Chilvera Bhanu Teja
Institute of Aeronautical Engineering (IARE), Hyderabad
Chilvera Bhanu Teja has created this Calculator and 200+ more calculators!
Anshika Arya
National Institute Of Technology (NIT), Hamirpur
Anshika Arya has verified this Calculator and 400+ more calculators!

11 Other formulas that calculate the same Output

Energy of an electron in an elliptical orbit
Energy=(-((Atomic number^2)*[Mass-e]*([Charge-e]^4))/(8*([Permitivity-vacuum]^2)*([hP]^2)*(Quantum Number^2))) GO
Total energy of electron in nth orbit
Energy=(-([Mass-e]*([Charge-e]^4)*(Atomic number^2))/(8*([Permitivity-vacuum]^2)*(Quantum Number^2)*([hP]^2))) GO
Energy Of A Moving Particle Using Wavelength
Energy=(Plancks Constant*Velocity Of Light in Vacuum)/Wavelength GO
Energy Of A Moving Particle Using Wave Number
Energy=Plancks Constant*Velocity Of Light in Vacuum*Wave Number GO
Kinetic Energy Of A Electron
Energy=-2.178*10^-18*(Atomic number)^2/(Quantum Number)^2 GO
Potential Energy Of Electron
Energy=1.085*10^-18*(Atomic number)^2/(Quantum Number)^2 GO
Total Energy Of Electron
Energy=-1.085*(Atomic number)^2/(Quantum Number)^2 GO
Energy of stationary state of hydrogen
Energy=-([Rydberg])*(1/(Quantum Number^2)) GO
Energy Of A Moving Particle Using Frequency
Energy=Plancks Constant*frequency GO
Energy of particle when de-Broglie wavelength is given
Energy=([hP]*[c])/Wavelength GO
Energy of a particle
Energy=[hP]*frequency GO

Energy transfer due to the change of the relative kinetic energy of the fluid Formula

Energy=(Relative velocity at exit^2-Relative velocity at inlet^2)/2
e=(w<sub>2</sub>^2-w<sub>1</sub>^2)/2
More formulas
Peripheral velocity of the blade at the exit corresponding to diameter GO
Peripheral velocity of the blade at the entry corresponding to diameter GO
Angular moment of momentum at inlet GO
Angular moment of momentum at exit GO
Torque produced GO
Energy transfer due to change of absolute kinetic energy of the fluid GO
Energy transfer due to centrifugal effect GO

What is energy?

Energy is the quantitative property that must be transferred to an object in order to perform work on, or to heat, the object. Energy is a conserved quantity; the law of conservation of energy states that energy can be converted in form, but not created or destroyed.

How to Calculate Energy transfer due to the change of the relative kinetic energy of the fluid?

Energy transfer due to the change of the relative kinetic energy of the fluid calculator uses Energy=(Relative velocity at exit^2-Relative velocity at inlet^2)/2 to calculate the Energy, The Energy transfer due to the change of the relative kinetic energy of the fluid formula is defined as the half of the difference of square of relative velocities at exit and inlet. Energy and is denoted by e symbol.

How to calculate Energy transfer due to the change of the relative kinetic energy of the fluid using this online calculator? To use this online calculator for Energy transfer due to the change of the relative kinetic energy of the fluid, enter Relative velocity at exit (w2) and Relative velocity at inlet (w1) and hit the calculate button. Here is how the Energy transfer due to the change of the relative kinetic energy of the fluid calculation can be explained with given input values -> 6536 = (124^2-48^2)/2.

FAQ

What is Energy transfer due to the change of the relative kinetic energy of the fluid?
The Energy transfer due to the change of the relative kinetic energy of the fluid formula is defined as the half of the difference of square of relative velocities at exit and inlet and is represented as e=(w2^2-w1^2)/2 or Energy=(Relative velocity at exit^2-Relative velocity at inlet^2)/2. Relative velocity at exit which will be observed by an observer positioned on the rotor. and Relative velocity at inlet which will be observed by an observer positioned on the rotor. .
How to calculate Energy transfer due to the change of the relative kinetic energy of the fluid?
The Energy transfer due to the change of the relative kinetic energy of the fluid formula is defined as the half of the difference of square of relative velocities at exit and inlet is calculated using Energy=(Relative velocity at exit^2-Relative velocity at inlet^2)/2. To calculate Energy transfer due to the change of the relative kinetic energy of the fluid, you need Relative velocity at exit (w2) and Relative velocity at inlet (w1). With our tool, you need to enter the respective value for Relative velocity at exit and Relative velocity at inlet 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 Energy?
In this formula, Energy uses Relative velocity at exit and Relative velocity at inlet. We can use 11 other way(s) to calculate the same, which is/are as follows -
  • Energy=Plancks Constant*frequency
  • Energy=-2.178*10^-18*(Atomic number)^2/(Quantum Number)^2
  • Energy=1.085*10^-18*(Atomic number)^2/(Quantum Number)^2
  • Energy=-1.085*(Atomic number)^2/(Quantum Number)^2
  • Energy=(Plancks Constant*Velocity Of Light in Vacuum)/Wavelength
  • Energy=Plancks Constant*Velocity Of Light in Vacuum*Wave Number
  • Energy=-([Rydberg])*(1/(Quantum Number^2))
  • Energy=(-((Atomic number^2)*[Mass-e]*([Charge-e]^4))/(8*([Permitivity-vacuum]^2)*([hP]^2)*(Quantum Number^2)))
  • Energy=(-([Mass-e]*([Charge-e]^4)*(Atomic number^2))/(8*([Permitivity-vacuum]^2)*(Quantum Number^2)*([hP]^2)))
  • Energy=[hP]*frequency
  • Energy=([hP]*[c])/Wavelength
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