Exit Energy Loss Coefficient given Inlet Impedance Solution

STEP 0: Pre-Calculation Summary
Formula Used
Exit Energy Loss Coefficient = Inlet Impedance-Entrance Energy Loss Coefficient-(Dimensionless Parameter*Inlet Length/(4*Hydraulic Radius))
Kex = F-Ken-(f*L/(4*rH))
This formula uses 6 Variables
Variables Used
Exit Energy Loss Coefficient - Exit Energy Loss Coefficient [dimensionless] is a dimensionless number (characteristic coefficient) to calculate the head loss.
Inlet Impedance - Inlet Impedance is measure of opposition to airflow at an inlet, influences performance and efficiency of fluid systems.
Entrance Energy Loss Coefficient - Entrance Energy Loss Coefficient [dimensionless] The loss coefficient (ζ) is a dimensionless number (characteristic coefficient) to calculate the head loss.
Dimensionless Parameter - Dimensionless Parameter is a numerical value without units used to express ratios, similarities, or relationships between physical quantities.
Inlet Length - (Measured in Meter) - Inlet Length is the length of a narrow water passage between peninsulas or through a barrier island leading to a bay or lagoon.
Hydraulic Radius - (Measured in Meter) - Hydraulic Radius is the ratio of the cross-sectional area of a channel or pipe in which a fluid is flowing to the wet perimeter of the conduit.
STEP 1: Convert Input(s) to Base Unit
Inlet Impedance: 2.246 --> No Conversion Required
Entrance Energy Loss Coefficient: 1.01 --> No Conversion Required
Dimensionless Parameter: 0.03 --> No Conversion Required
Inlet Length: 50 Meter --> 50 Meter No Conversion Required
Hydraulic Radius: 0.33 Meter --> 0.33 Meter No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Kex = F-Ken-(f*L/(4*rH)) --> 2.246-1.01-(0.03*50/(4*0.33))
Evaluating ... ...
Kex = 0.0996363636363637
STEP 3: Convert Result to Output's Unit
0.0996363636363637 --> No Conversion Required
FINAL ANSWER
0.0996363636363637 0.099636 <-- Exit Energy Loss Coefficient
(Calculation completed in 00.004 seconds)

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Coorg Institute of Technology (CIT), Coorg
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25 Inlet Currents and Tidal Elevations Calculators

Ocean Tide Amplitude using King's Dimensionless Velocity
Go Ocean Tide Amplitude = (Average Area over the Channel Length*Maximum Cross Sectional Average Velocity*Tidal Period)/ (King’s Dimensionless Velocity*2*pi*Surface Area of Bay)
Average Area over Channel Length using King's Dimensionless Velocity
Go Average Area over the Channel Length = (King’s Dimensionless Velocity*2*pi*Ocean Tide Amplitude*Surface Area of Bay)/(Tidal Period*Maximum Cross Sectional Average Velocity)
Maximum Cross-Sectionally Averaged Velocity during Tidal Cycle
Go Maximum Cross Sectional Average Velocity = (King’s Dimensionless Velocity*2*pi*Ocean Tide Amplitude*Surface Area of Bay)/(Average Area over the Channel Length*Tidal Period)
Surface Area of Bay using King's Dimensionless Velocity
Go Surface Area of Bay = (Average Area over the Channel Length*Tidal Period*Maximum Cross Sectional Average Velocity)/(King’s Dimensionless Velocity*2*pi*Ocean Tide Amplitude)
Tidal Period using King's Dimensionless Velocity
Go Tidal Period = (2*pi*Ocean Tide Amplitude*Surface Area of Bay*King’s Dimensionless Velocity)/(Average Area over the Channel Length*Maximum Cross Sectional Average Velocity)
King's Dimensionless Velocity
Go King’s Dimensionless Velocity = (Average Area over the Channel Length*Tidal Period*Maximum Cross Sectional Average Velocity)/(2*pi*Ocean Tide Amplitude*Surface Area of Bay)
Inlet Hydraulic Radius given Inlet Impedance
Go Hydraulic Radius = (Dimensionless Parameter*Inlet Length)/(4*(Inlet Impedance-Exit Energy Loss Coefficient-Entrance Energy Loss Coefficient))
Entrance Energy Loss Coefficient given Inlet Impedance
Go Entrance Energy Loss Coefficient = Inlet Impedance-Exit Energy Loss Coefficient-(Dimensionless Parameter*Inlet Length/(4*Hydraulic Radius))
Darcy - Weisbach Friction Term given Inlet Impedance
Go Dimensionless Parameter = (4*Hydraulic Radius*(Inlet Impedance-Entrance Energy Loss Coefficient-Exit Energy Loss Coefficient))/Inlet Length
Exit Energy Loss Coefficient given Inlet Impedance
Go Exit Energy Loss Coefficient = Inlet Impedance-Entrance Energy Loss Coefficient-(Dimensionless Parameter*Inlet Length/(4*Hydraulic Radius))
Inlet Impedance
Go Inlet Impedance = Entrance Energy Loss Coefficient+Exit Energy Loss Coefficient+(Dimensionless Parameter*Inlet Length/(4*Hydraulic Radius))
Inlet Length given Inlet Impedance
Go Inlet Length = 4*Hydraulic Radius*(Inlet Impedance-Exit Energy Loss Coefficient-Entrance Energy Loss Coefficient)/Dimensionless Parameter
Duration of Inflow given Inlet Channel Velocity
Go Duration of Inflow = (asin(Inlet Velocity/Maximum Cross Sectional Average Velocity)*Tidal Period)/(2*pi)
Maximum Cross-Sectionally Averaged Velocity during Tidal Cycle given Inlet Channel Velocity
Go Maximum Cross Sectional Average Velocity = Inlet Velocity/sin(2*pi*Duration of Inflow/Tidal Period)
Inlet Channel Velocity
Go Inlet Velocity = Maximum Cross Sectional Average Velocity*sin(2*pi*Duration of Inflow/Tidal Period)
Change of Bay Elevation with Time for Flow through Inlet into Bay
Go Change of Bay Elevation with Time = (Average Area over the Channel Length*Average Velocity in Channel for Flow)/Surface Area of Bay
Average Area over Channel Length for Flow through Inlet into Bay
Go Average Area over the Channel Length = (Surface Area of Bay*Change of Bay Elevation with Time)/Average Velocity in Channel for Flow
Average Velocity in Channel for Flow through Inlet into Bay
Go Average Velocity in Channel for Flow = (Surface Area of Bay*Change of Bay Elevation with Time)/Average Area over the Channel Length
Surface Area of Bay for Flow through Inlet into Bay
Go Surface Area of Bay = (Average Velocity in Channel for Flow*Average Area over the Channel Length)/Change of Bay Elevation with Time
Inlet Friction Coefficient Parameter given Keulegan Repletion Coefficient
Go King’s 1st Inlet Friction Coefficient = sqrt(1/King’s Inlet Friction Coefficient)/(Keulegan Repletion Coefficient [dimensionless])
Keulegan Repletion Coefficient
Go Keulegan Repletion Coefficient [dimensionless] = 1/King’s 1st Inlet Friction Coefficient*sqrt(1/King’s Inlet Friction Coefficient)
Inlet Friction Coefficient given Keulegan Repletion Coefficient
Go King’s Inlet Friction Coefficient = 1/(Keulegan Repletion Coefficient [dimensionless]*King’s 1st Inlet Friction Coefficient)^2
Hydraulic Radius given Dimensionless Parameter
Go Hydraulic Radius of the Channel = (116*Manning’s Roughness Coefficient^2/Dimensionless Parameter)^3
Surface Area of Bay given Tidal Prism Filling Bay
Go Surface Area of Bay = Tidal Prism Filling Bay/(2*Bay Tide Amplitude)
Bay Tide Amplitude given Tidal Prism Filling Bay
Go Bay Tide Amplitude = Tidal Prism Filling Bay/(2*Surface Area of Bay)

Exit Energy Loss Coefficient given Inlet Impedance Formula

Exit Energy Loss Coefficient = Inlet Impedance-Entrance Energy Loss Coefficient-(Dimensionless Parameter*Inlet Length/(4*Hydraulic Radius))
Kex = F-Ken-(f*L/(4*rH))

What is Darcy - Weisbach Friction term?

In fluid dynamics, the Darcy–Weisbach equation is an empirical equation, which relates the head loss, or pressure loss, due to friction along a given length of pipe to the average velocity of the fluid flow for an incompressible fluid. The equation is named after Henry Darcy and Julius Weisbach.

How to Calculate Exit Energy Loss Coefficient given Inlet Impedance?

Exit Energy Loss Coefficient given Inlet Impedance calculator uses Exit Energy Loss Coefficient = Inlet Impedance-Entrance Energy Loss Coefficient-(Dimensionless Parameter*Inlet Length/(4*Hydraulic Radius)) to calculate the Exit Energy Loss Coefficient, The Exit Energy Loss Coefficient given Inlet Impedance is a dimensionless number (characteristic coefficient) to calculate the head loss (HL) (see Pressure loss): v Characteristic flow velocity in the relevant hydraulic component (usually the flow velocity in the. cross-section of the connection downstream of the component. Exit Energy Loss Coefficient is denoted by Kex symbol.

How to calculate Exit Energy Loss Coefficient given Inlet Impedance using this online calculator? To use this online calculator for Exit Energy Loss Coefficient given Inlet Impedance, enter Inlet Impedance (F), Entrance Energy Loss Coefficient (Ken), Dimensionless Parameter (f), Inlet Length (L) & Hydraulic Radius (rH) and hit the calculate button. Here is how the Exit Energy Loss Coefficient given Inlet Impedance calculation can be explained with given input values -> 0.099636 = 2.246-1.01-(0.03*50/(4*0.33)).

FAQ

What is Exit Energy Loss Coefficient given Inlet Impedance?
The Exit Energy Loss Coefficient given Inlet Impedance is a dimensionless number (characteristic coefficient) to calculate the head loss (HL) (see Pressure loss): v Characteristic flow velocity in the relevant hydraulic component (usually the flow velocity in the. cross-section of the connection downstream of the component and is represented as Kex = F-Ken-(f*L/(4*rH)) or Exit Energy Loss Coefficient = Inlet Impedance-Entrance Energy Loss Coefficient-(Dimensionless Parameter*Inlet Length/(4*Hydraulic Radius)). Inlet Impedance is measure of opposition to airflow at an inlet, influences performance and efficiency of fluid systems, Entrance Energy Loss Coefficient [dimensionless] The loss coefficient (ζ) is a dimensionless number (characteristic coefficient) to calculate the head loss, Dimensionless Parameter is a numerical value without units used to express ratios, similarities, or relationships between physical quantities, Inlet Length is the length of a narrow water passage between peninsulas or through a barrier island leading to a bay or lagoon & Hydraulic Radius is the ratio of the cross-sectional area of a channel or pipe in which a fluid is flowing to the wet perimeter of the conduit.
How to calculate Exit Energy Loss Coefficient given Inlet Impedance?
The Exit Energy Loss Coefficient given Inlet Impedance is a dimensionless number (characteristic coefficient) to calculate the head loss (HL) (see Pressure loss): v Characteristic flow velocity in the relevant hydraulic component (usually the flow velocity in the. cross-section of the connection downstream of the component is calculated using Exit Energy Loss Coefficient = Inlet Impedance-Entrance Energy Loss Coefficient-(Dimensionless Parameter*Inlet Length/(4*Hydraulic Radius)). To calculate Exit Energy Loss Coefficient given Inlet Impedance, you need Inlet Impedance (F), Entrance Energy Loss Coefficient (Ken), Dimensionless Parameter (f), Inlet Length (L) & Hydraulic Radius (rH). With our tool, you need to enter the respective value for Inlet Impedance, Entrance Energy Loss Coefficient, Dimensionless Parameter, Inlet Length & Hydraulic Radius and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
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