Mridul Sharma
Indian Institute of Information Technology (IIIT), Bhopal
Mridul Sharma has created this Calculator and 100+ more calculators!
Rithik Agrawal
National Institute of Technology Karnataka (NITK), Surathkal
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11 Other formulas that you can solve using the same Inputs

Stress at Point y for a Curved Beam
Stress=((Bending Moment )/(Cross sectional area*Radius of Centroidal Axis))*(1+((Distance of Point from Centroidal Axis)/(Cross-Section Property*(Radius of Centroidal Axis+Distance of Point from Centroidal Axis)))) GO
Bending Moment When Stress is Applied at Point y in a Curved Beam
Bending Moment =((Stress*Cross sectional area*Radius of Centroidal Axis)/(1+(Distance of Point from Centroidal Axis/(Cross-Section Property*(Radius of Centroidal Axis+Distance of Point from Centroidal Axis))))) GO
Neutral Axis to Outermost Fiber Distance when Total Unit Stress in Eccentric Loading is Given
Outermost Fiber Distance=(Total Unit Stress-(Axial Load/Cross sectional area))*Moment of Inertia about Neutral Axis/(Axial Load*Distance_from Load Applied) GO
Total Unit Stress in Eccentric Loading
Total Unit Stress=(Axial Load/Cross sectional area)+(Axial Load*Outermost Fiber Distance*Distance_from Load Applied/Moment of Inertia about Neutral Axis) GO
Maximum Bending Moment when Maximum Stress For Short Beams is Given
Maximum Bending Moment=((Maximum stress at crack tip-(Axial Load/Cross sectional area))*Moment of Inertia)/Distance from the Neutral axis GO
Maximum Stress For Short Beams
Maximum stress at crack tip=(Axial Load/Cross sectional area)+((Maximum Bending Moment*Distance from the Neutral axis)/Moment of Inertia) GO
Axial Load when Maximum Stress For Short Beams is Given
Axial Load=Cross sectional area*(Maximum stress at crack tip-(Maximum Bending Moment*Distance from the Neutral axis/Moment of Inertia)) GO
Electric Current when Drift Velocity is Given
Electric Current=Number of free charge particles per unit volume*[Charge-e]*Cross sectional area*Drift Velocity GO
Resistance
Resistance=(Resistivity*Length of Conductor)/Cross sectional area GO
Centrifugal Stress
Centrifugal Stress=2*Tensile Stress*Cross sectional area GO
Rate of Flow
Rate of flow=Cross sectional area*Average Velocity GO

10 Other formulas that calculate the same Output

Velocity of flow at the outlet of the nozzle
flow velocity=sqrt(2*[g]*Total Head at Entrance/(1+(4*Coefficient of Friction*Length of Pipe*(nozzle area at outlet^2)/(Diameter of Pipe*(Cross sectional area of Pipe^2))))) GO
Flow velocity using Manning's formula
flow velocity=(conversion factor*hydraulic radius^(2/3)*energy loss^(1/2))/roughness coefficient of conduit surface GO
Flow Velocity when Power Lost is Given
flow velocity=Absolute Velocity of the Issuing Jet-sqrt((Power Loss/(density of fluid*Rate of flow*0.5))) GO
Full flow velocity in sewer
flow velocity=(0.59*Inner Diameter^(2/3)*energy loss^(1/2))/roughness coefficient of conduit surface GO
Flow Velocity when Thrust on the Propeller is Given
flow velocity=-(Thrust force/(Water Density*Rate of flow))+Absolute Velocity of the Issuing Jet GO
Manning’s Equation
flow velocity=(1/Manning’s Roughness Coefficient)*(hydraulic radius)^2/3*(Bed Slope)^1/2 GO
Flow Velocity when Rate of Flow through Propeller is Given
flow velocity=(8*Rate of flow/(pi*Diameter ^2))-Absolute Velocity of the Issuing Jet GO
Flow Velocity when Theoretical Propulsive Efficiency is Given
flow velocity=Absolute Velocity of the Issuing Jet/(2/Efficiency -1) GO
Velocity of flow at the outlet of the nozzle for efficiency and head
flow velocity=sqrt(Efficiency *2*[g]*Total Head at Entrance) GO
Flow velocity in Continuous Discharge Measurements
flow velocity=0.00198*Water Depth^1.3597 GO

Velocity when water flow equation is given Formula

flow velocity=water flow/Cross sectional area
V=Q/A
More formulas
Flow velocity using Manning's formula GO
Roughness coefficient when flow velocity is given GO
Hydraulic radius when flow velocity is given GO
Energy loss when flow velocity is given GO
Conversion factor when flow velocity is given GO
Water flow equation GO
Area when water flow equation is given GO

What is the difference between flow rate and velocity?

Rate of flow, or simply flow, is the quantity of water, for example, that flows in a tube or other medium, in an interval of time. Examples: 2 kg of water per second, or 100 cubric meters of air per minute. Velocity is how fast the water, air or other fluid is moving in a tube or other medium.

How to Calculate Velocity when water flow equation is given?

Velocity when water flow equation is given calculator uses flow velocity=water flow/Cross sectional area to calculate the flow velocity, The Velocity when water flow equation is given formula calculates the flow velocity when area of cross section of the pipe and water flow are given. flow velocity and is denoted by V symbol.

How to calculate Velocity when water flow equation is given using this online calculator? To use this online calculator for Velocity when water flow equation is given, enter water flow (Q) and Cross sectional area (A) and hit the calculate button. Here is how the Velocity when water flow equation is given calculation can be explained with given input values -> 0.03048 = 0.304800000001219/10.

FAQ

What is Velocity when water flow equation is given?
The Velocity when water flow equation is given formula calculates the flow velocity when area of cross section of the pipe and water flow are given and is represented as V=Q/A or flow velocity=water flow/Cross sectional area. water flow is rate of flow of water and Cross sectional area is the area of a two-dimensional shape that is obtained when a three dimensional shape is sliced perpendicular to some specifies axis at a point.
How to calculate Velocity when water flow equation is given?
The Velocity when water flow equation is given formula calculates the flow velocity when area of cross section of the pipe and water flow are given is calculated using flow velocity=water flow/Cross sectional area. To calculate Velocity when water flow equation is given, you need water flow (Q) and Cross sectional area (A). With our tool, you need to enter the respective value for water flow and Cross sectional area 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 flow velocity?
In this formula, flow velocity uses water flow and Cross sectional area. We can use 10 other way(s) to calculate the same, which is/are as follows -
  • flow velocity=(conversion factor*hydraulic radius^(2/3)*energy loss^(1/2))/roughness coefficient of conduit surface
  • flow velocity=(0.59*Inner Diameter^(2/3)*energy loss^(1/2))/roughness coefficient of conduit surface
  • flow velocity=(1/Manning’s Roughness Coefficient)*(hydraulic radius)^2/3*(Bed Slope)^1/2
  • flow velocity=0.00198*Water Depth^1.3597
  • flow velocity=sqrt(2*[g]*Total Head at Entrance/(1+(4*Coefficient of Friction*Length of Pipe*(nozzle area at outlet^2)/(Diameter of Pipe*(Cross sectional area of Pipe^2)))))
  • flow velocity=sqrt(Efficiency *2*[g]*Total Head at Entrance)
  • flow velocity=-(Thrust force/(Water Density*Rate of flow))+Absolute Velocity of the Issuing Jet
  • flow velocity=(8*Rate of flow/(pi*Diameter ^2))-Absolute Velocity of the Issuing Jet
  • flow velocity=Absolute Velocity of the Issuing Jet-sqrt((Power Loss/(density of fluid*Rate of flow*0.5)))
  • flow velocity=Absolute Velocity of the Issuing Jet/(2/Efficiency -1)
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