Sagar S Kulkarni
Dayananda Sagar College of Engineering (DSCE), Bengaluru
Sagar S Kulkarni has created this Calculator and 100+ more calculators!
Chilvera Bhanu Teja
Institute of Aeronautical Engineering (IARE), Hyderabad
Chilvera Bhanu Teja has verified this Calculator and 100+ more calculators!

9 Other formulas that you can solve using the same Inputs

The Actual Fall at a Stage when Actual Discharge is Given
Actual Fall=((actual discharge*Normalized Value of the Fall^Exponent on Rating Curve with a value close to 0.5)/Normalized Discharge)^1/Exponent on Rating Curve with a value close to 0.5 GO
Normalized Value of the Fall when Discharge is Given
Normalized Value of the Fall=((Normalized Discharge*Actual Fall^Exponent on Rating Curve with a value close to 0.5)/actual discharge)^1/Exponent on Rating Curve with a value close to 0.5 GO
Normalized Discharge of Backwater Effect on a Rating Curve-Normalized Curve
Normalized Discharge=(actual discharge*Normalized Value of the Fall^Exponent on Rating Curve with a value close to 0.5)/Actual Fall^Exponent on Rating Curve with a value close to 0.5 GO
Volumetric efficiency
Volumetric efficiency of a motor=(theoretical discharge/actual discharge)*100 GO
Volumetric efficiency
Volumetric efficiency of a pump=(actual discharge/theoretical discharge)*100 GO
Actual discharge given volumetric efficiency(%)
actual discharge=(theoretical discharge*100)/volumetric efficiency GO
Co-efficient of discharge
coefficient of discharging=actual discharge/theoretical discharge GO
co-efficient of discharge (Cd) of the pump.
Coefficient of Discharge =actual discharge/theoretical discharge GO
slip of the pump
Pump slippage=theoretical discharge-actual discharge GO

4 Other formulas that calculate the same Output

Discharge over a trapezoidal notch or weir
theoretical discharge=((2/3)*coefficient of discharge rectangular*Length*sqrt(2*[g])*(head of the liquid^1.5))+((8/15)*coefficient of discharge triangular*(tan(Angle A/2))*sqrt(2*[g])*(head of the liquid^2.5)) GO
Discharge over a triangular notch or weir
theoretical discharge=(8/15)*coefficient of discharging*(tan(Angle A/2))*sqrt(2*[g])*(head of the liquid^2.5) GO
Discharge over rectangle notch or weir
theoretical discharge=(2/3)*coefficient of discharging*Length*sqrt(2*[g])*(head of the liquid^1.5) GO
Theoretical discharge
theoretical discharge=Theoretical volumetric displacement*Angular Speed GO

Theoretical discharge given volumetric efficiency(%) Formula

theoretical discharge=(volumetric efficiency*actual discharge)/100
Q th=(VE*Q)/100
More formulas
Theoretical torque developed GO
Theoretical volumetric displacement given torque and pressure GO
Pressure of the liquid entering the motor GO
Theoretical power GO
Theoretical power in terms of volumetric displacement and pressure GO
Theoretical discharge GO
Volumetric efficiency GO
Actual discharge given volumetric efficiency(%) GO
Mechanical efficiency(%) GO
Actual torque delivered GO
Overall efficiency(%) GO

What is minimum motor speed?

Minimum motor speed is the slowest, continuous, uninterrupted rotational speed available from the motor output shaft.

How to Calculate Theoretical discharge given volumetric efficiency(%)?

Theoretical discharge given volumetric efficiency(%) calculator uses theoretical discharge=(volumetric efficiency*actual discharge)/100 to calculate the theoretical discharge, The Theoretical discharge given volumetric efficiency(%) formula is defined as the product of volumetric efficiency and actual discharge. theoretical discharge and is denoted by Q th symbol.

How to calculate Theoretical discharge given volumetric efficiency(%) using this online calculator? To use this online calculator for Theoretical discharge given volumetric efficiency(%), enter volumetric efficiency (VE) and actual discharge (Q) and hit the calculate button. Here is how the Theoretical discharge given volumetric efficiency(%) calculation can be explained with given input values -> 5.000E-5 = (0.5*0.01)/100.

FAQ

What is Theoretical discharge given volumetric efficiency(%)?
The Theoretical discharge given volumetric efficiency(%) formula is defined as the product of volumetric efficiency and actual discharge and is represented as Q th=(VE*Q)/100 or theoretical discharge=(volumetric efficiency*actual discharge)/100. volumetric efficiency is the ratio of the volume of air/charge drawn into the cylinder/s during the suction stroke to the total displacement of all the cylinder/s at the atmospheric pressure and Actual discharge is given by the actual area and velocity.
How to calculate Theoretical discharge given volumetric efficiency(%)?
The Theoretical discharge given volumetric efficiency(%) formula is defined as the product of volumetric efficiency and actual discharge is calculated using theoretical discharge=(volumetric efficiency*actual discharge)/100. To calculate Theoretical discharge given volumetric efficiency(%), you need volumetric efficiency (VE) and actual discharge (Q). With our tool, you need to enter the respective value for volumetric efficiency and actual discharge 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 theoretical discharge?
In this formula, theoretical discharge uses volumetric efficiency and actual discharge. We can use 4 other way(s) to calculate the same, which is/are as follows -
  • theoretical discharge=(2/3)*coefficient of discharging*Length*sqrt(2*[g])*(head of the liquid^1.5)
  • theoretical discharge=Theoretical volumetric displacement*Angular Speed
  • theoretical discharge=(8/15)*coefficient of discharging*(tan(Angle A/2))*sqrt(2*[g])*(head of the liquid^2.5)
  • theoretical discharge=((2/3)*coefficient of discharge rectangular*Length*sqrt(2*[g])*(head of the liquid^1.5))+((8/15)*coefficient of discharge triangular*(tan(Angle A/2))*sqrt(2*[g])*(head of the liquid^2.5))
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