Autoplay
Autocomplete
Previous Lesson
Complete and Continue
Fluid Mechanics - Incompressible Flow
Welcome!
Welcome/Trailer (4:21)
Before you Start - Course Overview (4:16)
Fluid Mechanics Series - Course Structure
About this Course (3:44)
Reference Material & Downloads
NOTES: Updated Course (4:09)
Basic Review of Topics (34:16)
Introduction to the Mechanical Energy Equation (M.E.E.)
What is Mechanical Energy? (1:37)
The Mechanical Energy Equation - Applications to Piping Systems, Pumps & More! (5:31)
More on the Mechanical Energy Equation: Systems, Surroundings, etc... (14:24)
Important Notes Regarding the Mechanical Energy Equation (20:58)
Kinetic Energy in MEE (2:55)
More on the Kinetic Energy (7:50)
Potential Energy & The M.E.E. (3:31)
More on Potential Energy in the MEE (4:30)
Pressure Head, Pressure Loss & Work & The M.E.E. (1:16)
More on Pressure, Pressure Head and Relating to Energy (5:21)
Introduction to Inlet & Outlet Work (3:18)
Inlet and Outlet Work (Input vs. Output) (9:17)
A Brief Introduction to Friction Losses (2:30)
Friction Loss - It's Nature, Type of frictions, Theoretical Concept (9:18)
Friciton Loss Exercise (7:07)
Read this FIRST! Check out other courses on pumping, piping, fittings, valves (1:30)
Application of M.E.E. to Gases... Foot for thought (2:40)
Closure to Section 1 (1:29)
Evaluation Section 1 (Part 1)
Applications of M.E.E to Incompressible Flow
Introduction of Applications of the MEE to Incompressible Flow (2:18)
Applying the Mechanical Energy Equation - Important Notes (4:22)
Bernoulli's Law: Theory + Exercises (9:42)
Torricelli's Law - Theory & Exercises (7:20)
Ex. 0 - Emptying a Tank - Torricelli's Law (8:35)
Ex.1 Time Calculations for Tank Depletion - Torricelli's Law (7:09)
Ex.2 Velocity of a Jet Stream while Emptying a Tank - Torricelli's Law (4:48)
Ex.3 Maximum Height for a Jet Stream - Torricelli's Law (2:57)
Ex.4 Height Calculation for a Pressurized Stream - Torricelli's Law (5:17)
Notes on Torricell's Law (0:40)
Ex.5 Pipe Reduction Effecst - Bernoulli's Law (10:27)
Ex.6 Applying Bernoulli's Principle to a Cone - Bernoulli's Law (4:36)
Ex.7 Pressure Drop in Pipeline Expansion - Bernoulli's Law (5:09)
Ex.8 Emptying a Pressurized Tank - Bernoulli's Law (4:12)
Ex.9 Emptying a Depressurized (Vacuum) Tank - Bernoulli's Law (4:40)
Ex.10 Changes in Pressure and Velocity in a Pipeline - Bernoulli's Law (4:27)
Ex.11 Pressure Drop due to changes in Velocity - Bernoulli's Law (3:59)
Notes on Bernoulli's Law (0:48)
A Brief Introduction to the "General Case" of the M.E.E. (0:53)
The "General" Application of the Mechanical Energy Equation (16:38)
Ex.12 Pumping Requirements for a given System (MEE Application - No Friction) (18:11)
Ex.13 Minimum Height Requirement for a Pump (MEE Application - No Friction) (11:04)
Ex.14 Pump Requirements vs. Turbine Production (MEE Application - No Friction) (11:59)
Closure to Section 2 (1:02)
Evaluation Section 2
Advanced Applications of Incompressible Flow
Introduction to Advanced Applications of the MEE to Engineering (0:53)
IMPORTANT NOTE! About Friction Loss Calculations (2:19)
About Series Flow (Piping Systems) (1:53)
Series Flow: Common Type of Problems (6:27)
Type I Problems - Theory & Solved Example (7:05)
Ex.15 Power Requirements for a Fan Blower (Type I) (8:59)
Ex. 16 Effects of Pressure vs Diameter Changes (Type I + Friction Loss) (11:06)
Ex.17 Pumping Cost Calculations (Type I + Friction Loss) (12:34)
Ex.18 Pump Requirements for a Non-Cylindrical Duct (Type I + Deq + Friction Loss) (4:16)
Ex.19 Pumping Costs from Reservoir A to B (Type I + Friction Loss) (20:46)
Ex.20 Piping Investment vs. Pumping Costs (Type I + Friction Loss) (33:09)
Ex.21 Flow through Non-Cylindrical Channel (Type I + Friction Loss) (14:05)
Ex.22 Pressure Changes due to Petroleum Production Drilling (Type I + Friction Loss) (13:08)
Ex.23 Friction Loss in a Long Pipe (Type I + Friction Loss) (7:25)
Ex.24 Pump Requirements for Fluid Transport (Type I + Friction Loss) (15:14)
Ex.25 Pressure Reading in a Manometer (Type I + Friction Loss) (7:28)
Ex.26 Pressure Drop in an Inclined Pipe (Type I + Friction Loss) (8:20)
Type II Problems - Theory & Solved Example (11:22)
Ex.27 Finding Volumetric Flow Rate for a Given System (Type II + Friction Loss) (17:50)
Ex.28 Calculating Volumetric Flow of a Tank losing Liquid (Type II + Friction Loss) (13:01)
Ex.29 Maximum Volumetric Flow Rate given a Discharge Pressure (Type II + Friction Loss) (11:46)
Ex.30 Max. Flow Rate given Friction Loss of a System (Type II + Friction Loss) (15:25)
Type III Problems - Theory & Solved Example (15:34)
Ex.31 Proposal of Internal Diameter for a System (Type III + Friction Loss) (20:09)
Ex.32 Proposing the Nominal Diameter given a Pressure Drop (Type III + Friction Loss) (21:01)
Ex.33 Optimal Nominal Diameter given Pressure Drops (Type III + Friction Loss) (14:33)
Ex.34 More Advanced Diameter Proposal (Type III + Friction Loss) (19:40)
About Parallel & Branched Flow Problems (Piping Systems) (0:32)
Parallel Flow - An Introduction (9:04)
Parallel Flow: Case 1 vs Case 2 (10:33)
Ex.35 Parallel Flow and Pressure Drop (Parallel Flow) (27:21)
Ex.36 Flow through Frictious and Free Paths (Parallel Flow) (21:01)
Ex.37 Flow Patterns: Low Velocity vs High Velocity (Parallel Flow) (25:25)
Ex.38A Parallel Pipes Systems: Defining the System (13:30)
Ex.38B Parallel Pipes Systems Solved in Excel (Parallel Flow) (22:03)
Branch Flow: Case Study (4:11)
Complex Piping: Solving with Software (5:06)
Closure to Section 3 (0:57)
Evaluation Section 3
Closure
Course Content Review & Closure (7:06)
Bonus Lecture - What's Next? (5:39)
BONUS - Friction Loss Calculations (30:32)
BONUS - Top Technical Questions in Fluid Mechanics
Introduction of Applications of the MEE to Incompressible Flow
Lesson content locked
If you're already enrolled,
you'll need to login
.
Enroll in Course to Unlock