Volume of Mixing Tank given Mean Velocity Gradient Calculator

✖Power Requirement refers to the amount of energy needed to operate various processes, systems, or equipment involved in environmental management.ⓘ Power Requirement [P]			+10% -10%
✖Mean Velocity Gradient refers to the rate of change of velocity within a fluid over a specified distance or depth.ⓘ Mean Velocity Gradient [G]			+10% -10%
✖Dynamic Viscosity refers to a measure of a fluid's resistance to flow under an applied force or shear stress.ⓘ Dynamic Viscosity [μ_viscosity]			+10% -10%

✖Volume of Tank refers to the total capacity or size of a tank used for storing liquids, such as water, chemicals, or wastewater.ⓘ Volume of Mixing Tank given Mean Velocity Gradient [V]

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Volume of Mixing Tank given Mean Velocity Gradient Solution

STEP 0: Pre-Calculation Summary

Formula Used

Volume of Tank = (Power Requirement/((Mean Velocity Gradient)^2*Dynamic Viscosity))
V = (P/((G)^2*μ_viscosity))
This formula uses 4 Variables

Variables Used

Volume of Tank - (Measured in Cubic Meter) - Volume of Tank refers to the total capacity or size of a tank used for storing liquids, such as water, chemicals, or wastewater.
Power Requirement - (Measured in Watt) - Power Requirement refers to the amount of energy needed to operate various processes, systems, or equipment involved in environmental management.
Mean Velocity Gradient - (Measured in 1 Per Second) - Mean Velocity Gradient refers to the rate of change of velocity within a fluid over a specified distance or depth.
Dynamic Viscosity - (Measured in Pascal Second) - Dynamic Viscosity refers to a measure of a fluid's resistance to flow under an applied force or shear stress.

STEP 1: Convert Input(s) to Base Unit

Power Requirement: 3 Kilojoule per Second --> 3000 Watt (Check conversion here)
Mean Velocity Gradient: 2 1 Per Second --> 2 1 Per Second No Conversion Required
Dynamic Viscosity: 833.33 Poise --> 83.333 Pascal Second (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

V = (P/((G)^2*μ_viscosity)) --> (3000/((2)^2*83.333))

Evaluating ... ...

V = 9.000036000144

STEP 3: Convert Result to Output's Unit

9.000036000144 Cubic Meter --> No Conversion Required

FINAL ANSWER

9.000036000144 ≈ 9.000036 Cubic Meter <-- Volume of Tank

(Calculation completed in 00.004 seconds)

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Birsa Institute of Technology (BIT), Sindri

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< Design of Rapid Mix Basin and Flocculation Basin Calculators

Mean Velocity Gradient given Power Requirement

LaTeX Go Mean Velocity Gradient = sqrt(Power Requirement/(Dynamic Viscosity*Volume of Tank))

Hydraulic Retention Time given Volume of Rapid Mix Basin

LaTeX Go Hydraulic Retention Time in Seconds = Volume of Rapid Mix Basin/Francis Discharge with Suppressed End

Wastewater Flow given Volume of Rapid Mix Basin

LaTeX Go Waste Water Flow = Volume of Rapid Mix Basin/Hydraulic Retention Time

Volume of Rapid Mix Basin

LaTeX Go Volume of Rapid Mix Basin = Hydraulic Retention Time*Waste Water Flow

Volume of Mixing Tank given Mean Velocity Gradient Formula

LaTeX Go

Volume of Tank = (Power Requirement/((Mean Velocity Gradient)^2*Dynamic Viscosity))
V = (P/((G)^2*μ_viscosity))

What is Mean Velocity Gradient?

The difference in velocity between adjacent layers of the fluid is known as a velocity gradient and is given by v/x, where v is the velocity difference and x is the distance between the layers.

How to Calculate Volume of Mixing Tank given Mean Velocity Gradient?

Volume of Mixing Tank given Mean Velocity Gradient calculator uses Volume of Tank = (Power Requirement/((Mean Velocity Gradient)^2*Dynamic Viscosity)) to calculate the Volume of Tank, The Volume of Mixing Tank given Mean Velocity Gradient is defined as the relationship to find volume of tank when we have prior information of power required, mean velocity gradient and dynamic viscosity. Volume of Tank is denoted by V symbol.

How to calculate Volume of Mixing Tank given Mean Velocity Gradient using this online calculator? To use this online calculator for Volume of Mixing Tank given Mean Velocity Gradient, enter Power Requirement (P), Mean Velocity Gradient (G) & Dynamic Viscosity (μ_viscosity) and hit the calculate button. Here is how the Volume of Mixing Tank given Mean Velocity Gradient calculation can be explained with given input values -> 735.2941 = (3000/((2)^2*83.333)).

FAQ

What is Volume of Mixing Tank given Mean Velocity Gradient?

The Volume of Mixing Tank given Mean Velocity Gradient is defined as the relationship to find volume of tank when we have prior information of power required, mean velocity gradient and dynamic viscosity and is represented as V = (P/((G)^2*μ_viscosity)) or Volume of Tank = (Power Requirement/((Mean Velocity Gradient)^2*Dynamic Viscosity)). Power Requirement refers to the amount of energy needed to operate various processes, systems, or equipment involved in environmental management, Mean Velocity Gradient refers to the rate of change of velocity within a fluid over a specified distance or depth & Dynamic Viscosity refers to a measure of a fluid's resistance to flow under an applied force or shear stress.

How to calculate Volume of Mixing Tank given Mean Velocity Gradient?

The Volume of Mixing Tank given Mean Velocity Gradient is defined as the relationship to find volume of tank when we have prior information of power required, mean velocity gradient and dynamic viscosity is calculated using Volume of Tank = (Power Requirement/((Mean Velocity Gradient)^2*Dynamic Viscosity)). To calculate Volume of Mixing Tank given Mean Velocity Gradient, you need Power Requirement (P), Mean Velocity Gradient (G) & Dynamic Viscosity (μ_viscosity). With our tool, you need to enter the respective value for Power Requirement, Mean Velocity Gradient & Dynamic Viscosity 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 Volume of Tank?

In this formula, Volume of Tank uses Power Requirement, Mean Velocity Gradient & Dynamic Viscosity. We can use 3 other way(s) to calculate the same, which is/are as follows -

Volume of Tank = (Power Requirement/((Mean Velocity Gradient)^2*Dynamic Viscosity))
Volume of Tank = (Retention Time*Flow Rate of Secondary Effluent)/Time in Min Per Day
Volume of Tank = (Power Requirement/((Mean Velocity Gradient)^2*Dynamic Viscosity))

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