Velocity for Work Done if there is no Loss of Energy Calculator

✖Work done by/on a system is energy transferred by/to the system to/from its surroundings.ⓘ Work Done [w]			+10% -10%
✖Specific Gravity of Fluid is the ratio of the specific weight of a substance to the specific weight of a standard fluid.ⓘ Specific Gravity of Fluid [G]			+10% -10%
✖Weight of Fluid is the weight of fluid in Newtons or Kilo newton.ⓘ Weight of Fluid [w_f]			+10% -10%
✖Velocity of Jet can be described as the movement of the plate in meters per second.ⓘ Velocity of Jet [v]			+10% -10%

✖The Final Velocity is the speed of a moving body after it has reached its maximum acceleration.ⓘ Velocity for Work Done if there is no Loss of Energy [v_f]

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Formula

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Velocity for Work Done if there is no Loss of Energy

Formula

`"v"_{"f"} = sqrt((("w"*2*"G")/"w"_{"f"})+"v"^2)`

Example

`"80.02859m/s"=sqrt((("3.9KJ"*2*"10")/"12.36N")+("9.69m/s")^2)`

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Velocity for Work Done if there is no Loss of Energy Solution

STEP 0: Pre-Calculation Summary

Formula Used

Final Velocity = sqrt(((Work Done*2*Specific Gravity of Fluid)/Weight of Fluid)+Velocity of Jet^2)
v_f = sqrt(((w*2*G)/w_f)+v^2)
This formula uses 1 Functions, 5 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

Final Velocity - (Measured in Meter per Second) - The Final Velocity is the speed of a moving body after it has reached its maximum acceleration.
Work Done - (Measured in Joule) - Work done by/on a system is energy transferred by/to the system to/from its surroundings.
Specific Gravity of Fluid - Specific Gravity of Fluid is the ratio of the specific weight of a substance to the specific weight of a standard fluid.
Weight of Fluid - (Measured in Newton) - Weight of Fluid is the weight of fluid in Newtons or Kilo newton.
Velocity of Jet - (Measured in Meter per Second) - Velocity of Jet can be described as the movement of the plate in meters per second.

STEP 1: Convert Input(s) to Base Unit

Work Done: 3.9 Kilojoule --> 3900 Joule (Check conversion here)
Specific Gravity of Fluid: 10 --> No Conversion Required
Weight of Fluid: 12.36 Newton --> 12.36 Newton No Conversion Required
Velocity of Jet: 9.69 Meter per Second --> 9.69 Meter per Second No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

v_f = sqrt(((w*2*G)/w_f)+v^2) --> sqrt(((3900*2*10)/12.36)+9.69^2)

Evaluating ... ...

v_f = 80.0285930880363

STEP 3: Convert Result to Output's Unit

80.0285930880363 Meter per Second --> No Conversion Required

FINAL ANSWER

80.0285930880363 ≈ 80.02859 Meter per Second <-- Final Velocity

(Calculation completed in 00.004 seconds)

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< 21 Torque Exerted on a Wheel with Radial Curved Vanes Calculators

Radius at Outlet for Work Done on Wheel per Second

Go Radius of Outlet = (((Work Done*Specific Gravity of Fluid)/(Weight of Fluid*Angular Velocity))-(Final Velocity*Radius of wheel))/Velocity of Jet

Radius at Inlet for Work Done on Wheel per Second

Go Radius of wheel = (((Work Done*Specific Gravity of Fluid)/(Weight of Fluid*Angular Velocity))-(Velocity of Jet*Radius of Outlet))/Final Velocity

Angular Velocity for Work Done on Wheel per Second

Go Angular Velocity = (Work Done*Specific Gravity of Fluid)/(Weight of Fluid*(Final Velocity*Radius of wheel+Velocity of Jet*Radius of Outlet))

Radius at Outlet for Torque Exerted by Fluid

Go Radius of Outlet = (((Torque Exerted on Wheel*Specific Gravity of Fluid)/Weight of Fluid)-(Final Velocity*Radius of wheel))/Velocity of Jet

Radius at Inlet with Known Torque by Fluid

Go Radius of wheel = (((Torque Exerted on Wheel*Specific Gravity of Fluid)/Weight of Fluid)+(Velocity of Jet*Radius of Outlet))/Final Velocity

Torque Exerted by Fluid

Go Torque Exerted on Wheel = (Weight of Fluid/Specific Gravity of Fluid)*(Final Velocity*Radius of wheel+Velocity of Jet*Radius of Outlet)

Initial Velocity for Work Done if Jet leaves in Motion of Wheel

Go Initial Velocity = (((Power Delivered*Specific Gravity of Fluid)/Weight of Fluid)+(Velocity of Jet*Final Velocity))/Final Velocity

Power Delivered to Wheel

Go Power Delivered = (Weight of Fluid/Specific Gravity of Fluid)*(Final Velocity*Initial Velocity+Velocity of Jet*Final Velocity)

Initial Velocity given Power Delivered to Wheel

Go Initial Velocity = (((Power Delivered*Specific Gravity of Fluid)/(Weight of Fluid*Final Velocity))-(Velocity of Jet))

Velocity for Work Done if there is no Loss of Energy

Go Final Velocity = sqrt(((Work Done*2*Specific Gravity of Fluid)/Weight of Fluid)+Velocity of Jet^2)

Velocity given Angular Momentum at Outlet

Go Velocity of Jet = (Tangential Momentum*Specific Gravity of Fluid)/(Weight of Fluid*Radius of wheel)

Angular Momentum at Outlet

Go Angular Momentum = ((Weight of Fluid*Velocity of Jet)/Specific Gravity of Fluid)*Radius of wheel

Velocity given Angular Momentum at Inlet

Go Final Velocity = (Angular Momentum*Specific Gravity of Fluid)/(Weight of Fluid*Radius of wheel)

Angular Momentum at Inlet

Go Angular Momentum = ((Weight of Fluid*Final Velocity)/Specific Gravity of Fluid)*Radius of wheel

Initial Velocity when Work Done at Vane Angle is 90 and Velocity is Zero

Go Initial Velocity = (Work Done*Specific Gravity of Fluid)/(Weight of Fluid*Final Velocity)

Speed of Wheel given Tangential Velocity at Outlet Tip of Vane

Go Angular Speed = (Tangential Velocity*60)/(2*pi*Radius of Outlet)

Speed of Wheel given Tangential Velocity at Inlet Tip of Vane

Go Angular Speed = (Tangential Velocity*60)/(2*pi*Radius of wheel)

Velocity at Point given Efficiency of System

Go Velocity of Jet = sqrt(1-Efficiency of Jet)*Final Velocity

Velocity given Efficiency of System

Go Final Velocity = Velocity of Jet/sqrt(1-Efficiency of Jet)

Efficiency of System

Go Efficiency of Jet = (1-(Velocity of Jet/Final Velocity)^2)

Mass of Fluid Striking Vane per Second

Go Fluid Mass = Weight of Fluid/Specific Gravity of Fluid

Velocity for Work Done if there is no Loss of Energy Formula

Final Velocity = sqrt(((Work Done*2*Specific Gravity of Fluid)/Weight of Fluid)+Velocity of Jet^2)
v_f = sqrt(((w*2*G)/w_f)+v^2)

What is meant by Work Done?

The Work Done if there is no Loss of Energy is the quantity of energy transferred by the force to move an object is termed as work done.

How to Calculate Velocity for Work Done if there is no Loss of Energy?

Velocity for Work Done if there is no Loss of Energy calculator uses Final Velocity = sqrt(((Work Done*2*Specific Gravity of Fluid)/Weight of Fluid)+Velocity of Jet^2) to calculate the Final Velocity, The Velocity for Work Done if there is no Loss of Energy is the rate of change of its position with respect to a frame of reference, and is a function of time. Final Velocity is denoted by v_f symbol.

How to calculate Velocity for Work Done if there is no Loss of Energy using this online calculator? To use this online calculator for Velocity for Work Done if there is no Loss of Energy, enter Work Done (w), Specific Gravity of Fluid (G), Weight of Fluid (w_f) & Velocity of Jet (v) and hit the calculate button. Here is how the Velocity for Work Done if there is no Loss of Energy calculation can be explained with given input values -> 80.02859 = sqrt(((3900*2*10)/12.36)+9.69^2).

FAQ

What is Velocity for Work Done if there is no Loss of Energy?

The Velocity for Work Done if there is no Loss of Energy is the rate of change of its position with respect to a frame of reference, and is a function of time and is represented as v_f = sqrt(((w*2*G)/w_f)+v^2) or Final Velocity = sqrt(((Work Done*2*Specific Gravity of Fluid)/Weight of Fluid)+Velocity of Jet^2). Work done by/on a system is energy transferred by/to the system to/from its surroundings, Specific Gravity of Fluid is the ratio of the specific weight of a substance to the specific weight of a standard fluid, Weight of Fluid is the weight of fluid in Newtons or Kilo newton & Velocity of Jet can be described as the movement of the plate in meters per second.

How to calculate Velocity for Work Done if there is no Loss of Energy?

The Velocity for Work Done if there is no Loss of Energy is the rate of change of its position with respect to a frame of reference, and is a function of time is calculated using Final Velocity = sqrt(((Work Done*2*Specific Gravity of Fluid)/Weight of Fluid)+Velocity of Jet^2). To calculate Velocity for Work Done if there is no Loss of Energy, you need Work Done (w), Specific Gravity of Fluid (G), Weight of Fluid (w_f) & Velocity of Jet (v). With our tool, you need to enter the respective value for Work Done, Specific Gravity of Fluid, Weight of Fluid & Velocity of Jet 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 Final Velocity?

In this formula, Final Velocity uses Work Done, Specific Gravity of Fluid, Weight of Fluid & Velocity of Jet. We can use 2 other way(s) to calculate the same, which is/are as follows -

Final Velocity = (Angular Momentum*Specific Gravity of Fluid)/(Weight of Fluid*Radius of wheel)
Final Velocity = Velocity of Jet/sqrt(1-Efficiency of Jet)

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