Settling Velocity given Celsius for diameter greater than 0.1mm Calculator

✖Specific gravity of particle is the ratio of density of particle to density of standard material.ⓘ Specific gravity of particle [G]			+10% -10%
✖Specific Gravity of Fluid is the ratio of the specific weight of a substance to the specific weight of a standard fluid.ⓘ Specific Gravity of Fluid [G_f]			+10% -10%
✖Diameter is a straight line passing from side to side through the center of a body or figure, especially a circle or sphere.ⓘ Diameter [D]			+10% -10%
✖Temperature in Fahrenheit is the temperature scale based on one proposed in 1724 by the physicist Daniel Gabriel Fahrenheit. It uses the degree Fahrenheit as the unit.ⓘ Temperature in Fahrenheit [T_F]			+10% -10%

✖Settling velocity is defined as the terminal velocity of a particle in still fluid.ⓘ Settling Velocity given Celsius for diameter greater than 0.1mm [v_s]

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Formula

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Settling Velocity given Celsius for diameter greater than 0.1mm

Formula

`"v"_{"s"} = 418*("G"-"G"_{"f"})*"D"*(3*"T"_{"F"}+70)/100`

Example

`"71571.35m/s"=418*("16"-"14")*"10m"*(3*"12°F"+70)/100`

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Settling Velocity given Celsius for diameter greater than 0.1mm Solution

STEP 0: Pre-Calculation Summary

Formula Used

Settling Velocity = 418*(Specific gravity of particle-Specific Gravity of Fluid)*Diameter*(3*Temperature in Fahrenheit+70)/100
v_s = 418*(G-G_f)*D*(3*T_F+70)/100
This formula uses 5 Variables

Variables Used

Settling Velocity - (Measured in Meter per Second) - Settling velocity is defined as the terminal velocity of a particle in still fluid.
Specific gravity of particle - Specific gravity of particle is the ratio of density of particle to density of standard material.
Specific Gravity of Fluid - Specific Gravity of Fluid is the ratio of the specific weight of a substance to the specific weight of a standard fluid.
Diameter - (Measured in Meter) - Diameter is a straight line passing from side to side through the center of a body or figure, especially a circle or sphere.
Temperature in Fahrenheit - (Measured in Kelvin) - Temperature in Fahrenheit is the temperature scale based on one proposed in 1724 by the physicist Daniel Gabriel Fahrenheit. It uses the degree Fahrenheit as the unit.

STEP 1: Convert Input(s) to Base Unit

Specific gravity of particle: 16 --> No Conversion Required
Specific Gravity of Fluid: 14 --> No Conversion Required
Diameter: 10 Meter --> 10 Meter No Conversion Required
Temperature in Fahrenheit: 12 Fahrenheit --> 262.038882255554 Kelvin (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

v_s = 418*(G-G_f)*D*(3*T_F+70)/100 --> 418*(16-14)*10*(3*262.038882255554+70)/100

Evaluating ... ...

v_s = 71571.3516696929

STEP 3: Convert Result to Output's Unit

71571.3516696929 Meter per Second --> No Conversion Required

FINAL ANSWER

71571.3516696929 ≈ 71571.35 Meter per Second <-- Settling Velocity

(Calculation completed in 00.004 seconds)

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< 19 Settling Velocity Calculators

Settling Velocity

Go Settling Velocity = sqrt((4*[g]*(Density of Particle-Liquid Density)*Effective Particle Diameter)/(3*Drag Coefficient*Liquid Density))

Settling Velocity with respect to Kinematic Viscosity

Go Settling Velocity = [g]*(Specific Gravity of Material-Specific Gravity of Fluid)*Diameter^2/18*Kinematic Viscosity

Settling Velocity with respect to Dynamic Viscosity

Go Settling Velocity = [g]*(Density of Particle-Liquid Density)*Effective Particle Diameter^2/18*Dynamic Viscosity

Settling Velocity using Temperature in Fahrenheit

Go Settling Velocity = 418*(Specific gravity of particle-Specific Gravity of Fluid)*Effective Particle Diameter^2*((Outside Temperature+10)/60)

Settling Velocity with respect to Specific Gravity of Particle

Go Settling Velocity = sqrt((4*[g]*(Specific Gravity of Material-1)*Diameter)/(3*Drag Coefficient))

Settling Velocity given Celsius for diameter greater than 0.1mm

Go Settling Velocity = 418*(Specific gravity of particle-Specific Gravity of Fluid)*Diameter*(3*Temperature in Fahrenheit+70)/100

Settling Velocity given Fahrenheit for diameter greater than 0.1mm

Go Settling Velocity = 418*(Specific gravity of particle-Specific Gravity of Fluid)*Diameter*(Temperature in Fahrenheit+10)/60

Settling Velocity given degree Celsius

Go Settling Velocity = 418*(Specific gravity of particle-Specific Gravity of Fluid)*Diameter^2*((3*Temperature+70)/100)

Settling Velocity given Frictional Drag

Go Settling Velocity = sqrt(2*Drag Force/(Area*Drag Coefficient*Liquid Density))

Settling Velocity given Specific Gravity of Particle and Viscosity

Go Settling Velocity = [g]*(Specific gravity of particle-1)*Diameter^2/18*Kinematic Viscosity

Settling Velocity given Particle Reynold's Number

Go Settling Velocity = Dynamic Viscosity*Reynolds Number/(Liquid Density*Diameter)

Settling Velocity given Drag Force as per Stokes Law

Go Settling Velocity = Drag Force/3*pi*Dynamic Viscosity*Diameter

Settling Velocity at 10 degree Celsius

Go Settling Velocity = 418*(Specific gravity of particle-Specific Gravity of Fluid)*Diameter^2

Settling Velocity given Displacement Velocity for Fine Particles

Go Settling Velocity = Displacement velocity/sqrt(8/Darcy Friction Factor)

Settling Velocity given Height at Outlet Zone with respect to Settling Velocity

Go Settling Velocity = Falling Speed*Height of Crack/Outer Height

Settling Velocity given Surface Area with respect to Settling Velocity

Go Settling Velocity = Falling Speed*Cross-Sectional Area/Area

Settling Velocity given Ratio of Removal with respect to Settling Velocity

Go Settling Velocity = Falling Speed/Removal Ratio

Surface Loading with respect to Settling Velocity

Go Surface loading rate = 864000*Settling Velocity

Settling Velocity given Displacement Velocity with Settling Velocity

Go Settling Velocity = Displacement velocity/18

Settling Velocity given Celsius for diameter greater than 0.1mm Formula

Settling Velocity = 418*(Specific gravity of particle-Specific Gravity of Fluid)*Diameter*(3*Temperature in Fahrenheit+70)/100
v_s = 418*(G-G_f)*D*(3*T_F+70)/100

What is stokes law ?

Stokes law is the basis of the falling-sphere viscometer, in which the fluid is stationary in a vertical glass tube. A sphere of known size and density is allowed to descend through the liquid.

How to Calculate Settling Velocity given Celsius for diameter greater than 0.1mm?

Settling Velocity given Celsius for diameter greater than 0.1mm calculator uses Settling Velocity = 418*(Specific gravity of particle-Specific Gravity of Fluid)*Diameter*(3*Temperature in Fahrenheit+70)/100 to calculate the Settling Velocity, The Settling Velocity given Celsius for diameter greater than 0.1mm is defined as the settling velocity (also referred to as the “sedimentation velocity”) is defined as the terminal velocity of a particle in still fluid. Settling Velocity is denoted by v_s symbol.

How to calculate Settling Velocity given Celsius for diameter greater than 0.1mm using this online calculator? To use this online calculator for Settling Velocity given Celsius for diameter greater than 0.1mm, enter Specific gravity of particle (G), Specific Gravity of Fluid (G_f), Diameter (D) & Temperature in Fahrenheit (T_F) and hit the calculate button. Here is how the Settling Velocity given Celsius for diameter greater than 0.1mm calculation can be explained with given input values -> 71571.35 = 418*(16-14)*10*(3*262.038882255554+70)/100.

FAQ

What is Settling Velocity given Celsius for diameter greater than 0.1mm?

The Settling Velocity given Celsius for diameter greater than 0.1mm is defined as the settling velocity (also referred to as the “sedimentation velocity”) is defined as the terminal velocity of a particle in still fluid and is represented as v_s = 418*(G-G_f)*D*(3*T_F+70)/100 or Settling Velocity = 418*(Specific gravity of particle-Specific Gravity of Fluid)*Diameter*(3*Temperature in Fahrenheit+70)/100. Specific gravity of particle is the ratio of density of particle to density of standard material, Specific Gravity of Fluid is the ratio of the specific weight of a substance to the specific weight of a standard fluid, Diameter is a straight line passing from side to side through the center of a body or figure, especially a circle or sphere & Temperature in Fahrenheit is the temperature scale based on one proposed in 1724 by the physicist Daniel Gabriel Fahrenheit. It uses the degree Fahrenheit as the unit.

How to calculate Settling Velocity given Celsius for diameter greater than 0.1mm?

The Settling Velocity given Celsius for diameter greater than 0.1mm is defined as the settling velocity (also referred to as the “sedimentation velocity”) is defined as the terminal velocity of a particle in still fluid is calculated using Settling Velocity = 418*(Specific gravity of particle-Specific Gravity of Fluid)*Diameter*(3*Temperature in Fahrenheit+70)/100. To calculate Settling Velocity given Celsius for diameter greater than 0.1mm, you need Specific gravity of particle (G), Specific Gravity of Fluid (G_f), Diameter (D) & Temperature in Fahrenheit (T_F). With our tool, you need to enter the respective value for Specific gravity of particle, Specific Gravity of Fluid, Diameter & Temperature in Fahrenheit 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 Settling Velocity?

In this formula, Settling Velocity uses Specific gravity of particle, Specific Gravity of Fluid, Diameter & Temperature in Fahrenheit. We can use 17 other way(s) to calculate the same, which is/are as follows -

Settling Velocity = sqrt(2*Drag Force/(Area*Drag Coefficient*Liquid Density))
Settling Velocity = sqrt((4*[g]*(Density of Particle-Liquid Density)*Effective Particle Diameter)/(3*Drag Coefficient*Liquid Density))
Settling Velocity = sqrt((4*[g]*(Specific Gravity of Material-1)*Diameter)/(3*Drag Coefficient))
Settling Velocity = Dynamic Viscosity*Reynolds Number/(Liquid Density*Diameter)
Settling Velocity = Drag Force/3*pi*Dynamic Viscosity*Diameter
Settling Velocity = [g]*(Density of Particle-Liquid Density)*Effective Particle Diameter^2/18*Dynamic Viscosity
Settling Velocity = [g]*(Specific Gravity of Material-Specific Gravity of Fluid)*Diameter^2/18*Kinematic Viscosity
Settling Velocity = [g]*(Specific gravity of particle-1)*Diameter^2/18*Kinematic Viscosity
Settling Velocity = 418*(Specific gravity of particle-Specific Gravity of Fluid)*Diameter^2
Settling Velocity = 418*(Specific gravity of particle-Specific Gravity of Fluid)*Effective Particle Diameter^2*((Outside Temperature+10)/60)
Settling Velocity = 418*(Specific gravity of particle-Specific Gravity of Fluid)*Diameter^2*((3*Temperature+70)/100)
Settling Velocity = 418*(Specific gravity of particle-Specific Gravity of Fluid)*Diameter*(Temperature in Fahrenheit+10)/60
Settling Velocity = Falling Speed*Height of Crack/Outer Height
Settling Velocity = Displacement velocity/sqrt(8/Darcy Friction Factor)
Settling Velocity = Displacement velocity/18
Settling Velocity = Falling Speed/Removal Ratio
Settling Velocity = Falling Speed*Cross-Sectional Area/Area

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