SYLLABUS MAE 650:481 HEAT TRANSFER - SOE | Rutgers ...
SYLLABUS MAE 650:481 HEAT TRANSFER - SOE | Rutgers ...
SYLLABUS MAE 650:481 HEAT TRANSFER - SOE | Rutgers ...
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<strong>Rutgers</strong>, The State University of New Jersey<br />
<strong>SYLLABUS</strong><br />
<strong>MAE</strong> <strong>650</strong>:<strong>481</strong> <strong>HEAT</strong> <strong>TRANSFER</strong> (3 Cr.)<br />
SPRING 2011<br />
Course Information<br />
Catalog Description: Theory of heat transfer by steady and transient conduction. Heat<br />
transfer by radiation. Convection of heat by fluid motion in external<br />
and internal flow. Computational heat transfer - the finite difference<br />
method.<br />
Textbook: Introduction to Heat Transfer, 5 th ed., Incropera et al., John Wiley<br />
and Sons, 2006.<br />
Instructor: Prof. Zhixiong (James) Guo<br />
B241 Busch Campus Engineering Building<br />
Office Phone: 5-2024<br />
E-mail: zguo@rci.rutgers.edu<br />
http://coewww.rutgers.edu/radiation<br />
Electric Resources: Sakai@<strong>Rutgers</strong><br />
Lecture Time/Location: W 12:00 – 1:20 pm; F 1:40 – 3:00 pm / SEC-118 Busch<br />
Office Hours: Tue. 4:40 – 6:00 pm; Fri. 3:00 – 4:20 pm<br />
Teaching Assistant: Mr. Jiandong Meng, Rm. D122, Eng. Bldg.<br />
E-mail: jiandong@eden.rutgers.edu<br />
Prerequisite: Undergraduate thermodynamics and fluid mechanics<br />
Grading Policy: Homework 10%<br />
Quizzes 20%<br />
Midterm 30%<br />
Final 40%<br />
Notes: • Homework is collected every Wednesday before class and is<br />
subjected to selective correcting and grading.<br />
• Late homework will not be graded.<br />
• An alternative midterm exam will be given.<br />
• No make-up exams & quizzes.
Week Chapter Topics<br />
Tentative Course Schedule<br />
1 1 Introduction to HT<br />
2 2 Heat Conduction Theory and Thermal Properties<br />
3 3 Analysis of 1-D Steady State Conduction.<br />
4 4,5 2-D Steady State Conduction. Transient Conduction<br />
5 4,5 The finite difference method<br />
6 Midterm I and Review<br />
7 6 Introduction to Convection<br />
8 7 External Forced Convection.<br />
9 8 Internal Forced Convection<br />
10 9 Natural Convection.<br />
11 Midterm II and Review<br />
12 12 Introduction to Radiation<br />
13 13 Surface Radiation Exchange<br />
14 13 Combined HT and Overall Review<br />
15 Final Exam<br />
Learning Objectives<br />
• You should understand the meaning of the terminology & physical principles<br />
associated with the subject.<br />
• You should be able to delineate pertinent transport phenomena for any process or<br />
system involving heat transfer.<br />
• You should be able to use requisite inputs for analyzing/computing heat transfer rates<br />
and/or material temperature distributions.<br />
• You should be able to develop representative models of real processes & systems and<br />
draw conclusions concerning process/system design or performance from attendant<br />
analysis.
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