Ishan Gupta
Birla Institute of Technology & Science (BITS), Pilani
Ishan Gupta has created this Calculator and 50+ more calculators!

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

Volume of a Conical Frustum
Lateral Surface Area of a Cone
Area of a Rectangle when breadth and diagonal are given
Area of a Rectangle when length and diagonal are given
Area=Length*(sqrt((Diagonal)^2-(Length)^2)) GO
Volume of a Circular Cone
Area of a Trapezoid
Area=((Base A+Base B)/2)*Height GO
Volume of a Circular Cylinder
Volume of a Pyramid
Volume=(1/3)*Side^2*Height GO
Area of a Triangle when base and height are given
Area=1/2*Base*Height GO
Area of a Rectangle when length and breadth are given
Area of a Parallelogram when base and height are given
Area=Base*Height GO

## < 2 Other formulas that calculate the same Output

Sphericity of a cylindrical particle
Sphericity of a particle
Sphericity of Particle=6*(Volume of one Particle/(Surface Area of a Particle*Density of Particle)) GO

### Sphericity of a cuboidal particle Formula

More formulas
Sphericity of a particle GO
Sphericity of a cylindrical particle GO
Number of Particles GO
Total Surface Area of Particles GO
Energy Required to Crush Coarse Materials according to Bond's Law GO
Heat Transfer Through Plane Wall or Surface GO
Critical Radius of Insulation of a Sphere GO
Critical Radius of Insulation of a Cylinder GO
Emmisive power of a body (Radiation) GO
Number of Transfer Units in a Heat Exchanger GO
Log Mean Temperature Difference for CoCurrent Flow GO
Log Mean Temperature Difference for Counter Current Flow GO
Heat Exchanger Effectiveness GO
Heat Transfer in a Heat Exchanger using overall heat transfer coefficient GO
Heat Transfer in a Heat Exchanger using cold fluid properties GO
Heat Transfer in a Heat Exchanger using hot fluid properties GO
Reynolds Number for Circular Tubes GO
Reynolds Number for Non-Circular Tubes GO
Prandtl Number GO
Nusselt Number for Transitional and Rough Flow in Circular Tube GO
Stanton Number (using dimensionless numbers) GO
Stanton Number (using basic fluid properties) GO
Concentration of the reactant in zero-order reaction GO
Concentration of the reactant in first-order reaction GO
Concentration of the reactant in second-order reaction (only one reactant) GO
Partial Pressure (using Raoult's Law) GO
Relative Volatility GO
Thermal Diffusivity GO
Momentum Diffusivity GO
Prandtl Number (using diffusivities) GO
Initial concentration of reactants in the feed GO
Molar Feed Rate of Reactants GO
Volumetric flow rate of feed GO
Space time of the reactor GO
Space velocity of a reactor GO
Conversion of Reactant A (batch) GO
Molar flow rate at which reactant A leaves the system GO
Conversion of Reactant A (flow) GO
Batch Reactor: Number of Moles Remaining (of reactant A) GO
Height of capillary rise/fall GO
Hydrostatic Force on Plane Submerged Surface GO
Hydrostatic Force on Curved Submerged Surface GO
Head Loss due to friction GO
Fanning friction factor GO
Radial Heat flowing through a cylinder GO

## Sphericity of a cuboidal particle

Sphericity of a cuboidal particle gives an estimate of how closely their shape resembles a sphere.

## How to Calculate Sphericity of a cuboidal particle?

Sphericity of a cuboidal particle calculator uses Sphericity of Particle=((((Length*Breadth*Height)*(0.75/pi))^(1/3)^2)*4*pi)/(2*(Length*Breadth+Breadth*Height+Height*Length)) to calculate the Sphericity of Particle, Sphericity of a cuboidal particle gives an estimate of how closely their shape resembles a sphere. Its value lies between 0 and 1. Sphericity of Particle and is denoted by Φp symbol.

How to calculate Sphericity of a cuboidal particle using this online calculator? To use this online calculator for Sphericity of a cuboidal particle, enter Height (h), Length (l) and Breadth (b) and hit the calculate button. Here is how the Sphericity of a cuboidal particle calculation can be explained with given input values -> 0.130583 = ((((3*2*12)*(0.75/pi))^(1/3)^2)*4*pi)/(2*(3*2+2*12+12*3)).

### FAQ

What is Sphericity of a cuboidal particle?
Sphericity of a cuboidal particle gives an estimate of how closely their shape resembles a sphere. Its value lies between 0 and 1 and is represented as Φp=((((l*b*h)*(0.75/pi))^(1/3)^2)*4*pi)/(2*(l*b+b*h+h*l)) or Sphericity of Particle=((((Length*Breadth*Height)*(0.75/pi))^(1/3)^2)*4*pi)/(2*(Length*Breadth+Breadth*Height+Height*Length)). Height is the distance between the lowest and highest points of a person standing upright, Length is the measurement or extent of something from end to end and Breadth is the measurement or extent of something from side to side.
How to calculate Sphericity of a cuboidal particle?
Sphericity of a cuboidal particle gives an estimate of how closely their shape resembles a sphere. Its value lies between 0 and 1 is calculated using Sphericity of Particle=((((Length*Breadth*Height)*(0.75/pi))^(1/3)^2)*4*pi)/(2*(Length*Breadth+Breadth*Height+Height*Length)). To calculate Sphericity of a cuboidal particle, you need Height (h), Length (l) and Breadth (b). With our tool, you need to enter the respective value for Height, Length and Breadth 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 Sphericity of Particle?
In this formula, Sphericity of Particle uses Height, Length and Breadth. We can use 2 other way(s) to calculate the same, which is/are as follows -
• Sphericity of Particle=6*(Volume of one Particle/(Surface Area of a Particle*Density of Particle))