Blasius Solution for the y-Component of Velocity 
Blasius Solution for the y-Component of Velocity
by University of Colorado
Video Lecture 35 of 50
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Date Added: January 13, 2015

Lecture Description

Uses the Blasius solutions to develop an expression for the y-component of velocity at the edge of a boundary layer.

Course Index

  1. Heat Transfer Basics
  2. Introduction to Heat Transfer - Potato Example
  3. Heat Transfer Parameters and Units
  4. Heat Flux: Temperature Distribution
  5. Conduction Equation Derivation
  6. Heat Equation Derivation
  7. Heat Equation Derivation: Cylindrical Coordinates
  8. Boundary Conditions
  9. Thermal Circuits Introduction
  10. Thermal Circuits: Temperatures in a Composite Wall
  11. Composite Wall: Maximum Temperature
  12. Temperature Distribution for a Cylinder
  13. Rate of Heat Generation
  14. Uniform Heat Generation: Maximum Temperature
  15. Heat Loss from a Cylindrical Pin Fin
  16. Heat Loss from a Rectangular Fin
  17. Maximum Temperature for a Rectangular Fin
  18. Methods for Solving Transient Conduction Problems
  19. Lumped Capacitance Introduction
  20. Lumped Capacitance: Temperature of a Sphere
  21. Transient Conduction in a Sphere (Part I)
  22. Transient Conduction in a Sphere (Part II)
  23. Transient Conduction: One-Term Approximation
  24. Modeling Heat Transfer along a Semi-Infinite Medium
  25. Solving Convection Problems
  26. Flow over a Flat Plate
  27. Laminar Flow: Flat Plate Surface Temperature
  28. Solar Cell (Part I): Heat Transfer Coefficient
  29. Solar Cell (Part II): Surface Temperature
  30. Heat Transfer Rate: Tube Bank
  31. Rod Center-line Temperature
  32. Introduction to Blasius Solutions
  33. Blasius Solution for Boundary Layer Thickness
  34. Shear Stress at a Wall: Blasius Solutions
  35. Blasius Solution for the y-Component of Velocity
  36. y-Component of Velocity at a Boundary Layer
  37. Outlet Mean Temperature
  38. Heat Transfer Rate: Cross-Section Orientation
  39. Nucleate Boiling Example
  40. Counter-Flow Heat Exchanger: Outlet Temperature (Bio)
  41. Heat Exchanger: Mass Flow Rate
  42. Sizing a Heat Exchanger: Parallel Flow
  43. Sizing a Heat Exchanger: Counter-Flow
  44. Excel Solver Introduction
  45. Laminar, Fully-Developed Internal Flow Through a Pipe
  46. NTU Effectiveness Method
  47. NTU Effectiveness: Counter-Flow Heat Exchanger
  48. Log Mean Temperature Difference
  49. How to Calculate Heat Duty
  50. Estimates for Heat Transfer Coefficients
  51. Local and Average Heat Transfer Coefficients
  52. Internal Flow with Constant Surface Temperature
  53. Contact Resistance
  54. Contact Resistance Example
  55. Film Pool Boiling
  56. Nucleate Pool Boiling
  57. Nucleate Pool Boiling: Unit Conversion
  58. Overall Heat Transfer Coefficient Rectangular Coordinates
  59. View Factors
  60. Surface Temperature for a Cylindrical Pipe
  61. Internal Flow with Constant Surface Heat Flux
  62. Net Radiative Heat Transfer Rate from a Surface
  63. Radiation Exchange Between Surfaces
  64. Temperature of a Radiation Shield
  65. Heat Generation in a Pipe
  66. Properties of Radiative Heat Transfer

Course Description

LearnChemE features faculty prepared engineering education resources for students and instructors produced by the Department of Chemical and Biological Engineering at the University of Colorado Boulder and funded by the National Science Foundation, Shell, and the Engineering Excellence Fund. In this course, LearnChemE covers topics in heat transfer, such as conduction, convection, and radiation.

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