Applied Pressure in Terms of Coefficient of Flowability for Solids Solution

STEP 0: Pre-Calculation Summary
Formula Used
Applied Pressure = Normal Pressure/Coefficient of Flowability
PA = PN/K
This formula uses 3 Variables
Variables Used
Applied Pressure - (Measured in Pascal) - Applied Pressure is the pressure that is applied on the object of interest.
Normal Pressure - (Measured in Pascal) - Normal Pressure is the pressure that is normal on the surface of object of interest .
Coefficient of Flowability - Coefficient of Flowability of a device is a relative measure of its efficiency at allowing fluid flow.
STEP 1: Convert Input(s) to Base Unit
Normal Pressure: 15 Pascal --> 15 Pascal No Conversion Required
Coefficient of Flowability: 1.667 --> No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
PA = PN/K --> 15/1.667
Evaluating ... ...
PA = 8.99820035992801
STEP 3: Convert Result to Output's Unit
8.99820035992801 Pascal --> No Conversion Required
FINAL ANSWER
8.99820035992801 โ‰ˆ 8.9982 Pascal <-- Applied Pressure
(Calculation completed in 00.004 seconds)

Credits

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NIT Srinagar (NIT SRI), Srinagar, Kashmir
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3 Storage and Transportation Of Solids Calculators

Material Characteristic using Angle of Friction
Go Material Characteristic = (1-sin(Angle of Friction))/(1+sin(Angle of Friction))
Applied Pressure in Terms of Coefficient of Flowability for Solids
Go Applied Pressure = Normal Pressure/Coefficient of Flowability
Coefficient of Flowability of Solids
Go Coefficient of Flowability = Normal Pressure/Applied Pressure

21 Basic Formulas of Mechanical Operations Calculators

Sphericity of Cuboidal Particle
Go Sphericity of Cuboidal Particle = ((((Length*Breadth*Height)*(0.75/pi))^(1/3)^2)*4*pi)/(2*(Length*Breadth+Breadth*Height+Height*Length))
Sphericity of Cylindrical Particle
Go Sphericity of Cylindrical Particle = (((((Cylinder Radius)^2*Cylinder Height*3/4)^(1/3))^2)*4*pi)/(2*pi*Cylinder Radius*(Cylinder Radius+Cylinder Height))
Pressure Gradient using Kozeny Carman Equation
Go Pressure Gradient = (150*Dynamic Viscosity*(1-Porosity)^2*Velocity)/((Sphericity of Particle)^2*(Equivalent Diameter)^2*(Porosity)^3)
Projected Area of Solid Body
Go Projected Area of Solid Particle Body = 2*(Drag Force)/(Drag Coefficient*Density of Liquid*(Velocity of Liquid)^(2))
Total Surface Area of Particle using Spericity
Go Total Surface Area of Particles = Mass*6/(Sphericity of Particle*Density Of Particle*Arithmetic Mean Diameter)
Terminal Settling Velocity of Single Particle
Go Terminal Velocity of Single Particle = Settling Velocity of Group of Particles/(Void fraction)^Richardsonb Zaki Index
Material Characteristic using Angle of Friction
Go Material Characteristic = (1-sin(Angle of Friction))/(1+sin(Angle of Friction))
Sphericity of Particle
Go Sphericity of Particle = (6*Volume of One Spherical Particle)/(Surface Area of Particle*Equivalent Diameter)
Total Number of Particles in Mixture
Go Total Number of Particles in Mixture = Total Mass of Mixture/(Density Of Particle* Volume Of One Particle)
Energy Required to Crush Coarse Materials according to Bond's Law
Go Energy per Unit Mass of Feed = Work Index*((100/Product Diameter)^0.5-(100/Feed Diameter)^0.5)
Number of Particles
Go Number of Particles = Mixture Mass/(Density of One Particle*Volume of Spherical Particle)
Fraction of Cycle Time used for Cake Formation
Go Fraction of Cycle Time Used For Cake Formation = Time Required For Cake Formation/Total Cycle Time
Time Required for Cake Formation
Go Time Required For Cake Formation = Fraction of Cycle Time Used For Cake Formation*Total Cycle Time
Specific Surface Area of Mixture
Go Specific Surface Area of Mixture = Total Surface Area/Total Mass of Mixture
Mass Mean Diameter
Go Mass Mean Diameter = (Mass Fraction*Size Of Particles Present In Fraction)
Sauter Mean Diameter
Go Sauter Mean Diameter = (6*Volume of Particle)/(Surface Area of Particle)
Porosity or Void Fraction
Go Porosity or Void Fraction = Volume of Voids in Bed/Total Volume of Bed
Total Surface Area of Particles
Go Surface Area = Surface Area of One Particle*Number of Particles
Applied Pressure in Terms of Coefficient of Flowability for Solids
Go Applied Pressure = Normal Pressure/Coefficient of Flowability
Coefficient of Flowability of Solids
Go Coefficient of Flowability = Normal Pressure/Applied Pressure
Surface Shape Factor
Go Surface Shape Factor = 1/Sphericity of Particle

Applied Pressure in Terms of Coefficient of Flowability for Solids Formula

Applied Pressure = Normal Pressure/Coefficient of Flowability
PA = PN/K

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How to Calculate Applied Pressure in Terms of Coefficient of Flowability for Solids?

Applied Pressure in Terms of Coefficient of Flowability for Solids calculator uses Applied Pressure = Normal Pressure/Coefficient of Flowability to calculate the Applied Pressure, The Applied Pressure in Terms of Coefficient of Flowability for Solids is a relation between Applied Pressure and Coefficient of Flowability based on the principle that ratio of normal pressure and applied pressure remains constant. Applied Pressure is denoted by PA symbol.

How to calculate Applied Pressure in Terms of Coefficient of Flowability for Solids using this online calculator? To use this online calculator for Applied Pressure in Terms of Coefficient of Flowability for Solids, enter Normal Pressure (PN) & Coefficient of Flowability (K) and hit the calculate button. Here is how the Applied Pressure in Terms of Coefficient of Flowability for Solids calculation can be explained with given input values -> 8.9982 = 15/1.667.

FAQ

What is Applied Pressure in Terms of Coefficient of Flowability for Solids?
The Applied Pressure in Terms of Coefficient of Flowability for Solids is a relation between Applied Pressure and Coefficient of Flowability based on the principle that ratio of normal pressure and applied pressure remains constant and is represented as PA = PN/K or Applied Pressure = Normal Pressure/Coefficient of Flowability. Normal Pressure is the pressure that is normal on the surface of object of interest & Coefficient of Flowability of a device is a relative measure of its efficiency at allowing fluid flow.
How to calculate Applied Pressure in Terms of Coefficient of Flowability for Solids?
The Applied Pressure in Terms of Coefficient of Flowability for Solids is a relation between Applied Pressure and Coefficient of Flowability based on the principle that ratio of normal pressure and applied pressure remains constant is calculated using Applied Pressure = Normal Pressure/Coefficient of Flowability. To calculate Applied Pressure in Terms of Coefficient of Flowability for Solids, you need Normal Pressure (PN) & Coefficient of Flowability (K). With our tool, you need to enter the respective value for Normal Pressure & Coefficient of Flowability 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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