Coefficient of Discharge for Time Required to Lower Liquid Surface Solution

STEP 0: Pre-Calculation Summary
Formula Used
Coefficient of Discharge = ((2*Cross-Sectional Area of Reservoir)/((2/3)*Time Interval*sqrt(2*Acceleration due to Gravity)*Length of Weir Crest))*(1/sqrt(Head on Downstream of Weir)-1/sqrt(Head on Upstream of Weir))
Cd = ((2*AR)/((2/3)*Δt*sqrt(2*g)*Lw))*(1/sqrt(h2)-1/sqrt(HUpstream))
This formula uses 1 Functions, 7 Variables
Functions Used
sqrt - A square root function is a function that takes a non-negative number as an input and returns the square root of the given input number., sqrt(Number)
Variables Used
Coefficient of Discharge - Coefficient of Discharge is ratio of Actual discharge to theoretical discharge.
Cross-Sectional Area of Reservoir - (Measured in Square Meter) - Cross-Sectional Area of Reservoir is the area of a reservoir that is obtained when a three-dimensional reservoir shape is sliced perpendicular to some specified axis at a point.
Time Interval - (Measured in Second) - Time interval is the time duration between two events/entities of interest.
Acceleration due to Gravity - (Measured in Meter per Square Second) - The Acceleration due to Gravity is acceleration gained by an object because of gravitational force.
Length of Weir Crest - (Measured in Meter) - Length of Weir Crest is the measurement or extent of Weir Crest from end to end.
Head on Downstream of Weir - (Measured in Meter) - Head on Downstream of Weir pertains to the energy status of water in water flow systems and is useful for describing flow in hydraulic structures.
Head on Upstream of Weir - (Measured in Meter) - Head on Upstream of Weirr pertains to the energy status of water in water flow systems and is useful for describing flow in hydraulic structures.
STEP 1: Convert Input(s) to Base Unit
Cross-Sectional Area of Reservoir: 13 Square Meter --> 13 Square Meter No Conversion Required
Time Interval: 1.25 Second --> 1.25 Second No Conversion Required
Acceleration due to Gravity: 9.8 Meter per Square Second --> 9.8 Meter per Square Second No Conversion Required
Length of Weir Crest: 3 Meter --> 3 Meter No Conversion Required
Head on Downstream of Weir: 5.1 Meter --> 5.1 Meter No Conversion Required
Head on Upstream of Weir: 10.1 Meter --> 10.1 Meter No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Cd = ((2*AR)/((2/3)*Δt*sqrt(2*g)*Lw))*(1/sqrt(h2)-1/sqrt(HUpstream)) --> ((2*13)/((2/3)*1.25*sqrt(2*9.8)*3))*(1/sqrt(5.1)-1/sqrt(10.1))
Evaluating ... ...
Cd = 0.301037578264815
STEP 3: Convert Result to Output's Unit
0.301037578264815 --> No Conversion Required
FINAL ANSWER
0.301037578264815 0.301038 <-- Coefficient of Discharge
(Calculation completed in 00.020 seconds)

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National Institute of Technology (NIT), Warangal
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19 Time Required to Empty a Reservoir with Rectangular Weir Calculators

Coefficient of Discharge for Time Required to Lower Liquid Surface
Go Coefficient of Discharge = ((2*Cross-Sectional Area of Reservoir)/((2/3)*Time Interval*sqrt(2*Acceleration due to Gravity)*Length of Weir Crest))*(1/sqrt(Head on Downstream of Weir)-1/sqrt(Head on Upstream of Weir))
Cross Sectional Area given Time required to Lower Liquid Surface
Go Cross-Sectional Area of Reservoir = (Time Interval*(2/3)*Coefficient of Discharge* sqrt(2*Acceleration due to Gravity)*Length of Weir Crest)/(2*(1/sqrt(Head on Downstream of Weir)-1/sqrt(Head on Upstream of Weir)))
Length of Crest for time required to Lower Liquid Surface
Go Length of Weir Crest = ((2*Cross-Sectional Area of Reservoir)/((2/3)*Coefficient of Discharge*sqrt(2*Acceleration due to Gravity)*Time Interval))*(1/sqrt(Head on Downstream of Weir)-1/sqrt(Head on Upstream of Weir))
Time Required to Lower Liquid Surface
Go Time Interval = ((2*Cross-Sectional Area of Reservoir)/((2/3)*Coefficient of Discharge*sqrt(2*Acceleration due to Gravity)*Length of Weir Crest))*(1/sqrt(Head on Downstream of Weir)-1/sqrt(Head on Upstream of Weir))
Head given Time Required to Lower Liquid Surface using Francis Formula
Go Average Height of Downstream and Upstream = (((2*Cross-Sectional Area of Reservoir)/(1.84*Time Interval for Francis))*(1/sqrt(Head on Downstream of Weir)-1/sqrt(Head on Upstream of Weir))-Length of Weir Crest)/(-0.1*Number of End Contraction)
Length of Crest given Time Required to Lower Liquid Surface using Francis Formula
Go Length of Weir Crest = (((2*Cross-Sectional Area of Reservoir)/(1.84*Time Interval for Francis))*(1/sqrt(Head on Downstream of Weir)-1/sqrt(Head on Upstream of Weir)))+(0.1*Number of End Contraction*Average Height of Downstream and Upstream)
Time Required to Lower Liquid Surface using Francis Formula
Go Time Interval for Francis = ((2*Cross-Sectional Area of Reservoir)/(1.84*(Length of Weir Crest-(0.1*Number of End Contraction*Average Height of Downstream and Upstream))))*(1/sqrt(Head on Downstream of Weir)-1/sqrt(Head on Upstream of Weir))
Head1 given Time Required to Lower Liquid for Triangular Notch
Go Head on Upstream of Weir = (1/((1/Head on Downstream of Weir^(3/2))-((Time Interval*(8/15)*Coefficient of Discharge* sqrt(2*Acceleration due to Gravity)*tan(Theta/2))/((2/3)*Cross-Sectional Area of Reservoir))))^(2/3)
Head1 given Time Required to Lower Liquid Surface
Go Head on Upstream of Weir = ((1/((1/sqrt(Head on Downstream of Weir))-(Time Interval*(2/3)*Coefficient of Discharge* sqrt(2*Acceleration due to Gravity)*Length of Weir Crest)/(2*Cross-Sectional Area of Reservoir)))^2)
Coefficient of Discharge given Time required to Lower Liquid for Triangular Notch
Go Coefficient of Discharge = (((2/3)*Cross-Sectional Area of Reservoir)/((8/15)*Time Interval*sqrt(2*Acceleration due to Gravity)*tan(Theta/2)))*((1/Head on Downstream of Weir^(3/2))-(1/Head on Upstream of Weir^(3/2)))
Cross Sectional Area given Time required to Lower Liquid for Triangular Notch
Go Cross-Sectional Area of Reservoir = (Time Interval*(8/15)*Coefficient of Discharge* sqrt(2*Acceleration due to Gravity)*tan(Theta/2))/((2/3)*((1/Head on Downstream of Weir^(3/2))-(1/Head on Upstream of Weir^(3/2))))
Head2 given Time Required to Lower Liquid for Triangular Notch
Go Head on Downstream of Weir = (1/(((Time Interval*(8/15)*Coefficient of Discharge* sqrt(2*Acceleration due to Gravity)*tan(Theta/2))/((2/3)*Cross-Sectional Area of Reservoir))+(1/Head on Upstream of Weir^(3/2))))^(2/3)
Time Required to Lower Liquid Surface for Triangular Notch
Go Time Interval = (((2/3)*Cross-Sectional Area of Reservoir)/((8/15)*Coefficient of Discharge*sqrt(2*Acceleration due to Gravity)*tan(Theta/2)))*((1/Head on Downstream of Weir^(3/2))-(1/Head on Upstream of Weir^(3/2)))
Head2 given Time Required to Lower Liquid Surface
Go Head on Downstream of Weir = (1/((Time Interval*(2/3)*Coefficient of Discharge* sqrt(2*Acceleration due to Gravity)*Length of Weir Crest)/(2*Cross-Sectional Area of Reservoir)+(1/sqrt(Head on Upstream of Weir))))^2
Cross Sectional Area given time required to Lower Liquid Surface using Bazins Formula
Go Cross-Sectional Area of Reservoir = (Time Interval*Bazins Coefficient*sqrt(2*Acceleration due to Gravity))/((1/sqrt(Head on Downstream of Weir)-1/sqrt(Head on Upstream of Weir))*2)
Bazins Constant given Time Required to Lower Liquid Surface
Go Bazins Coefficient = ((2*Cross-Sectional Area of Reservoir)/(Time Interval*sqrt(2*Acceleration due to Gravity)))*(1/sqrt(Head on Downstream of Weir)-1/sqrt(Head on Upstream of Weir))
Time Required to Lower Liquid Surface using Bazins Formula
Go Time Interval = ((2*Cross-Sectional Area of Reservoir)/(Bazins Coefficient*sqrt(2*Acceleration due to Gravity)))*(1/sqrt(Head on Downstream of Weir)-1/sqrt(Head on Upstream of Weir))
Head1 given Time Required to Lower Liquid Surface using Bazins Formula
Go Head on Upstream of Weir = ((1/((Time Interval*Bazins Coefficient*sqrt(2*Acceleration due to Gravity))/(2*Cross-Sectional Area of Reservoir)-(1/sqrt(Head on Downstream of Weir))))^2)
Head2 given Time Required to Lower Liquid Surface using Bazins Formula
Go Head on Downstream of Weir = (1/((Time Interval*Bazins Coefficient*sqrt(2*Acceleration due to Gravity))/(2*Cross-Sectional Area of Reservoir)+(1/sqrt(Head on Upstream of Weir))))^2

Coefficient of Discharge for Time Required to Lower Liquid Surface Formula

Coefficient of Discharge = ((2*Cross-Sectional Area of Reservoir)/((2/3)*Time Interval*sqrt(2*Acceleration due to Gravity)*Length of Weir Crest))*(1/sqrt(Head on Downstream of Weir)-1/sqrt(Head on Upstream of Weir))
Cd = ((2*AR)/((2/3)*Δt*sqrt(2*g)*Lw))*(1/sqrt(h2)-1/sqrt(HUpstream))

What is Acceleration due to gravity?

Acceleration due to gravity defines the acceleration which is gained by an object because of gravitational force is called its acceleration due to gravity.

How to Calculate Coefficient of Discharge for Time Required to Lower Liquid Surface?

Coefficient of Discharge for Time Required to Lower Liquid Surface calculator uses Coefficient of Discharge = ((2*Cross-Sectional Area of Reservoir)/((2/3)*Time Interval*sqrt(2*Acceleration due to Gravity)*Length of Weir Crest))*(1/sqrt(Head on Downstream of Weir)-1/sqrt(Head on Upstream of Weir)) to calculate the Coefficient of Discharge, Coefficient of discharge for time required to lower liquid surface is ratio of actual discharge to theoretical discharge, i.e., ratio of mass flow rate at discharge end. Coefficient of Discharge is denoted by Cd symbol.

How to calculate Coefficient of Discharge for Time Required to Lower Liquid Surface using this online calculator? To use this online calculator for Coefficient of Discharge for Time Required to Lower Liquid Surface, enter Cross-Sectional Area of Reservoir (AR), Time Interval (Δt), Acceleration due to Gravity (g), Length of Weir Crest (Lw), Head on Downstream of Weir (h2) & Head on Upstream of Weir (HUpstream) and hit the calculate button. Here is how the Coefficient of Discharge for Time Required to Lower Liquid Surface calculation can be explained with given input values -> 0.301038 = ((2*13)/((2/3)*1.25*sqrt(2*9.8)*3))*(1/sqrt(5.1)-1/sqrt(10.1)) .

FAQ

What is Coefficient of Discharge for Time Required to Lower Liquid Surface?
Coefficient of discharge for time required to lower liquid surface is ratio of actual discharge to theoretical discharge, i.e., ratio of mass flow rate at discharge end and is represented as Cd = ((2*AR)/((2/3)*Δt*sqrt(2*g)*Lw))*(1/sqrt(h2)-1/sqrt(HUpstream)) or Coefficient of Discharge = ((2*Cross-Sectional Area of Reservoir)/((2/3)*Time Interval*sqrt(2*Acceleration due to Gravity)*Length of Weir Crest))*(1/sqrt(Head on Downstream of Weir)-1/sqrt(Head on Upstream of Weir)). Cross-Sectional Area of Reservoir is the area of a reservoir that is obtained when a three-dimensional reservoir shape is sliced perpendicular to some specified axis at a point, Time interval is the time duration between two events/entities of interest, The Acceleration due to Gravity is acceleration gained by an object because of gravitational force, Length of Weir Crest is the measurement or extent of Weir Crest from end to end, Head on Downstream of Weir pertains to the energy status of water in water flow systems and is useful for describing flow in hydraulic structures & Head on Upstream of Weirr pertains to the energy status of water in water flow systems and is useful for describing flow in hydraulic structures.
How to calculate Coefficient of Discharge for Time Required to Lower Liquid Surface?
Coefficient of discharge for time required to lower liquid surface is ratio of actual discharge to theoretical discharge, i.e., ratio of mass flow rate at discharge end is calculated using Coefficient of Discharge = ((2*Cross-Sectional Area of Reservoir)/((2/3)*Time Interval*sqrt(2*Acceleration due to Gravity)*Length of Weir Crest))*(1/sqrt(Head on Downstream of Weir)-1/sqrt(Head on Upstream of Weir)). To calculate Coefficient of Discharge for Time Required to Lower Liquid Surface, you need Cross-Sectional Area of Reservoir (AR), Time Interval (Δt), Acceleration due to Gravity (g), Length of Weir Crest (Lw), Head on Downstream of Weir (h2) & Head on Upstream of Weir (HUpstream). With our tool, you need to enter the respective value for Cross-Sectional Area of Reservoir, Time Interval, Acceleration due to Gravity, Length of Weir Crest, Head on Downstream of Weir & Head on Upstream of Weir 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 Coefficient of Discharge?
In this formula, Coefficient of Discharge uses Cross-Sectional Area of Reservoir, Time Interval, Acceleration due to Gravity, Length of Weir Crest, Head on Downstream of Weir & Head on Upstream of Weir. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Coefficient of Discharge = (((2/3)*Cross-Sectional Area of Reservoir)/((8/15)*Time Interval*sqrt(2*Acceleration due to Gravity)*tan(Theta/2)))*((1/Head on Downstream of Weir^(3/2))-(1/Head on Upstream of Weir^(3/2)))
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