Sagar S Kulkarni
Dayananda Sagar College of Engineering (DSCE), Bengaluru
Sagar S Kulkarni has created this Calculator and 200+ more calculators!
Vaibhav Malani
National Institute of Technology (NIT), Tiruchirapalli
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11 Other formulas that you can solve using the same Inputs

Variation of acceleration due to gravity effect on the surface of earth
Variation of acceleration due to gravity=Acceleration Due To Gravity*(1-[Earth-R]*Angular Velocity/Acceleration Due To Gravity) GO
Angular Displacement if initial angular velocity, angular acceleration and time are given
Angular Displacement=(Angular Velocity*Time Taken to Travel)+((Angular Acceleration*(Time Taken to Travel)^2)/2) GO
Angular Displacement of body when initial and final angular velocity and angular acceleration are given
Angular Displacement=((Final Angular Velocity)^2-(Angular Velocity)^2)/(2*Angular Acceleration) GO
Angular Displacement if initial angular velocity, final angular velocity and time are given
Angular Displacement=((Angular Velocity+Final Angular Velocity)*Time Taken to Travel)/2 GO
Final Angular Velocity if initial angular velocity, angular acceleration and time is given
Final Angular Velocity=Angular Velocity+(Angular Acceleration*Time Taken to Travel) GO
angle traced in nth second( accelerated rotatory motion)
Angular Displacement=Angular Velocity+((Angular Acceleration*(2*Nth Second -1))/2) GO
Time Period for Alternating Current
Time Period Of Progressive Wave=(2*pi)/Angular Velocity GO
Capacitive Reactance
capacitive reactance=1/(Angular Velocity*Capacitance) GO
Angular Momentum
Angular Momentum=Moment of Inertia*Angular Velocity GO
Inductive Reactance
Inductive reactance=Angular Velocity*Inductance GO
Torque Of Series DC Generator Using Input Power
Torque=Input Power/Angular Velocity GO

Impeller radius at inlet given inlet tangential velocity Formula

Radius of impeller at inlet=Tangential velocity of impeller at inlet/Angular Velocity
R<sub>1</sub>=u<sub>1</sub>/ω
More formulas
Angular velocity GO
Tangential velocity of the impeller at inlet GO
Tangential velocity of impeller at outlet GO
Torque at outlet GO
Work done per second GO
Work done per second in terms of torque and angular velocity GO
Work done per second per unit weight of liquid GO
Work done per second if the flow at inlet is not radial GO
Work done per second per unit weight of liquid if the flow at inlet is not radial GO
Volume of liquid at inlet GO
Weight of liquid GO
Static head GO
Manometric head in terms of static head and losses in pipes GO
Manometric head in terms of head imparted by the impeller and loss of head in the pump GO
Manometric head in terms of total head at outlet and inlet of the pump GO
Manometric efficiency GO
Manometric efficiency in terms of velocities GO
Tangential velocity of the impeller at inlet in terms of angular velocity and impeller radius GO
Tangential velocity of the impeller at outlet in terms of angular velocity and impeller radius GO
Impeller radius at outlet given outlet tangential velocity GO
Volume of liquid at outlet GO
Manometric head in terms of static head, friction losses in suction and delivery pipes GO
Manometric head in terms of head imparted by the impeller if loss of head in the pump is zero GO
Volumetric efficiency GO
Mechanical efficiency GO
Overall efficiency in terms of manometric, volumetric and mechanical efficiencies GO
Minimum speed for starting a centrifugal pump GO
vane efficiency GO
Flow ratio GO
Tangential velocity given speed ratio GO
Flow velocity given flow ratio GO
Flow velocity at inlet given volume of liquid GO
Flow velocity at outlet given volume of liquid GO
Impeller power GO
Output power GO
Static power GO
Outlet diameter of impeller in terms of speed ratio, manometric head and impeller speed GO
Manometric head given outlet impeller diameter, impeller speed and speed ratio GO
Least diameter of impeller GO
Diameter of suction pipe GO
Diameter of delivery pipe GO
Leakage of liquid given volumetric efficiency and discharge GO
Overall efficiency GO
Thoma's cavitation factor GO
Net positive suction head GO
Suction specific speed GO
Thoma's cavitation factor in terms of net positive suction head GO

What is tangential velocity?

Tangential velocity is the linear speed of any object moving along a circular path. In this case the inlet pipe is axial and therefore fluid enters the impeller with very little whirl or tangential component of velocity and flows outwards in the direction of the blades.

How to Calculate Impeller radius at inlet given inlet tangential velocity?

Impeller radius at inlet given inlet tangential velocity calculator uses Radius of impeller at inlet=Tangential velocity of impeller at inlet/Angular Velocity to calculate the Radius of impeller at inlet, The Impeller radius at inlet given inlet tangential velocity formula is defined as the ratio of tangential velocity of impeller at inlet and angular velocity. Radius of impeller at inlet and is denoted by R1 symbol.

How to calculate Impeller radius at inlet given inlet tangential velocity using this online calculator? To use this online calculator for Impeller radius at inlet given inlet tangential velocity, enter Tangential velocity of impeller at inlet (u1) and Angular Velocity (ω) and hit the calculate button. Here is how the Impeller radius at inlet given inlet tangential velocity calculation can be explained with given input values -> 0.5 = 10/20.

FAQ

What is Impeller radius at inlet given inlet tangential velocity?
The Impeller radius at inlet given inlet tangential velocity formula is defined as the ratio of tangential velocity of impeller at inlet and angular velocity and is represented as R1=u1 or Radius of impeller at inlet=Tangential velocity of impeller at inlet/Angular Velocity. Tangential velocity of impeller at inlet is the velocity at the inlet of fluid flow and The angular velocity refers to how fast an object rotates or revolves relative to another point, i.e. how fast the angular position or orientation of an object changes with time.
How to calculate Impeller radius at inlet given inlet tangential velocity?
The Impeller radius at inlet given inlet tangential velocity formula is defined as the ratio of tangential velocity of impeller at inlet and angular velocity is calculated using Radius of impeller at inlet=Tangential velocity of impeller at inlet/Angular Velocity. To calculate Impeller radius at inlet given inlet tangential velocity, you need Tangential velocity of impeller at inlet (u1) and Angular Velocity (ω). With our tool, you need to enter the respective value for Tangential velocity of impeller at inlet and Angular Velocity 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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