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Flow of Liquids Through Pipes, Fittings & Valves - Friction Loss & Efficiency Analysis
Welcome
Welcome/Trailer (3:13)
Before you Start - Course Overview (3:43)
Fluid Mechanics Series - Course Structure
About this Course (4:21)
Introduction to Piping Systems. Why We Need Piping systems? (8:16)
Reference Material & Downloads
NOTES: Updated Course (4:09)
Basic Review of Topics + Mechanical Energy Equation Review (71:41)
All About Pipes: Types, Materials & Standards
All About Pipes (0:55)
Pipes, Piping, Pipeline, Piping Systems (3:54)
Pipe Selection Criteria (3:09)
Piping Materials & Piping Standards (ASTM, API, B88, etc...) (3:45)
Pipe Sizing (ASME, BWG and Others) (11:38)
Context of Material Roughnes (5:27)
Common Piping Problems & Troubleshooting (7:12)
Closure of Pipes (0:33)
Evaluation 1 (0:13)
Fittings & Valves Used in Piping Systems
Introduction to Fittings & Valves! (1:01)
Common Accesories Found in Piping Systems: Fittings & Valves (2:59)
Accesories that Won't Affect Fluid Flow: Pipe Hangers, Base, Shoes, etc. (6:29)
Fittings that Affect Fluid Flow: Expanders, Contractors, Elbows, Reducers, etc. (6:54)
What Are Valves? Why We Need Them in the Industry? (1:31)
Common Industrial Valves: Ball, Globe, Gate, Butterfly, Check, Safety Valves & More! (5:42)
More on Valves? Check out this Course! (0:19)
Problems & Troubleshooting of Fittings & Valves (4:11)
Section Closure - Fittings & Valves (0:20)
Evaluation 2
Fundamentals of Fluid Flow in Pipes (REVIEW)
Introduction to Fluid Flow in Pipes (1:06)
Reynolds Number and Types of Flow (5:20)
Types of Flow: Laminar, Transient & Turbulent (10:51)
Turbulent Flow (Theory + Exercise) (3:53)
Special Case: Plug Flow (1:00)
Relative Roughness - What is it? (7:44)
Non-Cylindrical Pipes: Hydraulic Radius and Equivalent Diameter (6:25)
Exercises: Non-Cylindrical Pipes: Hydraulic Radius and Equivalent Diameter (9:34)
Closure of Fluid Flow in Pipes (0:22)
Evaluation 3
Friction Loss in Pipes (a.k.a. Head Loss or Pressure Loss) Hfs
Introduction to Friction Loss in Pipes (Hfs) (1:00)
What Is Friction? How Is It Related to Head Loss? (7:52)
Introduction to the Friction Factor - (Darcy's and Fanning Models in Laminar and Turbulent Flow) (14:41)
How to Read Moody's Chart for Friction Factor - Theory and Exercise (13:30)
Friction Factor Equations: Chen, Swamee Jain, Hazen Williams & More! (12:07)
NOTE: Energy Loss vs Friction Factor (1:09)
Energy Loss due to Pipe Wall Friction - Theory and Exercises (25:20)
Closure to Friction Loss in Pipes (0:34)
Evaluation 4
Friction Loss in Fittings & Valves (Hff)
Introduction to Friction Loss due to Fittings & Valves (Hff) (0:22)
Friction Loss in Fittings & Valves - Theory & Exercises (14:01)
K Constant for Fittings & Valves - Theory & Exercises (9:40)
NOTE: Why relating to Equivalent Lenght is Important (1:47)
How to Relate Friction due to Fittings to Pipe Wall (Hfs and Hff) + Exercise (8:34)
Putting it All Together: Friction Loss due to Pipe Walls, Fittings and Valves (12:51)
Closure of Friction Loss due to Fittings & Valves (0:36)
Evaluation 5
Solved Problems: Liquid Flow through Pipes, Fittings & Valves
Introduction to Friciton Loss in Piping Systems (0:29)
Basics & Reynolds Number
Ex. 043 Relationship Between Volumetric Flow Rate, Area and Velocity (Basic Engineering) (1:32)
Ex. 045 Continuity Equation Application (Basic Eng) (3:47)
Ex. 046 Relating Velocity and Volumetric Flow to Get the Pipes Diameter (Basic Engineering) (2:04)
Ex. 047 Continuity Equation Applied to a Pipe Reduction (3:42)
Ex. 049 Interesting Pressure Drop in an Expanded Pipe (Bernoulli) (5:25)
Ex. 052 Relating Pressure Drop With Velocities (Bernoulli) (4:39)
Ex. 053 Pressure Drops Due to Velocity Changes (Bernoulli) (4:14)
Ex. 020 Reynolds Number and Pressure Drop in a Non-Cylindrical Pipe (4:39)
Ex. 061 Identifying Type of Flow: Laminar or Turbulent Flow (5:14)
Ex. 063 Minimum Pipe Diameter Given Different Operation Fluids (Reynolds Number) (7:39)
Ex. 065 Transient State Flow in a Pipe (Reynolds Number) (3:34)
Friction Loss in Pipes
Ex. 068 Friction Loss in a Long Pipe (Friction Loss Type I) (7:25)
Ex. 073 Using Chen's Equation for Friction Factor (Friction Factor Equations) (6:44)
Ex. 075 Hazen Williams Equation (Friction Factor Equations & Friction Loss) (4:52)
Friction Loss in Fittings & Valves
Ex. 059 Calculating K Value With Experimental Data (Friction Due to Valves) (7:50)
Ex. 087 Friction Loss Due to a Pipe Connected to a Vessel (Friction Loss in Fittings) (3:24)
Ex. 089 Friction Loss Due to Gradual Expansion of 60ยบ (Friction Loss due to Fittings) (2:25)
Ex. 091 Friction Loss in a Sudden Contraction (Friction Loss in Fittings) (2:31)
Ex. 093 Pipe Entrace Edge Effect on Friction Loss (Friction Factor in Fittings) (4:24)
Ex. 097 Pressure Drop Due to a Street Elbow (Friction Loss in Fittings) (2:41)
Closure to Friction Loss in Piping Systems (0:30)
Bonus Section - More Solved Problems!
Bonus Section - Solved Problems (0:18)
Ex. 062 Maximum Volumetric Flow Given a Pipeline Diameter (Laminar Flow) (3:08)
Ex. 064 Reynolds Number in a Pipe (Type of Flow Transient or Turbulent) (2:59)
Ex. 066 Importance of Wall Thickness in a Pipe (Reynolds Number) (9:48)
Ex. 021 Reynolds Number Exercises + Hydraulic Radius (4:06)
Ex. 077 Flow in Ducts vs Parallel Pipes (Geometry + Rh) In a Pipe (Reynolds Number) (4:27)
Ex. 078 Reynolds Number of a Non-cylindrical Pipe (Hydraulic Radius and Equivalent Diameter) (10:18)
Ex. 079 Reynolds Number of a Heat Exchanger (Reynolds Number) (6:37)
Ex. 022 Pressure Drop Due to Wall Friction in a Non-Cyindrical Pipe (Hydraulic Radius) (6:32)
Ex. 057 Friction Loss Due to Wall Friction (Wall Friction) (3:51)
Ex. 067 Pressure Changes When Drilling Petroleum (Friction Factor + Type I) (13:08)
Ex. 069 Finding the Real Material Roughness of a Pipe (Type I + Friction Wall) (11:29)
Ex. 074 Janine Swamee Equation Example (Friction Factor Equations) (4:05)
Ex. 076 Hazen William Equation for SI System (Friction Loss & Friction Factor Equations) (4:24)
Ex. 080 Flow Through an Open Channel (Equivalent Diamater, Deq + Hydraulic Radius) (7:58)
Ex. 081 Drop of Pressure in a Heat Exchanger (Hydraulic Radius, Reynolds Number, Friction Loss) (6:42)
Ex. 082 Hydraulic Radius and Equivalent Diameter of a Half-Pipe (Hydraulic Radius, Equivalent Diameter; Rh Deq) (4:00)
Ex. 083 Equivalent Diameter of an Open Channel (Deq + Rh) (4:22)
Ex. 084 Complex Channel Flow (Rh + Deq) (6:14)
Ex. 088 Friction Loss Due to Gradual Expansion (Friction Loss due to Fittings) (2:39)
Ex. 090 Friction Loss Due to Pipe Exit (Friction Loss due to Fittings) (2:44)
Ex. 092 Drop of Pressure in a Sudden Contraction (Friction Loss due to Fittings) (6:52)
Ex. 094 Equivalent Length of a Gate Valve (Friction Factor in Valves) (4:38)
Ex. 095 Equivalent Length of a Globe Valve (Friction Factor in Valves) (3:27)
Ex. 096 Pressure Drop Due to an Elbow (Friction Loss due to Fittings) (5:30)
Ex. 098 Elbow Pressure Drop Comparison (Friction Factor due to Fittings) (3:24)
Ex. 099 Empirical Rules for Pressure Drops in Valves (Friction Loss due to Fittings) (3:17)
Closure
Course Content Review & Closure (4:53)
Bonus Lecture - What's Next? (3:27)
BONUS - Top Technical Questions in Fluid Mechanics
Ex. 084 Complex Channel Flow (Rh + Deq)
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