Course Syllabus
Instructor’sName:
Dr. Adulaziz Alklaibi
Course Title:
Engineering Mechanics
Prerequisite:
Academic Year:
Lecture Times:
Office Hours
ME 353
Course code:
Co-requisite:
---
2015/2016
: Sun 10-12 &Tu: 2- 3
Su & Wed & Th: 10:00 - 10:50
Tutorial
Time:
Semester:
ME 354
Th:11 to 12
Cr.Hrs:
(3,1,0)
First
Lab Time:
Office number
--Mech. HOD office
Course Objectives
This course aims to achieve the following objectives
1 Understanding heat Transfer Mechanisms.
2 Understanding one-dimensional heat conduction equation in different geometry and combined layers
3 Understanding heat Transfer from Extended Surfaces and calculate their performance.
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5
6
7
8
Understanding TRANSIENT HEAT CONDUCTION
Understanding CONVECTION heat transfer problems
Understanding radiation heat transfer problems
Understanding Boiling and Condensation
Understanding the different type of HEAT EXCHANGERS and analyze them.
Student Learning Outcomes
Course Learning Outcomes
By the end of this course the students will be able to
1
2
3
4
5
6
7
k8
To understand heat Transfer Mechanisms.
To be able to solve One-dimensional heat conduction equation in different geometry and
combined layers
To be able to analyze heat Transfer from Extended Surfaces and calculate their
performance.
To be able to analyze TRANSIENT HEAT CONDUCTION
To able to solve CONVECTION heat transfer problems
To able to solve radiation heat transfer problems
To understand Boiling and Condensation
Be able to differentiate between the different type of HEAT EXCHANGERS and
analyze them.
ABET
Student
Outcomes
a, b, c
a, b, c
a, c, e,k
a, c, e,k
a, c, e, k
a, c, e, k
a, c, e,
a, c, e, f, i
Assessment
N
Methods of Assessment
1
2
3
4
5
6
First exam
Second exam
Exercise questions and participation
Quiz and homework assignments
Report, Project or Assignment
Final Exam
Total
N
1
2
3
4
5
6
7
Assessed Learning Outcomes
1, 2
2,3,4, 5
1,2,3,4,5, 6
1,2,3,4, 5
1,2,3,4,5,6
1,2,3,4,5,6, 7
Course Contents
Short Description
Introduction to Heat Transfer Mechanisms: Conduction , Convection & Radiation
Heat Conduction Equation in a Large Plane Wall.
Heat Conduction Equation in a Long Cylinder.
Heat Conduction Equation in a Sphere.
Generalized Thermal Resistance Networks
Heat Transfer from Finned Surfaces and Fin Performance
Lumped System Analysis
Transient Heat Conduction in
Large Plane Walls, Long Cylinders
Transient Heat Conduction in
Semi-Infinite Solids
Transient Heat Conduction in
Maximum Score
15
15
10
10
10
40
100
Week
1
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Multidimensional Systems
Velocity boundary and thermal Boundary Layers
Local and Average Convection Coefficients
Conservation of Mass Equation Conservation of Momentum and Equations
Conservation of Energy Equation
Internal Flow
Velocity Profile , pressure Gradient and Friction Factor in the Fully Developed Region
The Mean Temperature, Newton’s Law of Cooling
Convection Correlations for fully Developed Region and the Entry Region
Physical Mechanism of Natural Convection
Laminar Free Convection on a Vertical Surface
Empirical Correlations: External Free Convection Flows The Vertical Plate and Inclined and
Horizontal Plates
Empirical Correlations: Enclosures Rectangular Cavities Concentric Cylinders
Pool Boiling and Flow Boiling
Film Condensation and Dropwise Condensation
Thermal Radiation and Blackbody Radiation
Emissivity , Absorptivity, Reflectivity, and Transmissivity
Radiation Shields and the Radiation Effect
Types of Heat Exchangers
The Log Mean Temperature Difference Method
The Effectiveness–NTU Method
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Books
Textbook:
Essential Reference Yunus A. Çengel "Heat Transfer: A Practical Approach"
McGraw-Hill, 2003
2. Incropera and De Witt, "Fundamentals of heat and mass transfer," 7th Edition,
2012.
1.