Fluid Mechanics - Concept and Derivation

Fluid Mechanics - Concept and Derivation

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Fluid Mechanics: Topic 2.3 - Hydrostatic pressure distribution

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10 of 45

Fluid Mechanics: Topic 2.3 - Hydrostatic pressure distribution

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Fluid Mechanics - Concept and Derivation

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  1. 1 Fluid Mechanics: Topic 1.1 - Definition of a fluid
  2. 2 Fluid Mechanics: Topic 1.2 - Pressure
  3. 3 Fluid Mechanics: Topic 1.3 - Absolute pressure and gage pressure
  4. 4 Fluid Mechanics: Topic 1.4 - Density
  5. 5 Fluid Mechanics: Topic 1.5 - Viscosity
  6. 6 Fluid Mechanics: Topic 1.6 - Continuum approximation
  7. 7 Fluid Mechanics: Topic 1.7 - Vapor pressure
  8. 8 Fluid Mechanics: Topic 2.1 - Pascal's Law
  9. 9 Fluid Mechanics: Topic 2.2 - Hydrostatic pressure gradient
  10. 10 Fluid Mechanics: Topic 2.3 - Hydrostatic pressure distribution
  11. 11 Fluid Mechanics: Topic 3.1 - Introduction to manometers
  12. 12 Fluid Mechanics: Topic 3.2 - Barometers
  13. 13 Fluid Mechanics: Topic 3.3 - Piezometer tube manometers
  14. 14 Fluid Mechanics: Topic 3.4 - U-tube manometers
  15. 15 Fluid Mechanics: Topic 3.5 - Inclined tube manometers
  16. 16 Fluid Mechanics: Topic 4.1 - Hydrostatic force on a plane surface
  17. 17 Fluid Mechanics: Topic 4.2 - Center of pressure on a plane surface
  18. 18 Fluid Mechanics: Topic 4.3 - Hydrostatic force on a curved surface
  19. 19 Fluid Mechanics: Topic 5 - Buoyancy & Archimedes' principle
  20. 20 Fluid Mechanics: Topic 6.1 - Systems vs Control Volumes
  21. 21 Fluid Mechanics: Topic 6.2 - Reynolds transport theorem
  22. 22 Fluid Mechanics: Topic 7.1 - Conservation of mass for a control volume
  23. 23 Fluid Mechanics: Topic 7.2 - Conservation of linear momentum for a control volume
  24. 24 Fluid Mechanics: Topic 7.2.1 - Analyzing pressure forces on a CV
  25. 25 Fluid Mechanics: Topic 7.3 - Conservation of energy for a control volume
  26. 26 Fluid Mechanics: Topic 7.3.1 - Energy grade line (EGL) & Hydraulic grade line (HGL)
  27. 27 Fluid Mechanics: Topic 7.3.2 - The Bernoulli equation
  28. 28 Fluid Mechanics: Topic 7.3.3 - Definition of pump efficiency & turbine efficiency
  29. 29 Fluid Mechanics: Topic 8.1 - General Characteristics of laminar and turbulent flows in pipes
  30. 30 Fluid Mechanics: Topic 8.2 - Developing and fully-developed flow in pipes
  31. 31 Fluid Mechanics: Topic 8.3 - Pressure drop and head loss in pipe flow
  32. 32 Fluid Mechanics: Topic 8.4 - Velocity profile of fully-developed laminar flow in pipes
  33. 33 Fluid Mechanics: Topic 8.5 - Velocity profile for fully-developed turbulent flow in pipes
  34. 34 Fluid Mechanics: Topic 8.6.1 - Major losses in circular pipe systems
  35. 35 Fluid Mechanics: Topic 8.6.2 - The Moody chart
  36. 36 Fluid Mechanics: Topic 8.6.3 - Major losses in non-circular ducts
  37. 37 Fluid Mechanics: Topic 8.7 - Minor losses in pipe systems
  38. 38 Fluid Mechanics: Topic 9.1 - Categories of pipe flow problems
  39. 39 Fluid Mechanics: Topic 9.2 - Example of type I pipe flow problem
  40. 40 Fluid Mechanics: Topic 10.1 - Lagrangian vs Eulerian descriptions of flow
  41. 41 Fluid Mechanics: Topic 10.2 - The material derivative
  42. 42 Fluid Mechanics: Topic 10.3 - Steamlines, streaklines, and pathlines
  43. 43 Fluid Mechanics: Topic 10.4 - Kinematics of fluid elements (translation and linear deformation)
  44. 44 Fluid Mechanics: Topic 10.5 - Kinematics of fluid elements (shear strain, rotation, and vorticity)
  45. 45 Fluid Mechanics: Topic 11.1 - The continuity equation

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