Kethavath Srinath
Osmania University (OU), Hyderabad
Kethavath Srinath has created this Calculator and 400+ more calculators!
Alithea Fernandes
Don Bosco College of Engineering (DBCE), Goa
Alithea Fernandes has verified this Calculator and 100+ more calculators!

11 Other formulas that you can solve using the same Inputs

Ultimate Strength for Symmetrical Reinforcement
Axial Load Capacity=0.85*28 Day Compressive Strength of Concrete*Width of compression face*Distance from Compression to Tensile Reinforcement*Capacity reduction factor*((-Area ratio of tensile reinforcement)+1-(Eccentricity by method of frame analysis/Distance from Compression to Tensile Reinforcement)+sqrt(((1-(Eccentricity by method of frame analysis/Distance from Compression to Tensile Reinforcement))^2)+2*Area ratio of tensile reinforcement*((Force ratio of strengths of reinforcements-1)*(1-(Distance from Compression to Centroid Reinforcment/Distance from Compression to Tensile Reinforcement))+(Eccentricity by method of frame analysis/Distance from Compression to Tensile Reinforcement)))) GO
Ultimate Strength for No Compression Reinforcement
Axial Load Capacity=0.85*28 Day Compressive Strength of Concrete*Width of compression face*Distance from Compression to Tensile Reinforcement*Capacity reduction factor*((-Area ratio of tensile reinforcement*Force ratio of strengths of reinforcements)+1-(Eccentricity by method of frame analysis/Distance from Compression to Tensile Reinforcement)+sqrt(((1-(Eccentricity by method of frame analysis/Distance from Compression to Tensile Reinforcement))^2)+2*(Area ratio of tensile reinforcement*Eccentricity by method of frame analysis*Force ratio of strengths of reinforcements/Distance from Compression to Tensile Reinforcement))) GO
Balanced Moment when Φ is Given
Balanced Moment=Resistance Factor*((.85*28 Day Compressive Strength of Concrete*Width of compression face*Depth Rectangular Compressive Stress*(Distance from Compression to Tensile Reinforcement-Distance from Plastic to Tensile Reinforcement-Depth Rectangular Compressive Stress/2))+(Area of Compressive Reinforcement*Yeild Strength of Base Plate*(Distance from Compression to Tensile Reinforcement-Distance from Compression to Centroid Reinforcment-Distance from Plastic to Tensile Reinforcement))+(area of tension reinforcement*Tensile Stress in Steel*Distance from Plastic to Tensile Reinforcement)) GO
Ultimate Strength for Symmetrical Reinforcement in Single Layers
Axial Load Capacity=Capacity reduction factor*((Area of Compressive Reinforcement*Yield strength of reinforcing steel/((Eccentricity/Distance from Compression to Tensile Reinforcement)-Distance from Compression to Centroid Reinforcment+0.5))+(Width of compression face*Depth of column*28 Day Compressive Strength of Concrete/((3*Depth of column*Eccentricity/(Distance from Compression to Tensile Reinforcement^2))+1.18))) GO
Compressive Reinforcement Area when Axial-Load Capacity of Short Rectangular Members is Given
Area of Compressive Reinforcement=((Axial Load Capacity/Resistance Factor)-(.85*28 Day Compressive Strength of Concrete*Width of compression face*Depth Rectangular Compressive Stress)+(area of tension reinforcement*Tensile Stress in Steel))/Yeild Strength of Base Plate GO
Tension Reinforcement Area when Axial-Load Capacity of Short Rectangular Members is Given
area of tension reinforcement=((.85*28 Day Compressive Strength of Concrete*Width of compression face*Depth Rectangular Compressive Stress)+(Area of Compressive Reinforcement*Yeild Strength of Base Plate)-(Axial Load Capacity/Resistance Factor))/Tensile Stress in Steel GO
Tensile Stress in Steel when Axial-Load Capacity of Short Rectangular Members is Given
Tensile Stress in Steel=((.85*28 Day Compressive Strength of Concrete*Width of compression face*Depth Rectangular Compressive Stress)+(Area of Compressive Reinforcement*Yeild Strength of Base Plate)-(Axial Load Capacity/Resistance Factor))/area of tension reinforcement GO
Axial-Load Capacity of Short Rectangular Members
Axial Load Capacity=Resistance Factor*((.85*28 Day Compressive Strength of Concrete*Width of compression face*Depth Rectangular Compressive Stress)+(Area of Compressive Reinforcement*Yeild Strength of Base Plate)-(area of tension reinforcement*Tensile Stress in Steel)) GO
Yield Strength of Reinforcing Steel when Column Ultimate Strength is Given
Yield Strength=(Ultimate strength-0.85*28 Day Compressive Strength of Concrete*(Gross area-Area of Reinforcement))/Area of Reinforcement GO
Column Ultimate Strength with Zero Eccentricity of Load
Ultimate strength=0.85*28 Day Compressive Strength of Concrete*(Gross area-Area of Reinforcement)+Yield Strength*Area of Reinforcement GO
Allowable Bearing Pressure when Full Area of Support is Occupied by Base Plate
Allowable Bearing Pressure=0.35*28 Day Compressive Strength of Concrete GO

2 Other formulas that calculate the same Output

Modulus of Elasticity of Concrete in SI Units
Modulus of Elasticity Concrete=0.043*sqrt(28 Day Compressive Strength of Concrete) GO
Concrete Column Elasticity Modulus when Flexural Stiffness is Given
Modulus of Elasticity Concrete=flexural stiffness of column/Moment of inertia GO

Modulus of Elasticity of Normal Weight and Density Concrete in SI Units Formula

Modulus of Elasticity Concrete=4700*sqrt(28 Day Compressive Strength of Concrete)
E<sub>c=4700*sqrt(f<sub>c)
More formulas
Modulus of Elasticity of Concrete in USCS Units GO
Modulus of Elasticity of Concrete in SI Units GO
Modulus of Elasticity of Normal Weight and Density Concrete in USCS Units GO
Youngs modulus of concrete GO

Define Modulus of Elasticity of Concrete?

Modulus of elasticity of concrete(Ec) is defined as the ratio of the applied stress to the corresponding strain. In other words, it reflects the ability of concrete to deflect elastically. Modulus of elasticity of concrete is sensitive to aggregate and mixture proportions of concrete.

How to Calculate Modulus of Elasticity of Normal Weight and Density Concrete in SI Units?

Modulus of Elasticity of Normal Weight and Density Concrete in SI Units calculator uses Modulus of Elasticity Concrete=4700*sqrt(28 Day Compressive Strength of Concrete) to calculate the Modulus of Elasticity Concrete, The Modulus of Elasticity of Normal Weight and Density Concrete in SI Units formula is defined as the ratio of the applied stress to the corresponding strain. Modulus of Elasticity Concrete and is denoted by Ec symbol.

How to calculate Modulus of Elasticity of Normal Weight and Density Concrete in SI Units using this online calculator? To use this online calculator for Modulus of Elasticity of Normal Weight and Density Concrete in SI Units, enter 28 Day Compressive Strength of Concrete (fc) and hit the calculate button. Here is how the Modulus of Elasticity of Normal Weight and Density Concrete in SI Units calculation can be explained with given input values -> 47 = 4700*sqrt(100000000).

FAQ

What is Modulus of Elasticity of Normal Weight and Density Concrete in SI Units?
The Modulus of Elasticity of Normal Weight and Density Concrete in SI Units formula is defined as the ratio of the applied stress to the corresponding strain and is represented as Ec=4700*sqrt(fc) or Modulus of Elasticity Concrete=4700*sqrt(28 Day Compressive Strength of Concrete). 28 Day Compressive Strength of Concrete is defined as the strength of the concrete after 28 days of using it.
How to calculate Modulus of Elasticity of Normal Weight and Density Concrete in SI Units?
The Modulus of Elasticity of Normal Weight and Density Concrete in SI Units formula is defined as the ratio of the applied stress to the corresponding strain is calculated using Modulus of Elasticity Concrete=4700*sqrt(28 Day Compressive Strength of Concrete). To calculate Modulus of Elasticity of Normal Weight and Density Concrete in SI Units, you need 28 Day Compressive Strength of Concrete (fc). With our tool, you need to enter the respective value for 28 Day Compressive Strength of Concrete 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 Modulus of Elasticity Concrete?
In this formula, Modulus of Elasticity Concrete uses 28 Day Compressive Strength of Concrete. We can use 2 other way(s) to calculate the same, which is/are as follows -
  • Modulus of Elasticity Concrete=0.043*sqrt(28 Day Compressive Strength of Concrete)
  • Modulus of Elasticity Concrete=flexural stiffness of column/Moment of inertia
Share Image
Let Others Know
Facebook
Twitter
Reddit
LinkedIn
Email
WhatsApp
Copied!