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Depth of flow2 when Absolute velocity of the surge when the flow is completely stopped Solution

STEP 0: Pre-Calculation Summary
Formula Used
depth2 = Depth of Point 1*(Velocity_of the fluid at 1+Absolute Velocity of the Issuing Jet)/Absolute Velocity of the Issuing Jet
h 2 = h 1*(V1+V)/V
This formula uses 3 Variables
Variables Used
Depth of Point 1 - Depth of Point 1 is the depth of point below the free surface in a static mass of liquid. (Measured in Meter)
Velocity_of the fluid at 1 - Velocity_of the fluid at 1 is defined as the velocity of the flowing liquid at a point 1 (Measured in Meter per Second)
Absolute Velocity of the Issuing Jet - Absolute Velocity of the Issuing Jet is actual velocity of jet used in propeller. (Measured in Meter per Second)
STEP 1: Convert Input(s) to Base Unit
Depth of Point 1: 10 Meter --> 10 Meter No Conversion Required
Velocity_of the fluid at 1: 10 Meter per Second --> 10 Meter per Second No Conversion Required
Absolute Velocity of the Issuing Jet: 10 Meter per Second --> 10 Meter per Second No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
h 2 = h 1*(V1+V)/V --> 10*(10+10)/10
Evaluating ... ...
h 2 = 20
STEP 3: Convert Result to Output's Unit
20 Meter --> No Conversion Required
20 Meter <-- Depth of Point 2
(Calculation completed in 00.016 seconds)

< 11 Other formulas that you can solve using the same Inputs

Specific Weight of Liquid when Work Done by the Jet on Ship is Given
specific_weight_of_liquid = (Work *[g])/(Absolute Velocity of the Issuing Jet*Velocity of the Ship*Area) Go
Parallel upstream flow components after shock as Mach tends to infinite
parallel_upstream_flow_component = Velocity_of the fluid at 1*(1-(2*(sin(Wave angle))^2)/(Specific Heat Ratio-1)) Go
Perpendicular upstream flow components behind the shock wave
perpedicular_upstream_flow_component = Velocity_of the fluid at 1*((sin(2*Wave angle))/(Specific Heat Ratio-1)) Go
Weight of Water when Work Done by the Jet on Ship is Given
weight_of_water = (Work *[g])/(Absolute Velocity of the Issuing Jet*Velocity of the Ship) Go
Work Done by the Jet on Ship
work = weight of water*Velocity of the Ship*Absolute Velocity of the Issuing Jet/[g] Go
Velocity of the moving ship when Work Done by the Jet on Ship is Given
ship_velocity = (Work *[g])/(weight of water*Absolute Velocity of the Issuing Jet) Go
Cross Sectional Area at Section 1 for a Steady Flow
cross_sectional_area = Discharge/(Density 1*Velocity_of the fluid at 1) Go
Mass Density at Section 1 for a Steady Flow
density_1 = Discharge/(Cross sectional area*Velocity_of the fluid at 1) Go
Weight of Water when Propelling Force is Given
weight_of_water = Force*[g]/Absolute Velocity of the Issuing Jet Go
Propelling Force
force = weight of water*Absolute Velocity of the Issuing Jet/[g] Go
Velocity of the Moving Ship when Relative Velocity is Given
ship_velocity = Relative Velocity-Absolute Velocity of the Issuing Jet Go

< 7 Other formulas that calculate the same Output

Depth of flow2 when Celerity of the Wave is Given
depth2 = -((((Height*[g])/(Celerity of the Wave*Velocity_of the fluid at 1))-2)/(((Height*[g])/(Celerity of the Wave*Velocity_of the fluid at 1))*Depth of Point 1)) Go
Conjugate Depth y2 when Critical Depth is Given
depth2 = 0.5*Depth of Point 1*(-1+sqrt(1+(8*(critical depth*critical depth*critical depth))/(Depth of Point 1*Depth of Point 1*Depth of Point 1))) Go
Conjugate Depth y2 when Discharge per unit width of channel is Given
depth2 = 0.5*Depth of Point 1*(-1+sqrt(1+(8*(discharge per unit width ^2))/([g]*Depth of Point 1*Depth of Point 1*Depth of Point 1))) Go
Depth of flow2 when Absolute velocity of the surge moving towards right is Given
depth2 = Depth of Point 1/((Absolute Velocity of the Issuing Jet-Velocity_of the fluid at 2)/(Absolute Velocity of the Issuing Jet-Velocity_of the fluid at 1)) Go
Depth of flow2 when Absolute velocity of the surge moving towards right is Given
depth2 = Depth of Point 1/((Absolute Velocity of the Issuing Jet-Velocity_of the fluid at 2)/(Absolute Velocity of the Issuing Jet-Velocity_of the fluid at 1)) Go
Conjugate Depth y2 when Froude Number Fr1 is Given
depth2 = Depth of Point 1*(0.5*(-1+sqrt(1+(8*(Froude number^2))))) Go
Conjugate Depth y2 when Froude Number Fr2 is Given
depth2 = Depth of Point 1/(0.5*(-1+sqrt(1+(8*(Froude number^2))))) Go

Depth of flow2 when Absolute velocity of the surge when the flow is completely stopped Formula

depth2 = Depth of Point 1*(Velocity_of the fluid at 1+Absolute Velocity of the Issuing Jet)/Absolute Velocity of the Issuing Jet
h 2 = h 1*(V1+V)/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 Depth of flow2 when Absolute velocity of the surge when the flow is completely stopped?

Depth of flow2 when Absolute velocity of the surge when the flow is completely stopped calculator uses depth2 = Depth of Point 1*(Velocity_of the fluid at 1+Absolute Velocity of the Issuing Jet)/Absolute Velocity of the Issuing Jet to calculate the Depth of Point 2, The Depth of flow2 when Absolute velocity of the surge when the flow is completely stopped is defined as velocity at a particular depth. Depth of Point 2 and is denoted by h 2 symbol.

How to calculate Depth of flow2 when Absolute velocity of the surge when the flow is completely stopped using this online calculator? To use this online calculator for Depth of flow2 when Absolute velocity of the surge when the flow is completely stopped, enter Depth of Point 1 (h 1), Velocity_of the fluid at 1 (V1) and Absolute Velocity of the Issuing Jet (V) and hit the calculate button. Here is how the Depth of flow2 when Absolute velocity of the surge when the flow is completely stopped calculation can be explained with given input values -> 20 = 10*(10+10)/10.

FAQ

What is Depth of flow2 when Absolute velocity of the surge when the flow is completely stopped?
The Depth of flow2 when Absolute velocity of the surge when the flow is completely stopped is defined as velocity at a particular depth and is represented as h 2 = h 1*(V1+V)/V or depth2 = Depth of Point 1*(Velocity_of the fluid at 1+Absolute Velocity of the Issuing Jet)/Absolute Velocity of the Issuing Jet. Depth of Point 1 is the depth of point below the free surface in a static mass of liquid, Velocity_of the fluid at 1 is defined as the velocity of the flowing liquid at a point 1 and Absolute Velocity of the Issuing Jet is actual velocity of jet used in propeller.
How to calculate Depth of flow2 when Absolute velocity of the surge when the flow is completely stopped?
The Depth of flow2 when Absolute velocity of the surge when the flow is completely stopped is defined as velocity at a particular depth is calculated using depth2 = Depth of Point 1*(Velocity_of the fluid at 1+Absolute Velocity of the Issuing Jet)/Absolute Velocity of the Issuing Jet. To calculate Depth of flow2 when Absolute velocity of the surge when the flow is completely stopped, you need Depth of Point 1 (h 1), Velocity_of the fluid at 1 (V1) and Absolute Velocity of the Issuing Jet (V). With our tool, you need to enter the respective value for Depth of Point 1, Velocity_of the fluid at 1 and Absolute Velocity of the Issuing Jet 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 Depth of Point 2?
In this formula, Depth of Point 2 uses Depth of Point 1, Velocity_of the fluid at 1 and Absolute Velocity of the Issuing Jet. We can use 7 other way(s) to calculate the same, which is/are as follows -
• depth2 = 0.5*Depth of Point 1*(-1+sqrt(1+(8*(discharge per unit width ^2))/([g]*Depth of Point 1*Depth of Point 1*Depth of Point 1)))
• depth2 = 0.5*Depth of Point 1*(-1+sqrt(1+(8*(critical depth*critical depth*critical depth))/(Depth of Point 1*Depth of Point 1*Depth of Point 1)))
• depth2 = Depth of Point 1*(0.5*(-1+sqrt(1+(8*(Froude number^2)))))
• depth2 = Depth of Point 1/(0.5*(-1+sqrt(1+(8*(Froude number^2)))))
• depth2 = Depth of Point 1/((Absolute Velocity of the Issuing Jet-Velocity_of the fluid at 2)/(Absolute Velocity of the Issuing Jet-Velocity_of the fluid at 1))
• depth2 = Depth of Point 1/((Absolute Velocity of the Issuing Jet-Velocity_of the fluid at 2)/(Absolute Velocity of the Issuing Jet-Velocity_of the fluid at 1))
• depth2 = -((((Height*[g])/(Celerity of the Wave*Velocity_of the fluid at 1))-2)/(((Height*[g])/(Celerity of the Wave*Velocity_of the fluid at 1))*Depth of Point 1))
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