Master Fluid Mechanics for Incompressible Flow

سرفصل های دوره

Applications of Mechanical Energy Equation, Piping & Fittings, Pumps & More!

1. Introduction

1. Welcome

2. Before you Start - Course Overview

3. About this Course

4. Note Updated Course

5. Basic Review of Topics

2. Introduction to the Mechanical Energy Equation (M.E.E.)

1. What is Mechanical Energy

2. The Mechanical Energy Equation - Applications to Piping Systems, Pumps & More!

3. More on the Mechanical Energy Equation Systems, Surroundings, etc...

4. Important Notes Regarding the Mechanical Energy Equation

5. Kinetic Energy in MEE

6. More on the Kinetic Energy

7. Potential Energy & The M.E.E.

8. More on Potential Energy in the MEE

9. Pressure Head, Pressure Loss & Work & The M.E.E.

10. More on Pressure, Pressure Head and Relating to Energy

11. Introduction to Inlet & Outlet Work

12. Inlet and Outlet Work (Input vs. Output)

13. A Brief Introduction to Friction Losses

14. Friction Loss - Its Nature, Type of frictions, Theoretical Concept

15. Friction Loss Exercise

16. Application of M.E.E. to Gases... Foot for thought

17. Closure to Section 1

3. Applications of M.E.E to Incompressible Flow

1. Introduction of Applications of the MEE to Incompressible Flow

2. Applying the Mechanical Energy Equation - Important Notes

3. Bernoullis Law Theory + Exercises

4. Torricellis Law - Theory & Exercises

5. Ex. 0 - Emptying a Tank - Torricellis Law

6. Ex.1 Time Calculations for Tank Depletion - Torricellis Law

7. Ex.2 Velocity of a Jet Stream while Emptying a Tank - Torricellis Law

8. Ex.3 Maximum Height for a Jet Stream - Torricellis Law

9. Ex.4 Height Calculation for a Pressurized Stream - Torricellis Law

10. Notes on Torricells Law

11. Ex.5 Pipe Reduction Effecst - Bernoullis Law

12. Ex.6 Applying Bernoullis Principle to a Cone - Bernoullis Law

13. Ex.7 Pressure Drop in Pipeline Expansion - Bernoullis Law

14. Ex.8 Emptying a Pressurized Tank - Bernoullis Law

15. Ex.9 Emptying a Depressurized (Vacuum) Tank - Bernoullis Law

16. Ex.10 Changes in Pressure and Velocity in a Pipeline - Bernoullis Law

17. Ex.11 Pressure Drop due to changes in Velocity - Bernoullis Law

18. Notes on Bernoullis Law

19. A Brief Introduction to the General Case of the M.E.E.

20. The General Application of the Mechanical Energy Equation

21. Ex.12 Pumping Requirements for a given System (MEE Application - No Friction)

22. Ex.13 Minimum Height Requirement for a Pump (MEE Application - No Friction)

23. Ex.14 Pump Requirements vs. Turbine Production (MEE Application - No Friction)

24. Closure to Section 2

4. Advanced Applications of Incompressible Flow

1. Introduction to Advanced Applications of the MEE to Engineering

2. IMPORTANT NOTE! About Friction Loss Calculations

3. About Series Flow (Piping Systems)

4. Series Flow Common Type of Problems

5. Type I Problems - Theory & Solved Example

6. Ex.15 Power Requirements for a Fan Blower (Type I)

7. Ex. 16 Effects of Pressure vs Diameter Changes (Type I + Friction Loss)

8. Ex.17 Pumping Cost Calculations (Type I + Friction Loss)

9. Ex.18 Pump Requirements for a Non-Cylindrical Duct (Type I + Deq + Friction Loss

10. Ex.19 Pumping Costs from Reservoir A to B (Type I + Friction Loss)

11. Ex.20 Piping Investment vs. Pumping Costs (Type I + Friction Loss)

12. Ex.21 Flow through Non-Cylindrical Channel (Type I + Friction Loss)

13. Ex.22 Pressure Changes due to Petroleum Production Drilling (Type I + Friction L

14. Ex.23 Friction Loss in a Long Pipe (Type I + Friction Loss)

15. Ex.24 Pump Requirements for Fluid Transport (Type I + Friction Loss)

16. Ex.25 Pressure Reading in a Manometer (Type I + Friction Loss)

17. Ex.26 Pressure Drop in an Inclined Pipe (Type I + Friction Loss)

18. Type II Problems - Theory & Solved Example

19. Ex.27 Finding Volumetric Flow Rate for a Given System (Type II + Friction Loss)

20. Ex.28 Calculating Volumetric Flow of a Tank losing Liquid (Type II + Friction Lo

21. Ex.29 Maximum Volumetric Flow Rate given a Discharge Pressure (Type II + Fricti

22. Ex.30 Max. Flow Rate given Friction Loss of a System (Type II + Friction Loss)

23. Type III Problems - Theory & Solved Example

24. Ex.31 Proposal of Internal Diameter for a System (Type III + Friction Loss)

25. Ex.32 Proposing the Nominal Diameter given a Pressure Drop (Type III + Friction

26. Ex.33 Optimal Nominal Diameter given Pressure Drops (Type III + Friction Loss)

27. Ex.34 More Advanced Diameter Proposal (Type III + Friction Loss)

28. About Parallel & Branched Flow Problems (Piping Systems)

29. Parallel Flow - An Introduction

30. Parallel Flow Case 1 vs Case 2

31. Ex.35 Parallel Flow and Pressure Drop (Parallel Flow)

32. Ex.36 Flow through Frictious and Free Paths (Parallel Flow)

33. Ex.37 Flow Patterns Low Velocity vs High Velocity (Parallel Flow)

34. Ex.38A Parallel Pipes Systems Defining the System

35. Ex.38B Parallel Pipes Systems Solved in Excel (Parallel Flow)

36. Branch Flow Case Study

37. Complex Piping Solving with Software

38. Closure to Section 3

5. Closure

1. Course Content Review & Closure

2.1 Bonus Lecture - Whats Next Coupons.pdf

2. BONUS Lecture

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تولید کننده: Udemy