Fluid Dynamics

Fluid Dynamics

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y-Component of Velocity at a Boundary Layer

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55 of 84

y-Component of Velocity at a Boundary Layer

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Fluid Dynamics

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  1. 1 Bernoulli Equation Derivation
  2. 2 Simple Bernoulli Equation Example
  3. 3 Air Flow Through a Constriction
  4. 4 Draining a Conical Tank
  5. 5 Draining a Cylindrical Tank
  6. 6 Flow Rate Out of a Coffee Urn
  7. 7 Flow Exiting a Tank (Bernoulli)
  8. 8 Draining a Spherical Tank
  9. 9 Velocity of a Falling Sphere
  10. 10 Pitot Static Tube Introduction & Example
  11. 11 Pitot Tube Example
  12. 12 Derivation of the Continuity Equation
  13. 13 Deriving Continuity Equation in Cylindrical Coordinates
  14. 14 Differential Form of Continuity Equation
  15. 15 Continuity and Stream Functions
  16. 16 Irrotational & Incompressible Flow
  17. 17 Naming Normal and Tangential Stresses
  18. 18 Coordinate Transformations, part 1 - Lecture 3.1 - Chemical Engineering Fluid Mechanics
  19. 19 Coordinate Transformations, part 2 - Lecture 3.2 - Chemical Engineering Fluid Mechanics
  20. 20 Coordinate Transformations, part 3 - Lecture 3.3 - Chemical Engineering Fluid Mechanics
  21. 21 Solve for Equations of Motion
  22. 22 Velocity Potentials and Stream Functions
  23. 23 Applying the Navier-Stokes Equations, part 1 - Lecture 4.6 - Chemical Engineering Fluid Mechanics
  24. 24 Applying the Navier-Stokes Equations, part 2 - Lecture 4.7 - Chemical Engineering Fluid Mechanics
  25. 25 Applying the Navier-Stokes Equations, part 3 - Lecture 4.8 - Chemical Engineering Fluid Mechanics
  26. 26 Applying the Navier-Stokes Equations, part 4 - Lecture 4.9 - Chemical Engineering Fluid Mechanics
  27. 27 Boundary Conditions for a Velocity Profile
  28. 28 Laminar Flow between Parallel Plates (Navier-Stokes)
  29. 29 Shear Stress between Parallel Plates
  30. 30 Energy Loss for Flow through Non-Circular Duct
  31. 31 Entrance Length Example
  32. 32 Entrance Region vs. Fully Developed Flow
  33. 33 Fully Developed Laminar Flow (Using Force Balance)
  34. 34 Losses & Friction Factors, part 1 - Lecture 6.1 - Chemical Engineering Fluid Mechanics
  35. 35 Losses & Friction Factors, part 2 - Lecture 6.2 - Chemical Engineering Fluid Mechanics
  36. 36 Losses & Friction Factors, part 3 - Lecture 6.3 - Chemical Engineering Fluid Mechanics
  37. 37 Losses & Friction Factors, part 4 - Lecture 6.4 - Chemical Engineering Fluid Mechanics
  38. 38 Pipe Flow Introduction
  39. 39 Pipe Flow Problem (Determine Diameter)
  40. 40 Pipe Flow Computer Solver (Determine Diameter)
  41. 41 Pipe Flow: Determining Power
  42. 42 Pipe Flow: Entrance Region & Entrance Length
  43. 43 Pressure Drop in a Pipe (Laminar Flow)
  44. 44 Pressure Drop in Pipe with Losses (Determine Pressure Drop)
  45. 45 Pressure Drop in Pipe with Losses (Determine Q)
  46. 46 Using a Moody Chart
  47. 47 Volumetric Flow Rate for Laminar Pipe Flow
  48. 48 Blasius Solution for the y-Component of Velocity
  49. 49 Boundary Layer Example Problem
  50. 50 Boundary Layers
  51. 51 Drag Force on an Irregular Object
  52. 52 Lift and Drag on Aircraft
  53. 53 Pressure Drag
  54. 54 Shear Stress at a Wall: Blasius Solutions
  55. 55 y-Component of Velocity at a Boundary Layer
  56. 56 Description and Derivation of the Navier-Stokes Equations
  57. 57 Integral Form of the Continuity Equation - Moving Control Volume
  58. 58 Introduction to the Integral Form of the Continuity Equation
  59. 59 Integral Form of the Continuity Equation - Branched System
  60. 60 Blasius Solution for Boundary Layer Flow
  61. 61 Example of Blasius Solution for Boundary Layer Flow
  62. 62 Using Boundary Conditions
  63. 63 Couette Flow
  64. 64 Density Example Problem
  65. 65 Properties of Fluids Part 1
  66. 66 Properties of Fluids Part 2
  67. 67 Flow in a Pipe
  68. 68 Barometer Example
  69. 69 Velocity Profile in the z-direction
  70. 70 Equivalent Length
  71. 71 Equivalent Length Example
  72. 72 Multipipe Systems
  73. 73 Multipipes in Series
  74. 74 Bernoulli Equation and Pipe Flow (Interactive Simulation)
  75. 75 Multipipe in Parallel
  76. 76 Surface Roughness Effect on Trajectory (Interactive Simulation)
  77. 77 Velocity and Drag on a Falling Object (Interactive Simulation)
  78. 78 Vectors (Interactive Simulation)
  79. 79 Calculating Velocity in a Pipe with Viscous Flow
  80. 80 Calculating Pipe Velocity Example
  81. 81 Buoyancy of a Floating Cube (Interactive Simulation)
  82. 82 Flow around a Sphere at Low Reynolds Number (Interactive Simulation)
  83. 83 Couette Flow (Interactive Simulation)
  84. 84 Manometers (Interactive Simulation)

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