Suspension Density given Solid Density and Volumetric Holdup Calculator

✖Solid Density refers to the density of the solid crystals that are produced in a crystallization process.ⓘ Solid Density [ρ_C]			+10% -10%
✖Volumetric Holdup represents the proportion of space within the crystallization system that is filled with crystals and the surrounding liquid phase.ⓘ Volumetric Holdup [φ_T]			+10% -10%

✖Suspension density refers to the concentration or density of crystals that are suspended within a liquid during the crystallization process.ⓘ Suspension Density given Solid Density and Volumetric Holdup [m_T]

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Formula

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Suspension Density given Solid Density and Volumetric Holdup

Formula

`"m"_{"T"} = "ρ"_{"C"}*"φ"_{"T"}`

Example

`"0.59904kg/m³"="1.872kg/m³"*"0.32"`

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Suspension Density given Solid Density and Volumetric Holdup Solution

STEP 0: Pre-Calculation Summary

Formula Used

Suspension Density = Solid Density*Volumetric Holdup
m_T = ρ_C*φ_T
This formula uses 3 Variables

Variables Used

Suspension Density - (Measured in Kilogram per Cubic Meter) - Suspension density refers to the concentration or density of crystals that are suspended within a liquid during the crystallization process.
Solid Density - (Measured in Kilogram per Cubic Meter) - Solid Density refers to the density of the solid crystals that are produced in a crystallization process.
Volumetric Holdup - Volumetric Holdup represents the proportion of space within the crystallization system that is filled with crystals and the surrounding liquid phase.

STEP 1: Convert Input(s) to Base Unit

Solid Density: 1.872 Kilogram per Cubic Meter --> 1.872 Kilogram per Cubic Meter No Conversion Required
Volumetric Holdup: 0.32 --> No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

m_T = ρ_C*φ_T --> 1.872*0.32

Evaluating ... ...

m_T = 0.59904

STEP 3: Convert Result to Output's Unit

0.59904 Kilogram per Cubic Meter --> No Conversion Required

FINAL ANSWER

0.59904 Kilogram per Cubic Meter <-- Suspension Density

(Calculation completed in 00.004 seconds)

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Created by Rishi Vadodaria

Malviya National Institute Of Technology (MNIT JAIPUR ), JAIPUR

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Verified by Vaibhav Mishra

DJ Sanghvi College of Engineering (DJSCE), Mumbai

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< 24 Crystallization Calculators

Supersaturation based on activities of Species A and B

Go Supersaturation Ratio = ((Activity of Specie A^Stochiometric Value for A)*((Activity of Specie B^Stochiometric Value for B))/Solubility Product for Activity)^(1/(Stochiometric Value for A+Stochiometric Value for B))

Supersaturation based on Concentration of Species A and B along with Solubility Product

Go Supersaturation Ratio = ((Concentration of Specie A^Stochiometric Value for A)*((Concentration of specie B^Stochiometric Value for B))/Solubility Product)^(1/(Stochiometric Value for A+Stochiometric Value for B))

Solubility Product given Activity Coefficient and Mole Fraction of Species A and B

Go Solubility Product for Activity = ((Activity Coefficient of A*Mole Fraction A)^Stochiometric Value for A)*((Activity Coefficient of B*Mole Fraction B)^Stochiometric Value for B)

Overall Excess Free Energy for Spherical Crystalline Body

Go Overall Excess Energy = 4*pi*(Crystal Radius^2)*Interfacial Tension+(4*pi/3)*(Crystal Radius^3)*Free Energy Change Per Volume

Reaction Rate Constant in Crystallization given Mass Flux Density and Order of Reaction

Go Reaction Rate Constant = Mass Density of Crystal Surface/((Interfacial Concentration-Equilibrium Saturation Value)^Order of Integration Reaction)

Mass Flux Density given Reaction Rate Constant and Order of Integration Reaction

Go Mass Density of Crystal Surface = Reaction Rate Constant*(Interfacial Concentration-Equilibrium Saturation Value)^Order of Integration Reaction

Solubility Product given Activities of Species A and B

Go Solubility Product for Activity = (Activity of Specie A^Stochiometric Value for A)*(Activity of Specie B^Stochiometric Value for B)

Solubility Product given Concentration of Species A and B

Go Solubility Product = ((Concentration of Specie A)^Stochiometric Value for A)*(Concentration of specie B)^Stochiometric Value for B

Mass Flux Density given Mass Transfer Coefficient and Concentration Gradient

Go Mass Density of Crystal Surface = Mass Transfer Coefficient*(Bulk Solution Concentration-Interface Concentration)

Mass Transfer Coefficient given Mass Flux Density and Concentration Gradient

Go Mass Transfer Coefficient = Mass Density of Crystal Surface/(Bulk Solution Concentration-Interface Concentration)

Nucleation Rate for given Number of Particles and Volume of Constant Supersaturation

Go Nucleation Rate = Number of Particles/(Supersaturation Volume*Supersaturation Time)

Number of Particles given Nucleation Rate and Supersaturation Volume and Time

Go Number of Particles = Nucleation Rate*(Supersaturation Volume*Supersaturation Time)

Supersaturation Volume given Nucleation Rate and Supersaturation Time

Go Supersaturation Volume = Number of Particles/(Nucleation Rate*Supersaturation Time)

Supersaturation Time given Nucleation Rate and Supersaturation Volume

Go Supersaturation Time = Number of Particles/(Nucleation Rate*Supersaturation Volume)

Supersaturation Ratio given Partial Pressure for Ideal Gas Condition

Go Supersaturation Ratio = Partial Pressure at Solution Concentration/Partial Pressure at Saturation Concentration

Kinetic Driving Force in Crystallization given Chemical Potential of Fluid and Crystal

Go Kinetic Driving Force = Chemical Potential of Fluid-Chemical Potential of Crystal

Relative Supersaturation given Degree of Saturation and Equilibrium Saturation Value

Go Relative Supersaturation = Degree of Supersaturation/Equilibrium Saturation Value

Equilibrium Saturation Value given Relative Supersaturation and Degree of Saturation

Go Equilibrium Saturation Value = Degree of Supersaturation/Relative Supersaturation

Degree of Supersaturation given Solution Concentration and Equilibrium Saturation Value

Go Degree of Supersaturation = Solution Concentration-Equilibrium Saturation Value

Solution Concentration given Degree of Supersaturation and Equilibrium Saturation Value

Go Solution Concentration = Degree of Supersaturation+Equilibrium Saturation Value

Equilibrium Saturation Value given Solution Concentration and Degree of Saturation

Go Equilibrium Saturation Value = Solution Concentration-Degree of Supersaturation

Supersaturation Ratio given Solution Concentration and Equilibrium Saturation Value

Go Supersaturation Ratio = Solution Concentration/Equilibrium Saturation Value

Suspension Density given Solid Density and Volumetric Holdup

Go Suspension Density = Solid Density*Volumetric Holdup

Relative Supersaturation for given Supersaturation Ratio

Go Relative Supersaturation = Supersaturation Ratio-1

Suspension Density given Solid Density and Volumetric Holdup Formula

Suspension Density = Solid Density*Volumetric Holdup
m_T = ρ_C*φ_T

What is Volumetric Holdup?

Volumetric holdup, in the context of crystallization, refers to the fraction or volume of a crystallization vessel or equipment that is occupied by the suspension or mixture of solid crystals and liquid. It represents the proportion of space within the crystallization system that is filled with crystals and the surrounding liquid phase.

What is Suspension Density?

In a crystallization process, a solution containing dissolved solute is cooled or otherwise manipulated to induce the formation of crystals. As the crystals form, they separate from the liquid phase and become suspended within the solution. The density of these suspended crystals relative to the liquid phase is the suspension density.

How to Calculate Suspension Density given Solid Density and Volumetric Holdup?

Suspension Density given Solid Density and Volumetric Holdup calculator uses Suspension Density = Solid Density*Volumetric Holdup to calculate the Suspension Density, The Suspension Density given Solid Density and Volumetric Holdup formula is defined as the concentration or density of solid particles (crystals) that are suspended within a liquid during the crystallization process. Suspension Density is denoted by m_T symbol.

How to calculate Suspension Density given Solid Density and Volumetric Holdup using this online calculator? To use this online calculator for Suspension Density given Solid Density and Volumetric Holdup, enter Solid Density (ρ_C) & Volumetric Holdup (φ_T) and hit the calculate button. Here is how the Suspension Density given Solid Density and Volumetric Holdup calculation can be explained with given input values -> 0.59904 = 1.872*0.32.

FAQ

What is Suspension Density given Solid Density and Volumetric Holdup?

The Suspension Density given Solid Density and Volumetric Holdup formula is defined as the concentration or density of solid particles (crystals) that are suspended within a liquid during the crystallization process and is represented as m_T = ρ_C*φ_T or Suspension Density = Solid Density*Volumetric Holdup. Solid Density refers to the density of the solid crystals that are produced in a crystallization process & Volumetric Holdup represents the proportion of space within the crystallization system that is filled with crystals and the surrounding liquid phase.

How to calculate Suspension Density given Solid Density and Volumetric Holdup?

The Suspension Density given Solid Density and Volumetric Holdup formula is defined as the concentration or density of solid particles (crystals) that are suspended within a liquid during the crystallization process is calculated using Suspension Density = Solid Density*Volumetric Holdup. To calculate Suspension Density given Solid Density and Volumetric Holdup, you need Solid Density (ρ_C) & Volumetric Holdup (φ_T). With our tool, you need to enter the respective value for Solid Density & Volumetric Holdup 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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