Velocity given Ratio of Inertial Forces and Viscous Forces using Newton's Friction model Solution

STEP 0: Pre-Calculation Summary
Formula Used
Velocity of Fluid = (Inertia Forces*Dynamic Viscosity)/(Viscous Force*Density of Fluid*Characteristic length)
Vf = (Fi*μviscosity)/(Fv*ρfluid*L)
This formula uses 6 Variables
Variables Used
Velocity of Fluid - (Measured in Meter per Second) - Velocity of Fluid is the vector field that is used to describe fluid motion in a mathematical manner.
Inertia Forces - (Measured in Newton) - Inertia Forces are the forces that keep fluid moving against viscous [ viscosity] forces.
Dynamic Viscosity - (Measured in Pascal Second) - The Dynamic Viscosity of a fluid is the measure of its resistance to flow when an external force is applied.
Viscous Force - (Measured in Newton) - Viscous Force is force due to viscosity.
Density of Fluid - (Measured in Kilogram per Cubic Meter) - Density of Fluid is defined as the mass of fluid per unit volume of the said fluid.
Characteristic length - (Measured in Meter) - Characteristic length is the linear dimension expressed in physical model relationships between prototype and model.
STEP 1: Convert Input(s) to Base Unit
Inertia Forces: 3.636 Kilonewton --> 3636 Newton (Check conversion here)
Dynamic Viscosity: 10.2 Poise --> 1.02 Pascal Second (Check conversion here)
Viscous Force: 0.0504 Kilonewton --> 50.4 Newton (Check conversion here)
Density of Fluid: 1.225 Kilogram per Cubic Meter --> 1.225 Kilogram per Cubic Meter No Conversion Required
Characteristic length: 3 Meter --> 3 Meter No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Vf = (Fiviscosity)/(Fvfluid*L) --> (3636*1.02)/(50.4*1.225*3)
Evaluating ... ...
Vf = 20.0233236151604
STEP 3: Convert Result to Output's Unit
20.0233236151604 Meter per Second --> No Conversion Required
FINAL ANSWER
20.0233236151604 20.02332 Meter per Second <-- Velocity of Fluid
(Calculation completed in 00.004 seconds)

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18 Relation between Forces on the Prototype and Forces on the Model Calculators

Scale Factor for Velocity given Forces on Prototype and Force on Model
Go Scale Factor for Velocity = sqrt(Force on Prototype/(Scale Factor for Density of Fluid*Scale Factor for Length^2*Force on Model))
Scale Factor for Length given Forces on Prototype and Force on Model
Go Scale Factor for Length = sqrt(Force on Prototype/(Scale Factor for Density of Fluid*Scale Factor for Velocity^2*Force on Model))
Velocity given Ratio of Inertial Forces and Viscous Forces using Newton's Friction model
Go Velocity of Fluid = (Inertia Forces*Dynamic Viscosity)/(Viscous Force*Density of Fluid*Characteristic length)
Density of Fluid for Ratio of Inertial Forces and Viscous Forces
Go Density of Fluid = (Inertia Forces*Dynamic Viscosity)/(Viscous Force*Velocity of Fluid*Characteristic length)
Length for Ratio of Inertial Forces and Viscous Forces
Go Characteristic length = (Inertia Forces*Dynamic Viscosity)/(Viscous Force*Density of Fluid*Velocity of Fluid)
Viscous Forces using Newton's Friction model
Go Viscous Force = (Inertia Forces*Dynamic Viscosity)/(Density of Fluid*Velocity of Fluid*Characteristic length)
Dynamic Viscosity for Ratio of Inertial Forces and Viscous Force
Go Dynamic Viscosity = (Viscous Force*Density of Fluid*Velocity of Fluid*Characteristic length)/Inertia Forces
Inertial Forces using Newton's Friction Model
Go Inertia Forces = (Viscous Force*Density of Fluid*Velocity of Fluid*Characteristic length)/Dynamic Viscosity
Relation between Forces on Prototype and Forces on Model
Go Force on Prototype = Scale Factor for Density of Fluid*(Scale Factor for Velocity^2)*(Scale Factor for Length^2)*Force on Model
Scale Factor for Density of Fluid given Forces on Prototype and Model
Go Scale Factor for Density of Fluid = Force on Prototype/(Scale Factor for Velocity^2*Scale Factor for Length^2*Force on Model)
Force on Model for Scale Factor Parameters
Go Force on Model = Force on Prototype/(Scale Factor for Density of Fluid*Scale Factor for Velocity^2*Scale Factor for Length^2)
Velocity given Kinematic Viscosity, Ratio of Inertial Forces and Viscous Forces
Go Velocity of Fluid = (Inertia Forces*Kinematic Viscosity for Model Analysis)/(Viscous Force*Characteristic length)
Length given Kinematic Viscosity, Ratio of Inertial forces and Viscous forces
Go Characteristic length = (Inertia Forces*Kinematic Viscosity for Model Analysis)/(Viscous Force*Velocity of Fluid)
Kinematic Viscosity for Ratio of Inertial Forces and Viscous Force
Go Kinematic Viscosity for Model Analysis = (Viscous Force*Velocity of Fluid*Characteristic length)/Inertia Forces
Inertial Forces given Kinematic Viscosity
Go Inertia Forces = (Viscous Force*Velocity of Fluid*Characteristic length)/Kinematic Viscosity for Model Analysis
Scale Factor for Inertia Forces given Force on Prototype
Go Scale Factor for Inertia Forces = Force on Prototype/Force on Model
Force on Model given Force on Prototype
Go Force on Model = Force on Prototype/Scale Factor for Inertia Forces
Force on Prototype
Go Force on Prototype = Scale Factor for Inertia Forces*Force on Model

Velocity given Ratio of Inertial Forces and Viscous Forces using Newton's Friction model Formula

Velocity of Fluid = (Inertia Forces*Dynamic Viscosity)/(Viscous Force*Density of Fluid*Characteristic length)
Vf = (Fi*μviscosity)/(Fv*ρfluid*L)

What is Viscous Force?

The viscosity of a fluid is a measure of its resistance to deformation at a given rate. For liquids, it corresponds to the informal concept of "thickness": for example, syrup has a higher viscosity than water. The viscous force is the force between a body and a fluid (liquid or gas) moving past it, in a direction so as to oppose the flow of the fluid past the object.

Define Inertial force

The force that keeps fluid moving against viscous [ viscosity] forces is the inertial force. The inertial forces are characterized by the product of the density rho times the velocity V times the gradient of the velocity dV/dx.

How to Calculate Velocity given Ratio of Inertial Forces and Viscous Forces using Newton's Friction model?

Velocity given Ratio of Inertial Forces and Viscous Forces using Newton's Friction model calculator uses Velocity of Fluid = (Inertia Forces*Dynamic Viscosity)/(Viscous Force*Density of Fluid*Characteristic length) to calculate the Velocity of Fluid, The Velocity given Ratio of Inertial Forces and Viscous Forces using Newton's Friction model is expressed using Newton’s friction model while the inertia forces (from above) are proportional to the respective parameters. Velocity of Fluid is denoted by Vf symbol.

How to calculate Velocity given Ratio of Inertial Forces and Viscous Forces using Newton's Friction model using this online calculator? To use this online calculator for Velocity given Ratio of Inertial Forces and Viscous Forces using Newton's Friction model, enter Inertia Forces (Fi), Dynamic Viscosity viscosity), Viscous Force (Fv), Density of Fluid fluid) & Characteristic length (L) and hit the calculate button. Here is how the Velocity given Ratio of Inertial Forces and Viscous Forces using Newton's Friction model calculation can be explained with given input values -> 20.02332 = (3636*1.02)/(50.4*1.225*3).

FAQ

What is Velocity given Ratio of Inertial Forces and Viscous Forces using Newton's Friction model?
The Velocity given Ratio of Inertial Forces and Viscous Forces using Newton's Friction model is expressed using Newton’s friction model while the inertia forces (from above) are proportional to the respective parameters and is represented as Vf = (Fiviscosity)/(Fvfluid*L) or Velocity of Fluid = (Inertia Forces*Dynamic Viscosity)/(Viscous Force*Density of Fluid*Characteristic length). Inertia Forces are the forces that keep fluid moving against viscous [ viscosity] forces, The Dynamic Viscosity of a fluid is the measure of its resistance to flow when an external force is applied, Viscous Force is force due to viscosity, Density of Fluid is defined as the mass of fluid per unit volume of the said fluid & Characteristic length is the linear dimension expressed in physical model relationships between prototype and model.
How to calculate Velocity given Ratio of Inertial Forces and Viscous Forces using Newton's Friction model?
The Velocity given Ratio of Inertial Forces and Viscous Forces using Newton's Friction model is expressed using Newton’s friction model while the inertia forces (from above) are proportional to the respective parameters is calculated using Velocity of Fluid = (Inertia Forces*Dynamic Viscosity)/(Viscous Force*Density of Fluid*Characteristic length). To calculate Velocity given Ratio of Inertial Forces and Viscous Forces using Newton's Friction model, you need Inertia Forces (Fi), Dynamic Viscosity viscosity), Viscous Force (Fv), Density of Fluid fluid) & Characteristic length (L). With our tool, you need to enter the respective value for Inertia Forces, Dynamic Viscosity, Viscous Force, Density of Fluid & Characteristic length 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 Velocity of Fluid?
In this formula, Velocity of Fluid uses Inertia Forces, Dynamic Viscosity, Viscous Force, Density of Fluid & Characteristic length. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Velocity of Fluid = (Inertia Forces*Kinematic Viscosity for Model Analysis)/(Viscous Force*Characteristic length)
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