Equation of conservation of energy in fluid mechanics скачать в хорошем качестве

Equation of conservation of energy in fluid mechanics

The equation of conservation of energy, also called energy principle, is based upon the first law of thermodynamics. The energy of the mass of fluid consists of: • potential energy of the mass linked to vertical elevation above a datum & positive upwards • kinetic energy of the fluid mass proportional to the square of the velocity of fluid particles • internal thermal energy The equation of conservation of energy is a fundamental principle in fluid mechanics, including its application and use in physical and numerical modelling of fluid flows and energy dissipator structures. This is further discussed in a number of relevant Youtube video movies in the same channel at: {   / @hubert_chanson  }. Fluid mechanics and hydraulics in Hubert Chanson Youtube channel {   / @hubert_chanson  } Fluid Mechanics [Playlist] Applied hydrodynamics [Playlist] Fundamentals of open channel hydraulics [Playlist] Advanced hydraulics of open channel flows [Playlist] Environmental hydraulics of open channel flows [Playlist] The Equation of Conservation of Mass in Fluid Mechanics {   • The Equation of Conservation of Mass in Fl...  } Momentum equation in open channels {   • Momentum equation in open channels  } Equation of conservation of momentum in fluid mechanics (1) Integral form {   • Equation of conservation of momentum in fl...  } Equation of conservation of momentum in fluid mechanics (2) Differential form {   • Equation of conservation of momentum in fl...  } The hydraulic jump in open channel {   • The hydraulic jump in open channel  } References GERHART, P.M., GROSS, R.J., and HOCHSTEIN, J.I. (1992). "Fundamentals of Fluid Mechanics." Addison-Wesley Publ., Reading MA, USA, 2nd edition, 983 pages. LIGGETT, J.A. (1994). "Fluid Mechanics." McGraw-Hill, New York, USA. MONTES, J.S. (1998). "Hydraulics of Open Channel Flow." ASCE Press, New-York, USA, 697 pages. CHANSON, H. (2004). "The Hydraulics of Open Channel Flow: An Introduction." Butterworth-Heinemann, 2nd edition, Oxford, UK, 630 pages (ISBN 978 0 7506 5978 9).