Discharge through pipe for power required and head loss in turbulent flow Calculator

Category	Physics ↺
Physics	Fluid Mechanics ↺
Fluid-Mechanics	Turbulent flow ↺

✖Power is the amount of energy liberated per second in a device.ⓘ Power [P]			+10% -10%
✖The density of fluid is the mass per unit volume considered in the relation falling resistance method.ⓘ density of fluid [ρ _f]			+10% -10%
✖The head loss due to friction occurs due to the effect of the fluid's viscosity near the surface of the pipe or duct.ⓘ head loss due to friction [h _f]			+10% -10%

✖Discharge is the rate of flow of a liquidⓘ Discharge through pipe for power required and head loss in turbulent flow [Q]

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Discharge through pipe for power required and head loss in turbulent flow

Maiarutselvan V

PSG College of Technology (PSGCT), Coimbatore

Maiarutselvan V has created this Calculator and 200+ more calculators!

Vinay Mishra

Indian Institute for Aeronautical Engineering and Information Technology (IIAEIT), Pune

Vinay Mishra has verified this Calculator and 100+ more calculators!

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

Torque transmitted if power is known for epicyclic-train dynamometer

Torque=(Power*60)/(2*pi* Speed of the shaft in rpm) GO

Indicated Thermal Efficiency

indicated thermal efficiency=Power/Energy Required GO

Brake Thermal Efficiency

brake thermal efficiency=Power/Energy Required GO

Voltage When The Power Factor Is Given

Voltage=Power/(Power Factor*Electric Current) GO

Current When The Power Factor Is Given

Electric Current=Power/(Power Factor*Voltage) GO

Power Factor When Power Is Given

Power Factor=Power/(Voltage*Electric Current) GO

Armature Current When Power Is Given

Armature Current=Power/Induced voltage GO

Induced Voltage When Power Is Given

Induced voltage=Power/Armature Current GO

Force By A Linear Induction Motor

Force=Power/Linear Synchronous Speed GO

Intensity Of Sound

Resultant Intensity=Power*Area GO

Angular Speed Of Series DC Generator Using Generated Power

Angular Speed=Power/Torque GO

< 11 Other formulas that calculate the same Output

Discharge with velocity of approach

Discharge=(2/3)*coefficient of discharging*Length*sqrt(2*[g])*(((initial height of liquid+final height of liquid)^1.5)-(final height of liquid^1.5)) GO

Discharge over a broad-crested weir for head of liquid at middle

Discharge=coefficient of discharging*Length*sqrt((2*[g])*((head of the liquid*head of liquid middle^2)-(head of liquid middle^3))) GO

Discharge over rectangle weir for Bazin's formula with velocity approach

Discharge=(0.405+(0.003/(head of the liquid+head due to Va)))*Length*sqrt(2*[g])*((head of the liquid+head due to Va)^1.5) GO

Discharge over rectangle weir with two end contractions

Discharge=(2/3)*coefficient of discharging*(Length-(0.2*head of the liquid))*sqrt(2*[g])*(head of the liquid^1.5) GO

Discharge over rectangle weir considering Francis's formula

Discharge=1.84*Length*(((initial height of liquid+final height of liquid)^1.5)-(final height of liquid^1.5)) GO

Discharge from Manning's equation

Discharge=(1/Manning’s Roughness Coefficient)*Cross sectional area*hydraulic radius^2/3*Bed Slope^1/2 GO

Discharge without velocity of approach

Discharge=(2/3)*coefficient of discharging*Length*sqrt(2*[g])*(initial height of liquid^1.5) GO

Discharge over rectangle weir considering Bazin's formula

Discharge=(0.405+(0.003/head of the liquid))*Length*sqrt(2*[g])*((head of the liquid)^1.5) GO

Discharge over a broad-crested weir

Discharge=1.705*coefficient of discharging*Length*(head of the liquid^1.5) GO

Discharge during retraction

Discharge=Velocity*(Area of piston-Area of piston rod) GO

Discharge during extension

Discharge=Velocity*Area of piston GO

Discharge through pipe for power required and head loss in turbulent flow Formula

Discharge=(Power*1000)/(density of fluid*[g]*head loss due to friction)
Q=(P*1000)/(ρ <sub>f</sub>*[g]*h <sub>f</sub>)

More formulas

Shear velocity for turbulent flow in pipes GO

Shear stress developed for turbulent flow in pipes GO

Roughness Reynold number for turbulent flow in pipes GO

Average height of irregularities for turbulent flow in pipes GO

Power required to maintain the turbulent flow GO

Head loss due to friction for power required and discharge in turbulent flow GO

What is head loss due to friction?

Head loss is potential energy that is converted to kinetic energy. Head losses are due to the frictional resistance of the piping system (pipes, valves, fittings, entrance, and exit losses). Unlike the velocity head, the friction head cannot be ignored in system calculations. Values vary as the square of the flow rate.

What is turbulent flow?

The turbulence or turbulent flow is fluid motion characterized by chaotic changes in pressure and flow velocity. It is in contrast to a laminar flow, which occurs when a fluid flows in parallel layers, with no disruption between those layers.

How to Calculate Discharge through pipe for power required and head loss in turbulent flow?

Discharge through pipe for power required and head loss in turbulent flow calculator uses Discharge=(Power*1000)/(density of fluid*[g]*head loss due to friction) to calculate the Discharge, The Discharge through pipe for power required and head loss in turbulent flow formula is known while considering the density of the fluid, head loss due to friction, and the power required to maintain the flow. Discharge and is denoted by Q symbol.

How to calculate Discharge through pipe for power required and head loss in turbulent flow using this online calculator? To use this online calculator for Discharge through pipe for power required and head loss in turbulent flow, enter Power (P), density of fluid (ρ _f) and head loss due to friction (h _f) and hit the calculate button. Here is how the Discharge through pipe for power required and head loss in turbulent flow calculation can be explained with given input values -> 101.9716 = (100*1000)/(10*[g]*10).

FAQ

What is Discharge through pipe for power required and head loss in turbulent flow?

The Discharge through pipe for power required and head loss in turbulent flow formula is known while considering the density of the fluid, head loss due to friction, and the power required to maintain the flow and is represented as Q=(P*1000)/(ρ _f*[g]*h _f) or Discharge=(Power*1000)/(density of fluid*[g]*head loss due to friction). Power is the amount of energy liberated per second in a device, The density of fluid is the mass per unit volume considered in the relation falling resistance method and The head loss due to friction occurs due to the effect of the fluid's viscosity near the surface of the pipe or duct.

How to calculate Discharge through pipe for power required and head loss in turbulent flow?

The Discharge through pipe for power required and head loss in turbulent flow formula is known while considering the density of the fluid, head loss due to friction, and the power required to maintain the flow is calculated using Discharge=(Power*1000)/(density of fluid*[g]*head loss due to friction). To calculate Discharge through pipe for power required and head loss in turbulent flow, you need Power (P), density of fluid (ρ _f) and head loss due to friction (h _f). With our tool, you need to enter the respective value for Power, density of fluid and head loss due to friction 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 Discharge?

In this formula, Discharge uses Power, density of fluid and head loss due to friction. We can use 11 other way(s) to calculate the same, which is/are as follows -

Discharge=Velocity*Area of piston
Discharge=Velocity*(Area of piston-Area of piston rod)
Discharge=(2/3)*coefficient of discharging*Length*sqrt(2*[g])*(((initial height of liquid+final height of liquid)^1.5)-(final height of liquid^1.5))
Discharge=(2/3)*coefficient of discharging*Length*sqrt(2*[g])*(initial height of liquid^1.5)
Discharge=(1/Manning’s Roughness Coefficient)*Cross sectional area*hydraulic radius^2/3*Bed Slope^1/2
Discharge=1.84*Length*(((initial height of liquid+final height of liquid)^1.5)-(final height of liquid^1.5))
Discharge=(0.405+(0.003/head of the liquid))*Length*sqrt(2*[g])*((head of the liquid)^1.5)
Discharge=(0.405+(0.003/(head of the liquid+head due to Va)))*Length*sqrt(2*[g])*((head of the liquid+head due to Va)^1.5)
Discharge=(2/3)*coefficient of discharging*(Length-(0.2*head of the liquid))*sqrt(2*[g])*(head of the liquid^1.5)
Discharge=1.705*coefficient of discharging*Length*(head of the liquid^1.5)
Discharge=coefficient of discharging*Length*sqrt((2*[g])*((head of the liquid*head of liquid middle^2)-(head of liquid middle^3)))

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