Download MEP 365 THERMAL ENGINEERING MEASUREMENTS (3: 2, 3)

KING ABDULAZIZ UNIVERSITY
FACUTY OF ENGINEERING
DEPARTMENT OF THERMAL ENGINEERING
AND DESALINATION TECHNOLOGY
COURSE DESIGN AND ASSESSMENT
COURSE SYLLABUS
1.
Course name and type:
MEP 360, Heat Transfer (4:3, 2) Core Course (In-Department Compulsory)
2.
Catalog course description:
General Conduction equations, composite walls and cylinders. Heat generation. Heat
transfer from extended surfaces. Transient and two-dimensional analysis. Convection
heat transfer, forced external and internal convection heat transfer. Natural convection.
Radiation heat transfer, emission and heat exchange between surfaces. Black and gray
bodies. View factors and enclosures
3.
Prerequisite:
MEP 261; Thermodynamics I; MEP 290; Fluid mechanics
4.
Textbooks and/or other Required Material:
Fundamentals of heat and mass transfer
By: Incropera and De Witt, 6th edition, 2003.
5.
Course topics and Course learning objectives:
Topics Covered
Introduction
(1.5 weeks)
Course Learning Objectives
CLO_1: students will be able to identify the different modes of heat transfer mechanisms.
CLO_2: students will be able to recall the energy balance equation.
Introduction to conduction CLO_3: Students will be able to define heat conduction.
CLO_4: Students will be able to describe the heat diffusion equation for conduction
(1 week)
problems and list its boundary conditions.
Steady 1-D conduction
(2 weeks)
CLO_5 Students will be able to derive heat diffusion equation for steady 1-D conduction.
CLO_6: Students will be able to solve steady 1-D basic heat conduction problems (plane
walls, cylinders, spheres, composite walls, conduction with internal heat
generation and extended surfaces).
Two-D computational
conduction analysis
(0.5 week)
CLO_7: Students will be able to apply finite difference methods to solve steady state 2-D
heat basic conduction problems
Transient conduction heat
transfer analysis
(2 weeks)
CLO_8: Students will be able to solve unsteady basic heat conduction problems using
lumped analysis.
Introduction to convection CLO_9: Students will be able to define heat convection.
heat transfer (1 week)
CLO_10: Student will be able to describe velocity and thermal boundary layers.
KING ABDULAZIZ UNIVERSITY
FACUTY OF ENGINEERING
DEPARTMENT OF THERMAL ENGINEERING
AND DESALINATION TECHNOLOGY
Forced convection heat
transfer analysis for
external flows
(1.5 weeks)
CLO_11: Students will be able to solve basic heat transfer problems involving forced
convection over flat plates, circular cylinders, non-circular cylinders, spheres
and over bank of tubes
Forced convection heat
transfer analysis for internal CLO_12: Students will be able to solve basic heat transfer problems involving forced
flows
convection inside circular and non-circular ducts.
(1.5 weeks)
Natural convection
(1 week)
CLO_13: Students will be able to define natural convection.
CLO_14: Students will be able to solve basic heat transfer problems involving natural
convection over vertical plates, inclined plates, horizontal plates, vertical
cylinders, horizontal cylinders and spheres.
Thermal radiation
(1 week)
CLO_15: Students will be able to define thermal radiation, irradiation, radiosity, spectral
and total hemispherical emmisivity, transmissivity, absorptivity, reflectivity,
black body and gray body.
Radiation exchange
between surfaces
(1 week)
CLO_16: Students will be able to calculate basic radiation heat transfer problems between
gray surfaces
Heat transfer Laboratory
CLO_17: Students will be able to conduct, design and analyze experiments
6.
Class/Laboratory schedule:



Determination of thermal conductivity in solids.
Forced convection from cylinder in cross flow.
Determination of view factor.
KING ABDULAZIZ UNIVERSITY
FACUTY OF ENGINEERING
DEPARTMENT OF THERMAL ENGINEERING
AND DESALINATION TECHNOLOGY
MEP 360 HEAT TRANSFER: (4: 3, 1) –2nd Term 1428-1429H (2007-2008G)
Course content, assigned problems and grading policy
No. Chapter #: Subject
Included
Sections
1
Chapter 1: Introduction
1.1-1.6
2
Chapter 2: Introduction to Conduction
3
Chapter 3: 1-D Steady State
Conduction
Lab # (1)
4
5
Chapter 4: 2-D Steady State
Conduction
Chapter 5: Transient Conduction
6
7
Assigned problems
1.1, 1.4, 1.7, 1.19, 1.31, 1.42
2.1-2.4
2.5, 2.8, 2.17, 2.26, 2.31(a, b)
3.1, 3.3-3.6
4.4 -4.5
HW3(a) 3.2(a), 3.4(a,b), 3.9,
3.10, 3.21
HW3(b) 3.41, 3.44, 3.52,
3.61, 3.73
HW3(c) 3.116, 3.123, 3.125,
3.127, 3.140
4.46, 4.49
5.1,5.2, 5.4,5.6
5.7, 5.10, 5.37, 5.51, 5.59
Chapter 6: Introduction to Convection
6.1- 6.5
6.3, 6.7, 6.15
7.1-7.6
7.20, 7.21, 7.46, 7.68, 7.86
8
Chapter 7: External Flow
Lab # (2)
Chapter 8: Internal Flow
8.1-8.5
8.16(a,b), 8.26, 8.55, 8.53
9
Chapter 9: Free Convection
9.6
9.5, 9.13, 9.36, 9.52, 9.78
10
Chapter 12: Radiation Processes &
12.1-12.6
12.43, 12.51
Properties
11 Chapter 13: Radiation Exchange
13.1-13.2
13.1, 13.62, 13.70, 13.74
between surfaces
Lab # (3)
Course Exams
 1st Common Major Exam (4th Rabai I 1429H-12th March 2008G)
 2nd Common Major Exam (17th Rabai I 1429H-25th March 2008G)
 Midterm Exam (2nd Rabai II 1428H-8th April 2008G)
 3rd Common Major Exam (1st Jumada I 1429H-6th May 2008G)
 4th Common Major Exam (22nd Jumada I 1429H- 27th May 2008G)
 Final Exam (to be announced later)
Grading System
Course Portfolio…..……………………………………………… 5
Projects…………………………………………………………….5
Lab. Reports………………………………………………………10
Four Common Major Exams………….……………………..… 30
Common Mid-Term Exam…………………………….………. 20
Common Final Exam…………………………………….……. 30
Total
100
th
Text Book: Fundamentals of Heat and Mass Transfer 6 Edition
By Incorpera/DeWitt/Bergman/Lavine