Stress on Bar Surface is Given

Sum of perimeters=Total Shear/(Ratio j*Effective depth of beam*Bond stress on surface of bar) GO

Total Shear when Bond Stress on Bar Surface is Given

Total Shear=Bond stress on surface of bar*(Ratio j*Effective depth of beam*Sum of perimeters) GO

Bond Stress on Bar Surface

Bond stress on surface of bar=Total Shear/(Ratio j*Effective depth of beam*Sum of perimeters) GO

Depth of Beam when Stress in Concrete is Given

Depth of the Beam=sqrt(2*Bending moment/(Ratio k*Ratio j*Beam Width*Stress)) GO

Bending Moment when Stress in Concrete is Given

Bending moment=(Stress*Ratio k*Ratio j*Beam Width*Depth of the Beam^2)/2 GO

Stress in Concrete

Stress=2*Bending moment/(Ratio k*Ratio j*Beam Width*Depth of the Beam^2) GO

Stress in Steel When Cross-Sectional Reinforcing Tensile Area to Beam Area Ratio is Given

Stress=Bending moment/(Ratio p*Ratio j*Beam Width*Depth of the Beam^2) GO

Effective Depth of Beam when Shearing Unit Stress in a Reinforced Concrete Beam is Given

Depth of the Beam=Total Shear/(Beam Width*Shearing Unit Stress) GO

Shearing Unit Stress in a Reinforced Concrete Beam

Shearing Unit Stress=Total Shear/(Beam Width*Depth of the Beam) GO

Total Shear when Shearing Unit Stress in a Reinforced Concrete Beam is Given

Total Shear=Shearing Unit Stress*Beam Width*Depth of the Beam GO

< 6 Other formulas that calculate the same Output

Moment Resistance of Concrete when Stress in Concrete is Given

Moment Resistance of Concrete=((stress in concrete*Beam Width*Flange Thickness*Ratio of Distance between centroids *Effective depth of beam)/(2*Ratio of Depth of Compression Area to Depth d*Effective depth of beam))*(2*Ratio of Depth of Compression Area to Depth d*Effective depth of beam-Flange Thickness) GO

Moment Resisting Capacity of Concrete

Moment Resistance of Concrete=(( stress in extreme compression surface*value of k*width of beam*distance to centroid of tensile steel)/2)*(distance to centroid of tensile steel-(value of k*distance to centroid of tensile steel)/3) GO

Moment Resistance of Concrete when Flange Thickness is Given

Moment Resistance of Concrete=1/2*28 Day Compressive Strength of Concrete*Beam Width*Flange Thickness*(Effective depth of beam-(Flange Thickness/2)) GO

Moment Resistance of Concrete when Compressive Force is Given

Moment Resistance of Concrete=Total Compression on Steel*Ratio of Distance between centroids *Effective depth of beam GO

Moment Resistance of Concrete when Kc is Given

Moment Resistance of Concrete=Modification Factor *Beam Width*(Effective depth of beam)^2 GO

Moment Resisting Capacity of Concrete when Bending Moment is Given

Moment Resistance of Concrete=Bending moment-moment resistance compressive steel GO

Moment Resistance of Concrete when Compressive Stress is Given Formula

Moment Resistance of Concrete=(1/2)*Compressive Stress in Extreme Surface of Concrete*Ratio of depth*Ratio of Distance between centroids *Beam Width*(Effective depth of beam)^2
M<sub>c</sub>=(1/2)*f<sub>c</sub>*k*j*b*(d)^2

More formulas

Moment Resistance of Concrete when Kc is Given GO

Moment Resistance of Steel when Stress and Area are Given GO

Moment Resistance of Steel when Steel Ratio is Given GO

Moment Resistance of Steel when Ks is Given GO

What is Compressive Stress?

Compressive Stress results from the shortening in one dimension of an elastic body due to oppositely directed collinear forces tending to crush it.

How to Calculate Moment Resistance of Concrete when Compressive Stress is Given?

Moment Resistance of Concrete when Compressive Stress is Given calculator uses Moment Resistance of Concrete=(1/2)*Compressive Stress in Extreme Surface of Concrete*Ratio of depth*Ratio of Distance between centroids *Beam Width*(Effective depth of beam)^2 to calculate the Moment Resistance of Concrete, The Moment Resistance of Concrete when Compressive Stress is Given formula is defined as the allowable bending moment of resistance of the concrete, inkip (kNm) . Moment Resistance of Concrete and is denoted by M_c symbol.

How to calculate Moment Resistance of Concrete when Compressive Stress is Given using this online calculator? To use this online calculator for Moment Resistance of Concrete when Compressive Stress is Given, enter Compressive Stress in Extreme Surface of Concrete (f_c), Ratio of depth (k), Ratio of Distance between centroids (j), Beam Width (b) and Effective depth of beam (d) and hit the calculate button. Here is how the Moment Resistance of Concrete when Compressive Stress is Given calculation can be explained with given input values -> 2.400E+6 = (1/2)*60000000*50*10*0.01*(4)^2.

FAQ

What is Moment Resistance of Concrete when Compressive Stress is Given?

The Moment Resistance of Concrete when Compressive Stress is Given formula is defined as the allowable bending moment of resistance of the concrete, inkip (kNm) and is represented as M_c=(1/2)*f_c*k*j*b*(d)^2 or Moment Resistance of Concrete=(1/2)*Compressive Stress in Extreme Surface of Concrete*Ratio of depth*Ratio of Distance between centroids *Beam Width*(Effective depth of beam)^2. Compressive Stress in Extreme Surface of Concrete assuming, fc, Ratio of depth is the ratio of depth of compression area to the effective depth of a section, Ratio of Distance between centroids of Compression and Tension to depth d, Beam Width is defined as the shortest/least measurement of the beam and Effective depth of beam is described as distance from the centroid of tension Steel to theoutermost face of compression fibre.

How to calculate Moment Resistance of Concrete when Compressive Stress is Given?

The Moment Resistance of Concrete when Compressive Stress is Given formula is defined as the allowable bending moment of resistance of the concrete, inkip (kNm) is calculated using Moment Resistance of Concrete=(1/2)*Compressive Stress in Extreme Surface of Concrete*Ratio of depth*Ratio of Distance between centroids *Beam Width*(Effective depth of beam)^2. To calculate Moment Resistance of Concrete when Compressive Stress is Given, you need Compressive Stress in Extreme Surface of Concrete (f_c), Ratio of depth (k), Ratio of Distance between centroids (j), Beam Width (b) and Effective depth of beam (d). With our tool, you need to enter the respective value for Compressive Stress in Extreme Surface of Concrete, Ratio of depth, Ratio of Distance between centroids , Beam Width and Effective depth of beam 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 Moment Resistance of Concrete?

In this formula, Moment Resistance of Concrete uses Compressive Stress in Extreme Surface of Concrete, Ratio of depth, Ratio of Distance between centroids , Beam Width and Effective depth of beam. We can use 6 other way(s) to calculate the same, which is/are as follows -

Moment Resistance of Concrete=Modification Factor *Beam Width*(Effective depth of beam)^2
Moment Resistance of Concrete=(( stress in extreme compression surface*value of k*width of beam*distance to centroid of tensile steel)/2)*(distance to centroid of tensile steel-(value of k*distance to centroid of tensile steel)/3)
Moment Resistance of Concrete=Bending moment-moment resistance compressive steel
Moment Resistance of Concrete=Total Compression on Steel*Ratio of Distance between centroids *Effective depth of beam
Moment Resistance of Concrete=((stress in concrete*Beam Width*Flange Thickness*Ratio of Distance between centroids *Effective depth of beam)/(2*Ratio of Depth of Compression Area to Depth d*Effective depth of beam))*(2*Ratio of Depth of Compression Area to Depth d*Effective depth of beam-Flange Thickness)
Moment Resistance of Concrete=1/2*28 Day Compressive Strength of Concrete*Beam Width*Flange Thickness*(Effective depth of beam-(Flange Thickness/2))

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