Issue date: 01.10.2019

Revision date: 01.10.2019

Revision No: 00

DF Board Decision No: -

Course Name : Heat Transfer

Degree: Bachelor

Code

Year/Semester

Local Credits

ECTS Credits

Course Implementation, Hours/Week

Course

Tutorial

Laboratory

SMME311

3/5 (Fall)

2.5

2

2

1

0

Department

Marine Engineering

Instructors

Contact Information

Office Hours

Web page

Course Type

 Compulsory

Course Language

English

Course Prerequisites

  SMME211

Course Category by Content, %

Basic Sciences

Engineering Science

Engineering Design

Humanities

20

30

50

0

Course Description

Intoduction and basic concepts of heat transfer. Heat conduction; steady, transient, numerical methods. Heat convection; external and internal, forced and natural. Boiling and condansation. Radiation heat transfer and  heat exchangers.

Course Objectives

• To make students understand the basic principles of heat transfer.
• To give students understanding for how heat transfer  can be applied to actual engineering applications.
• To develop basic engineering skill to analyse and  design.  thermodynamical systems and plants involving heat transfer.

Course Learning Outcomes

Students will acquire knowledge and skills as listed below.

1. Identify and explain basic concepts of heat transfer mechanisms.
2. Introduce the concept of conduction heat transfer.
3. Solve the steady and transient conduction problems.
4. Solve the basic steady and transient conduction problems using numerical methods.
5. Introduce the basics of heat convection,
6. Define the dimensionless Reynolds, Prandtl, and Nusselt numbers, and their physical significance.
7. To solve the external forced convection problems over a flat plate, cylinders and spheres for laminar and turbulent flows.
8. To derive the convection equations.
9. Introduce, external forced convection: Parallel flow over a flat plate, flow across cylinders and spheres, flow across tube banks.
10. Drive Equation of motion for the Natural convection. Define and Grashof number. Solve the problems heat transfer over surfaces, from finned surfaces, inside enclosures, combined forced and natural convection.
11. Understand the boiling heat transfer mechanism and solve the problems about pool boiling, flow boiling. Understand the condensation heat transfer and film condensation and solve problems  inside horizontal tubes, and dropwise condensation.
12. Understand the fundamentals of thermal radiation, blackbody radiation, radiation intensity, atmospheric and solar radiation.
13. Analyze radiation heat transfer: black surfaces, diffuse, gray surfaces, radiation shields, solve problems about radiation exchange.
14. Identify heat exchanger types.  Find the overall heat transfer coefficient, and log mean temperature difference, the effectiveness NTU method, selection of heat exchangers. 

Instructional Methods and Techniques

Discourse, discussion, presentation.

Tutorial Place

Class room

Co-term Condition

Textbook

Heat Transfer: A Practical Approach with EES CD, second edition.
Yunus Cengel

Other References

Heat Transfer, Jack P Holman (Author) 7th edition.

Homework & Projects

Projects and homeworks will be assigned. 

Laboratory Work

non

Computer Use

EES and matlab software programs will be used.

Other Activities

Assessment Criteria

Activities

Quantity

Effects on Grading, %

Attendance

Midterm

1

30

Quiz

2

20

Homework

Term Paper/Project

Laboratory Work

Practices

Tutorial

Seminar

Presentation

Field Study

Final Exam

1

50

TOTAL

%100

Effects of Midterm on Grading, %

%30

Effects of Final on Grading, %

%50

TOTAL

%100

ECTS/

WORKLOAD TABLE

Activities

Count

Hours

Total

Workload

Lecture

14

3

42

Midterm

1

10

10

Quiz

2

4

8

Homework

Term Paper/Project

Laboratory Work

Practices

Tutorial

Seminar

Presentation

Field Study

Final Exam

1

15

15

Total Workload

75

Total Workload/25

75/25

Course ECTS Credits

3

Week

Topics

Course Outcomes

1

Basic concepts of heat transfer mechanisms.

I

2

The concept of conduction heat transfer,

I-II

3

Steady and transient conduction problems.

I-III

4

Basic steady and transient conduction problems using numerical methods.

IV

5

The basics of heat convection:Reynolds, Prandtl, and Nusselt numbers, external forced convection problems over a flat plate, cylinders and spheres for laminar and turbulent flows.

V,VI,VII

6

Convection equations.External forced convection: Parallel flow over a flat plate, flow across cylinders and spheres, flow across tube banks.

VIII,IX, X

7

Natural convection: Grashof number. Natural convection over surfaces, from finned surfaces, inside enclosures, combined forced and natural convection

X

8

Natural convection: Grashof number. Natural convection over surfaces, from finned surfaces, inside enclosures, combined forced and natural convection

X

9

Midterm exam

10

Boiling heat transfer, pool boiling, and flow boiling. Condensation heat transfer, film condensation, inside horizontal tubes, and dropwise condensation.

XI

11

Fundamentals of thermal radiation, blackbody radiation, radiation intensity, atmospheric and solar radiation.

XII

12

Analysis of radiation heat transfer: black surfaces, diffuse, gray surfaces, radiation shields, problems about radiation exchange.

XIII

13

Heat exchanger types,  overall heat transfer coefficient, log  mean temperature difference, the effectiveness NTU method, selection of heat exchangers, project presentations.

XIV

14

Heat exchanger types.  overall heat transfer coefficient, log  mean temperature difference, the effectiveness NTU method, selection of heat exchangers, projects presentations.

XIV

Program Outcomes

Level of Contribution

1

2

3

a

An ability to apply knowledge of mathematics, science, and engineering

X

b

An  ability to design and conduct experiments, as well as to analyze and interpret data

X

c

An ability to design a system, component or process to meet desired needs

X

d

Ability to function on multi-disciplinary teams

X

e

An ability to identify, formulate, and solve engineering problems

X

f

An understanding of professional and ethical responsibility

X

g

An ability to communicate effectively

X

h

The broad education necessary to understand the impact of engineering solutions in a global and societal context

X

i

A recognition of the need for, and an ability to engage in life-long learning

X

j

A knowledge of contemporary issues

X

k

An ability to use the techniques, skills and modern engineering tools necessary for engineering practice

X

l

An ability to apply legal, societal and environmental knowledge in maritime transport and in all respective modes of transport operations.

X

m

An ability to interpret and analysis of the data regarding maritime management and operations, recognition and solution of problems for decision making process.

X

Course

Outcomes

I

II

III

IV

V

VI

VII

VIII

IX

X

XI

XII

XIII

Programme Outcomes

a

X

X

X

X

X

X

X

X

X

X

X

X

X

b

X

X

X

X

X

X

X

X

X

X

X

X

X

c

X

X

X

X

X

X

X

X

X

X

X

X

X

d

X

X

X

X

X

X

X

X

X

X

X

X

X

e

X

X

X

X

X

X

X

X

X

X

X

X

X

f

g

h

i

X

X

X

j

k

X

X

X

X

X

X

X

X

X

X

X

X

X

l

X

X

X

m