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Absolute Velocity of Surges when Depth of flow is Given Solution

STEP 0: Pre-Calculation Summary
Formula Used
absolute_velocity = Celerity of the Wave-Mean velocity
V = C-V
This formula uses 2 Variables
Variables Used
Celerity of the Wave - Celerity of the Wave is the addition to the normal water velocity of the channels. (Measured in Meter per Second)
Mean velocity - Mean velocity is defined as the average velocity of a fluid at a point and over an arbitrary time T. (Measured in Meter per Second)
STEP 1: Convert Input(s) to Base Unit
Celerity of the Wave: 10 Meter per Second --> 10 Meter per Second No Conversion Required
Mean velocity: 50 Meter per Second --> 50 Meter per Second No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
V = C-V --> 10-50
Evaluating ... ...
V = -40
STEP 3: Convert Result to Output's Unit
-40 Meter per Second --> No Conversion Required
FINAL ANSWER
-40 Meter per Second <-- Absolute Velocity of the Issuing Jet
(Calculation completed in 00.016 seconds)

11 Other formulas that you can solve using the same Inputs

Diameter of Pipe when Pressure Drop over the Length of Pipe is Given
diameter_of_pipe = sqrt((32*Dynamic viscosity*Mean velocity*Length of Pipe)/Pressure Difference) Go
Dynamic Viscosity when Pressure Drop over the Length of Pipe is Given
dynamic_viscosity = (Pressure Difference*(Diameter of Pipe^2))/(32*Length of Pipe*Mean velocity) Go
Length of Pipe when Pressure Drop over the Length of Pipe is Given
length_of_pipe = (Pressure Difference*Diameter of Pipe^2)/(32*Dynamic viscosity*Mean velocity) Go
Pressure Drop over the Length of Pipe
pressure_difference = (32*Dynamic viscosity*Mean velocity*Length of Pipe/(Diameter of Pipe^2)) Go
Radius of Pipe when Mean Velocity of Flow is Given
radius_of_pipe = sqrt(-Mean velocity*8*Dynamic viscosity/Pressure Gradient) Go
Viscosity when Mean Velocity of Flow is Given
dynamic_viscosity = -(1/(8*Mean velocity))*Pressure Gradient*radius of pipe^2 Go
Pressure Gradients when Mean Velocity of Flow is Given
pressure_gradient = -8*Mean velocity*Dynamic viscosity/(radius of pipe^2) Go
Friction velocity
friction_velocity = Mean velocity*(sqrt(Friction factor/8)) Go
Friction Factor When Frictional Velocity is Given
friction_factor = 8*((Friction velocity/Mean velocity)^2) Go
Surface Velocity of the river in Float Method
surface_velocity_river = Mean velocity/0.85 Go
Maximum Velocity at axis of Cylindrical Element when Mean Velocity of Flow is Given
maximum_velocity = 2*Mean velocity Go

11 Other formulas that calculate the same Output

Absolute Velocity(V) when Dynamic Thrust Exerted by the Jet on the Plate is given
absolute_velocity = (sqrt((Fluid mass*specific gravity of liquid )/(Specific Weight*Cross sectional area)))+Velocity of Jet Go
Absolute Velocity(V) when Mass of the Fluid Striking the Plate is given
absolute_velocity = ((Fluid mass*specific gravity of liquid )/(Specific Weight*Cross sectional area))+Velocity of Jet Go
Absolute Velocity when Mass of Fluid Striking the Plate is given
absolute_velocity = ((Fluid mass*specific gravity of liquid )/(Specific Weight*Cross sectional area))+Velocity of Jet Go
Jet Velocity when Output Power is Given
absolute_velocity = (Output Power/(Water Density*Rate of flow*flow velocity))+flow velocity Go
Jet Velocity when Power Lost is Given
absolute_velocity = sqrt((Power Loss/(density of fluid*Rate of flow*0.5)))+flow velocity Go
Jet Velocity when Thrust on the Propeller is Given
absolute_velocity = (Thrust force/(Water Density*Rate of flow))+flow velocity Go
Absolute Velocity of the Issuing Jet when Work Done by the Jet on Ship is Given
absolute_velocity = (Work *[g])/(weight of water*Velocity of the Ship) Go
Jet Velocity when Rate of Flow through Propeller is Given
absolute_velocity = (8*Rate of flow/(pi*Diameter ^2))-flow velocity Go
Absolute Velocity of the Issuing Jet when Propelling Force is Given
absolute_velocity = [g]*Force/weight of water Go
Absolute Velocity of the Issuing Jet when Relative Velocity is Given
absolute_velocity = Relative Velocity-Velocity of the Ship Go
Jet Velocity when Theoretical Propulsive Efficiency is Given
absolute_velocity = (2/Efficiency -1)*flow velocity Go

Absolute Velocity of Surges when Depth of flow is Given Formula

absolute_velocity = Celerity of the Wave-Mean velocity
V = C-V

What is Absolute Velocity ?

The concept of absolute velocity is mainly used in turbomachinery design and defines the velocity of a fluid particle in relation to the surrounding, stationary environment. Together with the relative velocity (w) and the circumferential speed (u), it forms the velocity triangle.

How to Calculate Absolute Velocity of Surges when Depth of flow is Given?

Absolute Velocity of Surges when Depth of flow is Given calculator uses absolute_velocity = Celerity of the Wave-Mean velocity to calculate the Absolute Velocity of the Issuing Jet, The Absolute Velocity of Surges when Depth of flow is Given is defined as velocity defined with no reference in the surges flow. Absolute Velocity of the Issuing Jet and is denoted by V symbol.

How to calculate Absolute Velocity of Surges when Depth of flow is Given using this online calculator? To use this online calculator for Absolute Velocity of Surges when Depth of flow is Given, enter Celerity of the Wave (C) and Mean velocity (V) and hit the calculate button. Here is how the Absolute Velocity of Surges when Depth of flow is Given calculation can be explained with given input values -> -40 = 10-50.

FAQ

What is Absolute Velocity of Surges when Depth of flow is Given?
The Absolute Velocity of Surges when Depth of flow is Given is defined as velocity defined with no reference in the surges flow and is represented as V = C-V or absolute_velocity = Celerity of the Wave-Mean velocity. Celerity of the Wave is the addition to the normal water velocity of the channels. and Mean velocity is defined as the average velocity of a fluid at a point and over an arbitrary time T.
How to calculate Absolute Velocity of Surges when Depth of flow is Given?
The Absolute Velocity of Surges when Depth of flow is Given is defined as velocity defined with no reference in the surges flow is calculated using absolute_velocity = Celerity of the Wave-Mean velocity. To calculate Absolute Velocity of Surges when Depth of flow is Given, you need Celerity of the Wave (C) and Mean velocity (V). With our tool, you need to enter the respective value for Celerity of the Wave and Mean velocity 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 Absolute Velocity of the Issuing Jet?
In this formula, Absolute Velocity of the Issuing Jet uses Celerity of the Wave and Mean velocity. We can use 11 other way(s) to calculate the same, which is/are as follows -
  • absolute_velocity = Relative Velocity-Velocity of the Ship
  • absolute_velocity = [g]*Force/weight of water
  • absolute_velocity = (Work *[g])/(weight of water*Velocity of the Ship)
  • absolute_velocity = (Thrust force/(Water Density*Rate of flow))+flow velocity
  • absolute_velocity = (8*Rate of flow/(pi*Diameter ^2))-flow velocity
  • absolute_velocity = (Output Power/(Water Density*Rate of flow*flow velocity))+flow velocity
  • absolute_velocity = sqrt((Power Loss/(density of fluid*Rate of flow*0.5)))+flow velocity
  • absolute_velocity = (2/Efficiency -1)*flow velocity
  • absolute_velocity = ((Fluid mass*specific gravity of liquid )/(Specific Weight*Cross sectional area))+Velocity of Jet
  • absolute_velocity = (sqrt((Fluid mass*specific gravity of liquid )/(Specific Weight*Cross sectional area)))+Velocity of Jet
  • absolute_velocity = ((Fluid mass*specific gravity of liquid )/(Specific Weight*Cross sectional area))+Velocity of Jet
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