Advanced Radiation Heat Transfer

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Nov 14, 2013 (3 years and 4 months ago)

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Course Title

Advanced Radiation Heat Transfer

Department

Mechanical Engineering

Division in the Dept.

Mechanical Engineering


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

MME 501

Fall

MSc

Optional

English

3

0

3

7



Name of Instructors

Assoc. Prof. Dr. Yunus ÇERÇİ

Instructor
Contact
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical
Engineering, Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 1258) e
-
mail:ycerci@adu.edu.tr

Course Object
ive and
brief Description

The aim of this course is to inform engineering methods about radiation which is one of
the heat transfer modes.

Textbook and Supplementary readings

1

Modest, M.F., Radiative Heat Transfer, Academic Press, 2nd Edition, 2003.

2

Incropera, F.P., DeWitt, D. P., Fundamentals of Heat and Mass Transfer, 5th edition, Wiley, 2001.

3

Siegel, R., Thermal Radiation Heat Transfer, 4
th

edition, Taylor & Francis, 2001.


COURSE CALANDER / SCHEDULE

Week

Lecture topics

Laboratory

1

Fundamenta
ls of Radiation


2

Direct Heat Transfer With Radiation


3

Total Heat Transfer With Radiation in a Closed Volume Enclosed By
Non
-
Absorptive Environment


4

Total Heat Transfer with Radiation in a Closed Volume Enclosed By
Absorptive Environment


5

Applic
ations of Heat Transfer


6

Radiation
-
Convection
-
Conduction Triple Boundary Condition


7

Midterm Exam



8

Temperature Measurement with Radiation


9

Kirchoff Laws


10

Monte
-
Carlo Methods


11

Determination of Mean Rays


12

Radiation by a Black Body in
Definite Wave Integrals


13

Emissivity of Atmosphere Containing CO2 and Vapor, Solar Radiation


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam
and 60 % for the final exam. Depending on
instructor’s preference, assessment may be b
y written or/and oral examination, homework, lab assay, projects,
group presentation, or a combination of these.


2



Course Title

Advanced Conduction Heat Transfer

Department

Mechanical Engineering

Division in the Dept.

Mechanical Engineering


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

MME 503

Fall

MSc

Optional

English

3

0

3

7



Name of Instructors

Assoc. Prof. Dr. Yunus ÇERÇİ

Instructor
Contact
Information

Adnan Menderes University, Faculty of Engineering, D
epartment of Mechanical
Engineering, Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 1258) e
-
mail:ycerci@adu.edu.tr

Course Objective and
brief Description

The aim of this course is to provide the student with general mathematical teniques and

basic numerical methods used to solve advanced heat conduction problems

Textbook and Supplementary readings

1

Yener, Y., Kakaç S., Heat Conduction, 4
th

edition, Taylor & Francis, 2008.

2

Özışık, M. N., Heat Conduction, 2nd edition, Wiley
-
Interscience,

1993

3

Jiji, M.L., Heat Conduction, 3
rd

edition, Springer, 2009.


COURSE CALANDER / SCHEDULE

Week

Lecture topics

Laboratory

1

Foundations of heat transfer, general heat conduction equation


2

One
-
dimensional steady heat conduction


3

Orthogonal func
tions, fourier expansions and finite fourier transforms


4

Steady Two
-
and Three dimensional heat conduction:solutions with
separation of variables


5

Steady Two
-
and Three dimensional heat conduction:solutions with
separation of variables


6

Unsteady hea
t conduction: solutions with separation of variables


7

Midterm Exam



8

Solutions with integral transforms


9

Solutions with integral transforms


10

Numerical solutions


11

Numerical solutions


12

Futher methods of solution


13

Futher methods of so
lution


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the final exam. Depending on instructor’s
preference, assessment may be by written or/and oral examination, homework, lab assay, projects, group
presentation, or a

combination of these.


3



Course Title

Heat Exhangers

Department

Mechanical Engineering

Division in the Dept.

Mechanical Engineering


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

MME 505

Fall

MSc

Optional

Englis
h

3

0

3

7



Name of Instructors

Assoc. Prof. Dr. Yunus ÇERÇİ

Instructor
Contact
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical
Engineering, Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 1258) e
-
mail:ycerci@adu.edu.tr

Course Object
ive and
brief Description

The aim of this course is to provide the students with common types of heat exchangers;
namely hair
-
pin, shell
-
and
-
tube, gasket
-
plate, and compact heat exchangers, fouling of
surfaces, fouling in designs, rating and sizing problem
s in heat exchanger design.

Textbook and Supplementary readings

1

Kakac, S., Pramuanjaroenkij, A., Liu, H., Heat Exchangers: Selection, Rating and Thermal Design, 2
nd

edition,
CRC Press, 2002.

2

Kays, W.M., London A.L., Compact Heat Exhangers, 3rd editi
on, Krieger Publishing Company, 1998.

3

Shah, R.K., Sekulic D.P., Fundamentals of heat exchanger desingn, 1
st

edition, Wiley, 2002.


COURSE CALANDER / SCHEDULE

Week

Lecture topics

Laboratory

1

Classification of heat exchangers


2

Fundamental Definition
s


3

Temperature Profiles in Steady Conditions


4

Variable Heat Transfer Temperature Coefficients


5

Design of Heat Exchangers With Fins


6

Design of Evaporators


7

Midterm Exam



8

Design of Compact Heat Exchangers


9

Air
-
Cooled Heat Exchangers


1
0

Shell
-
and
-
Tube Reboilers


11

Pressure Drop In Heat Exchangers


12

Pressure Drop In Heat Exchangers


13

Material Selection and Stress Calculations In Heat Exchangers


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for
the final exam. Depending on instructor’s
preference, assessment may be by written or/and oral examination, homework, lab assay, projects, group
presentation, or a combination of these.


4



Course Title

Finite Element Analysis

Department

Mechanical Engine
ering

Division in the Dept.

Mechanical Engineering


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

MME 507

Fall

MSc

Optional

English

3

0

3

7



Name of Instructors

Assoc. Prof. Dr. Yunus ÇERÇİ

Instructor
Contact
I
nformation

Adnan Menderes University, Faculty of Engineering, Department of Mechanical
Engineering, Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 1258) e
-
mail:ycerci@adu.edu.tr

Course Objective and
brief Description

The objective of the cou
rse is to teach the basic fundamentals of finite element method
with emphasis on the underlying theory, assumptions, and modeling issues as well as

providing hands on experience using finite element software to model, analyze and
design systems of relevanc
e to engineers
.

Textbook and Supplementary readings

1

Hughes
T.

J. R,
The Finite Element Method: Linear Static and Dynamic

Finite Element Analysis
,

Dover
Publications,

2000
.

2

Bathe
K.

J.,
Finite Element Procedures
, Prentice
-
Hall, 1996
.

3

Reddy J. N.,
An Introduction to the Finite
-
Element Method
,
3r
d edition, McGraw
-
Hill
, 2005.


COURSE CALANDER / SCHEDULE

Week

Lecture topics

Laboratory

1

Introduction to finite element analysis


2

Review of basic concepts in math and mechanics


3

1D and 2D finite ele
ment methods


4

Steady and unsteady advection
-
diffussion problems


5

Different stabilized formulations of incompressible mometum equations


6

Direct and iterative techniques for the solution of linear algebraic
systems


7

Midterm Exam



8

Heat transfe
r problems with free and forced convection


9

Heat transfer problems with free and forced convection


10

Error estimation and adaptive refinement


11

Formulation and fluid structure interaction


12

Other advanced topics


13

Other advanced topics


1
4

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the final exam. Depending on instructor’s
preference, assessment may be by written or/and oral examination, homework, lab assay, projects, group
presentation, or a combinati
on of these.


5



Course Title

Fundamentals and Applications of Hydrogen Energy

Department

Mechanical Engineering

Division in the Dept.

Mechanical Engineering


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

MME 509

Fall

MSc

Optional

English

3

0

3

7



Name of Instructors

Assoc. Prof. Dr. Yunus ÇERÇİ

Instructor
Contact
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical
Engineering, Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 1258) e
-
mail:ycerci@adu.edu.tr

Course Object
ive and
brief Description

The objective of the course is to teach the fundamentals and applications of hydrogen
energy.

Textbook and Supplementary readings

1

Press, R.J., Santhanam K.S.V., Miri J.M., Bailey, A.V., Takacs, G.A., Introduction to Hydrogen T
echnology,
Wiley
-
Interscinece, 2008.

2

Williams, L.O., Hydrogen Power: An Introduction to Hydrogen Energy and Its Applications, 1st edition,
Pergamon Pr, 1980.

3

Lymberopoulos, N., Hydrogen
-
based autonomous power systems: techno
-
economic analysis of the
integration
of hydrogen in autonomous power systems, 1
st

edition, Springer, 2008.


COURSE CALANDER / SCHEDULE

Week

Lecture topics

Laboratory

1

Hydrogen Production Techniques


2

Steam reforming of hydrocarbons


3

Partial oxidation, solar generation of h
ydrogen from water



4

Phot
ovoltaic cell plus electrolyzer,

p
hotoelectrochemical cells


5

Photobiological systems, Photodegradation systems


6

Hydrogen usage as fuel in internal combustion engines


7

Midterm Exam



8

Hydrogen usage
steam generation fo
r steam turbines and in fuel cells


9

Hydrogen storage techniques: Gas storage, Liquid storage, Storage in
porous media


10

Hydrogen storage techniques: Gas storage, Liquid storage, Storage in
porous media


11

Hydrogen storage techniques: Gas storage, L
iquid storage, Storage in
porous media


12

Hydrogen safety.


13

Hydrogen safety.


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the final exam. Depending on instructor’s
preference, assessment may be by written or/a
nd oral examination, homework, lab assay, projects, group
presentation, or a combination of these.







6


Course Title

Mechatronics

Department

Mechanical Engineering

Division in the Dept.

Mechanical Engineering


Code

Term

Level

Type

Language

Credit hours
/week

Lecture

Lab

Credit

ETSC
Credit

MME 511

Fall

MSc

Optional

English

3

0

3

7




Name of
Instructors

Assoc. Prof. Dr.
İsmail BÖĞREKCİ

Instructor
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical Engineering,
Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 12
81
)


e
-
mail:
ibogrekci
@adu.edu.tr

Course Objective
and b
rief
Description

The
aim of this course is to teach the design of a mechatronic system

Textbook and Supplementary readings

1

William Bolton, “Mechatronics a multidisiplinary approach” Essex, England, Pearson education Ltd. 2008

2

Sabri Çetinkunt, “Mech
atronics” John Willey and Sons, Inc. 2007

3

David G Algiatore and Michael B Histand, “Introduction to Mechatronics and Measurement Systems” Mc
Graw Hill

COURSE CALANDER / SCHEDULE

Week

Lecture topics

Laboratory

1

Sensors and transducers


2

Signal acqu
isition and conditioning


3

Signal processing


4

Mechanical, hydraulic and pneumatic systems


5

Electrical and Electronical systems


6

System modelling, dynamic response and transfer functions


7

Midterm
Exam


8

Digital logic


9

Microprocessors


10

Programming Languages


11

Programmable logic controller


12

Communication systems


13

Mechatronics project


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam

and 60 % for the final exam. Depending on
instructor’s preference, asse
ssment may be by written or/and oral examination, homework, lab assay, projects,
group presentation, or a combination of these.












7




Course Title

Instrumentation a
nd Control

Department

Mechanical Engineering

Division in the Dept.

Mechanical Engin
eering


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

MME 513

Fall

MSc

Optional

English

3

0

3

7



Name of
Instructors

Assoc. Prof. Dr.
İsmail BÖĞREKCİ

Instructor
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical Engineering,
Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 12
81
)


e
-
mail:
ibogrekci
@adu.edu.tr

Course Objective
and b
rief
Description

The
aim of this course is to teach the Fundamentals of Instrumentation and Control and
implement these into practice.

Textbook and Supplementary readings

1

NJATC, “
Fundamentals of Instrumentation


Delmar Cengage Learning; 2 edition (Marc
h 19, 2008)

ISBN
-
10: 1418073512

ISBN
-
13: 978
-
1418073510

2

Terry L.M. Bartelt
, “
Instrumentation and Process Control


Delmar Cengage Learning; 1 edition (November 28,
2006) ISBN
-
10: 1418041718 ISBN
-
13: 978
-
1418041717

3

William Dunn
, “
Fundamentals of Indus
trial Instrumentation and Process Control

McGraw
-
Hill Professional; 1
edition (March 31, 2005) ISBN
-
10: 0071457356
I
SBN
-
13: 978
-
0071457354

COURSE CALANDER / SCHEDULE

Week

Lecture topics

Laboratory

1

Measurement Concept


2

Electrical and electronic meas
urement ( Electrical measuring
instruments, power and energy measurement, magnetic measurements)


3

Electrical and electronic measurement (Process measurements: Level,
Flow, pressure, temperature etc. Measurement)


4

Electrical and electronic measurement

(Process measurements:
Dimension, viscosity, pH, Force, Torque, speed etc. Measurement)


5

Automatic control systems (Process control, Transfer functions)


6

Automatic control systems ( Automatic controllers and applications)


7

Midterm
Exam


8

Compu
ter aided control (Sensors and transducers)


9

Computer aided control (Transmitters, Telemetry systems and
recorders)


10

Computer aided control (Computer aided measurement and control
systems)


11

Instrument selection and commisioning (Programmable log
ic
controllers)


12

Instrument selection and commisioning (Distributed control systems)


13

Instrumentation and control project


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the final exam. Depending on instructor’
s
preference, assessment may be by written or/and oral examination, homework, lab assay, projects, group
presentation, or a combination of these.





8



Course Title

Machine Desi
gn

Department

Mechanical Engineering

Division in the Dept.

Mechanical Engineer
ing


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

MME 515

Fall

MSc

Optional

English

3

0

3

7



Name of
Instructors

Assoc. Prof. Dr. İsmail BÖĞREKCİ

Instructor
Information

Adnan Menderes University, Faculty of Engi
neering, Department of Mechanical Engineering,
Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 12
81
)


e
-
mail:
ibogrekci
@adu.edu.tr

Course Objective
and brief
Description

The
aim of this course is to teach the Fundamentals Machine Desig
n and design and
manufacture a machine.

Textbook and Supplementary readings

1

Robert L. Norton
, “
Machine Design: An Integrated Approach

Prentice Hall; 3 edition (May 20, 2005) ISBN
-
10: 0131481908 ISBN
-
13: 978
-
0131481909

2

Robert C. Juvinall and Kurt M
. Marshek
, “
Fundamentals of Machine Component Design

Wiley; 4 edition
(August 2, 2005) ISBN
-
10: 0471661775 ISBN
-
13: 978
-
0471661771

3

Robert L. Mott
, “
Machine Elements in Mechanical Design

Prentice Hall; 4 edition (July 26, 2003)

ISBN
-
10: 0130618853 ISB
N
-
13: 978
-
0130618856

COURSE CALANDER / SCHEDULE

Week

Lecture topics

Practice/Lab/Field

1

Machine design fundamentals


2

Machine elements


3

Machine elements


4

Machine design Project (Financial and economical analysis)


5

Machine design Project (Soli
d state modelling and drawings)


6

Machine design Project (Solid state modelling and drawings)


7

Midterm
Exam


8

Machine design Project (Solid state modelling and drawings)


9

Machine design Project (Solid state modelling and drawings)


10

Machine de
sign Project (FEA analysis)


11

Machine design Project (Dynamic simulation)


12

Machine design Project (Manufacturing)


13

Machine design Project (Manufacturing)


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the f
inal exam. Depending on instructor’s
preference, assessment may be by written or/and oral examination, homework, lab assay, projects, group
presentation, or a combination of these.









9

Course Title

Elementary Nanotechnology a
nd Nanometrology

Department

Mechanical Engineering

Division in the Dept.

Mechanical Engineering


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

MME 517

Fall

MSc

Optional

English

3

0

3

7



Name of
Instructors

Ass. Prof. Dr. Pınar DEMİRCİOĞLU

Instructor
Contact
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical
Engineering, Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 12
42
)

e
-
mail:
p
i
nar.demircioglu
@adu.edu.tr

Course Objective
and

brief
Description

The aim of this course is to inform students about nanotechnology and nanometrology. In
this course, new methods in the field of nanotechnology will be studied on.


Textbook and Supplementary readings

1

Charles P. Poole Jr., Frank J. O
wens, “Introduction to Nanotechnology”, Wiley

2

Whitehouse D.J., “Handbook of Surface and Nanometrology”, Institute of Physics, Bristol, (published in 1994),
2003, ISBN: 0

3

Taniguchi N.: On the basic concept of nanotechnology.


In: Proc. Int. Conf. Pro
d. Eng. Tokyo, 1974, part 2,
Tokyo: JSP4, 18

4

Whitehouse D.J.: Nanotechnology instrumentation.


Measurement + Control, 24 1991, No 2, 37

5

Binnig H., Rohrer H.: Scanning tunnelling microscopy.


Helv. Phys. Acta, 55, 1982, 726

COURSE CALENDAR / SCHEDU
LE

Week

Lecture topics

Laboratory

1

Workpiece accuracy and technical product specification


2

Metrology in precision engineering.


3

Development and state
-
of
-
the
-
art in precision engineering


4

Precision machining production techniques


5

Precision ma
chining limits and measurement sensitivities


6

Developments and requirements on instrumentation in nanotechnology


7

Midterm Exam


8

Instrumentation in nanotechnology


9

Stylus Contact Instruments and Optical Methods


10

Scanning tunneling and atomic

force microscopy


11

Building things with atoms


12

One atom
-
at
-
a
-
time construction of things


13

Atom manipulation


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the final exam. Depending on instructor’s
preferen
ce, assessment may be by written or/and oral examination, homework, lab assay, projects, group
presentation, or a combination of these.


10



Course Title

Qual
ity Engi
neer
ing i
n Product
i
on Systems

Department

Mechanical Engineering

Division in the Dept.

Mech
anical Engineering


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

MME 519

Fall

MSc

Optional

English

3

0

3

7




Name of
Instructors

Ass. Prof. Dr. Pınar DEMİRCİOĞLU

Instructor
Contact
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical
Engineering, Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 12
42
)

e
-
mail:
p
i
nar.demirciogl
u
@adu.edu.tr

Course Objective
and brief
Description

The course
will

give a deeper understanding within production and quality engineering.


Textbook and Supplementary readings

1

G. Taguchi, E.A. Elsayed and T. Hsiang,

Quality Engineering in Production
Systems

,

McGraw
-
Hill, New
York, 1989
, ISBN:
978
-
0070628304
, 192.

2

Osanna P.H.,
Durakbasa M.N., Afjehi
-
Sadat A.,


Quality in Industry
”,

Mar

2004,
printed in Austria (TU Wien:
Abteilung Austauschbau und Mes
stechnik),

ISBN: 3
-
901888
-
23
-
3,

147.

COURSE CA
LENDAR / SCHEDULE

Week

Lecture topics

Laboratory

1

Introduction to quality


2

General terms and definitions for quality management


3

Quality in production systems


4

Quality management philosophies and awards


5

Total quality management


6

Product r
ealization


7

Midterm Exam


8

Metrology and inspection


9

Quality management and Integration in modern production environment


10

Quality management system


11

Quality management system and tools for quality


12

Quality evaluation and quality improve
ment methods


13

The design of experiments to quality


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the final exam. Depending on instructor’s
preference, assessment may be by written or/and oral examination, homewor
k, lab assay, projects, group
presentation, or a combination of these.






11



Course Title

Advance Heat Convection

Department

Mechanical Engineering

Division in the Dept.

Mechanical Engineering


Code

Term

Level

Type

Language

Credit hours/week

Lec
ture

Lab

Credit

ETSC
Credit

MME 502

Spring

MSc

Optional

English

3

0

3

7



Name of Instructors

Assoc. Prof. Dr. Yunus ÇERÇİ

Instructor
Contact
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical
Engineering, Main Camp
us, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 1258) e
-
mail:ycerci@adu.edu.tr

Course Objective and
brief Description

The objective of the course is to provide students with insight into the nature of
convection problems physically and matematically,
and ability to understand and explain
convection phenomena.

Textbook and Supplementary readings

1

Kays, W.M., Crawford M.E., Convective Heat and Mass Transfer, 3
rd

edition, McGraw
-
Hill.

2

Kakaç, S., Yener Y., Convective Heat Tranfer, 2nd edition, CRC
-
P
ress, 1995.

3

Bejan, A., Convection Heat Tranfer, Wiley, 3
rd

edition, 2004.


COURSE CALANDER / SCHEDULE

Week

Lecture topics

Laboratory

1

Inroduction to Advanced Heat Convection


2

Heat Convection Coefficient


3

Boundary Layer Theory:Hydrodynamic Bound
ary Layer


4

Thermal Boundary Layer, Laminar and Turbulent Flows


5

Conservation Equations:Continuum Equation, Impulse Equation,
Energy Equation


6

Boundary Layer Similarities


7

Midterm Exam



8

Reynolds
-
Colburn Similarities


9

Forced Convection: Ex
ternal Flow


10

Laminar Boundary Layer Over Flat Plates


11

Energy Intergral Equat
ion, Turbulent Paralell Flows O
ver Flat Plate


12

Staggered Flows Around Cylinders and Spheres, Internal Flows,
Velocity Profiles in Laminar and Turbulent Flows


13

Bound
ary Conditions and Energy Equations for Internal Flows, Natural
Convection.


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the final exam. Depending on instructor’s
preference, assessment may be by written or/and oral

examination, homework, lab assay, projects, group
presentation, or a combination of these.


12



Course Title

Advance Thermodynamics

Department

Mechanical Engineering

Division in the Dept.

Mechanical Engineering


Code

Term

Level

Type

Language

Credit hour
s/week

Lecture

Lab

Credit

ETSC
Credit

MME 504

Spring

MSc

Optional

English

3

0

3

7



Name of Instructors

Assoc. Prof. Dr. Yunus ÇERÇİ

Instructor
Contact
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical
Engine
ering, Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 1258) e
-
mail:ycerci@adu.edu.tr

Course Objective and
brief Description

The course offers
Thermodynamic

laws of closed and open systems,

energy destruction
,

property relations, single phase

systems, Gibbs
-
Duhem relations,
multiphase systems,
equilibrium, and
engineering applications.

Textbook and Supplementary readings

1

Bejan, A., Advanced Engineering Thermodynamics, 3
rd

edition, Wiley, 2006.

2

Winterbone, D., Advanced Thermodynamics for

Engineers, Butterworth
-
Heinemann, 1996.

3

Annamalai, A., Advanced Thermodynamics Engineering, 1
st

edition, CRC press, 2001.


COURSE CALANDER / SCHEDULE

Week

Lecture topics

Laboratory

1

Introduction
-

descriptions of terms


2

First law of thermodyanmics


3

Availability


4

Availability


5

Gibbsian Thermodynamics


6

State Relationships for real gasses and liquids


7

Midterm Exam



8

Thermodynamic properties for pure fluids


9

Thermodynamic properties of mixtures


10

Phase equilibrium for mixtures


11

Stability


12

Reaction direction and chemical equilibrium


13

Availability analysis for reacting systems


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the final exam. Depending on instructor’s
preference, asses
sment may be by written or/and oral examination, homework, lab assay, projects, group
presentation, or a combination of these.


13



Course Title

Heat Pipes Theory and Applications

Department

Mechanical Engineering

Division in the Dept.

Mechanical Engineer
ing


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

MME 506

Spring

MSc

Optional

English

3

0

3

7



Name of Instructors

Assoc. Prof. Dr. Yunus ÇERÇİ

Instructor
Contact
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical
Engineering, Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 1258) e
-
mail:ycerci@adu.edu.tr

Course Object
ive and
brief Description

This course offers basic and advanced techniques in the analytical and numerical
modeling of various heat pipe systems under a variety of operating conditions and
limitations, and the variety of complex and coupled processes of he
at and mass transfer in
heat pipes.

Textbook and Supplementary readings

1

Reay, D., Kew P., Heat Pipes: Theory, Design, and Applications, 5
th

edition, Butterwoth
-
Heinemann, 2006.

2

Faghri, A., Heat Pipe Science and Technology, Taylor & Francis, 1st edi
tion, 1995.

3

Peterson, G.P., An Introduction to Heat Pipes:Modelling, Testing, and Applications, Wiley
-
Interscience, 1994


COURSE CALANDER / SCHEDULE

Week

Lecture topics

Laboratory

1

Types and Applications of Heat Pipe


2

Working Fluids


3

Weak Mater
ials, Control Methods, Heat Characteristics


4

Heat Pipes Theory


5

Heat Pipes Theory


6

Capilary Limitation and Temperature Characteristics


7

Midterm Exam



8

Sonic, Drag, and Boiling Limitations


9

Heat Pipes Design and Design Samples


10

Heat Pi
pes Design and Design Samples


11

Construction of Heat Pipes


12

Various Applications of Heat Pipes in Energy Systems


13

Various Applications of Heat Pipes in Energy Systems


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
6
0 % for the final exam. Depending on instructor’s
preference, assessment may be by written or/and oral examination, homework, lab assay, projects, group
presentation, or a combination of these.



14



Course Title

Advanced Solar Engineering

Department

Mecha
nical Engineering

Division in the Dept.

Mechanical Engineering


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

MME 508

Spring

MSc

Optional

English

3

0

3

7



Name of Instructors

Assoc. Prof. Dr. Yunus ÇERÇİ

Instru
ctor
Contact
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical
Engineering, Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 1258) e
-
mail:ycerci@adu.edu.tr

Course Objective and
brief Description

The course

introduces students to the applications of solar energy as an alternavite source
of energy, and aims at enhancing the students understanding on solar energy avalilabitiy,
collection, and potential utilization of solar energy.

Textbook and Supplementary
readings

1

Kalogirou, S., Solar Energy Engineering:Processes and Systems, Academic Press, 2009.

2

Duffie, J.A., Beckman W.A., Solar Engineering of Thermal Processes, 3
rd

edition, Wiley
, 2006.


3

Goswami, D. Y., Kretih, F., Kreider J.F., Principles of So
lar Engineering, , 2
nd

edition, CRC Press, 2000.


COURSE CALANDER / SCHEDULE

Week

Lecture topics

Laboratory

1

Solar Radiation


2

Solar Radiation


3

Available solar radiation


4

Selected heat transfer topics


5

Raditation characteristics of opague mat
erials


6

Radiation transmission through glazing, absorbed radiation


7

Midterm Exam



8

Flat
-
plate collectors


9

Flat
-
plate collectors


10

Concentrating collectors


11

Energy storage


12

System thermal calculations


13

Solar water heating active a
nd passive


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the final exam. Depending on instructor’s
preference, assessment may be by written or/and oral examination, homework, lab assay, projects, group
presentation,
or a combination of these.


15



Course Title

Com
puter Aided Analysis of Thermal Systems

Department

Mechanical Engineering

Division in the Dept.

Mechanical Engineering


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

M
M
E 5
10

Spring

MSc

Optional

English

3

0

3

7



Name of Instructors

Assoc. Prof. Dr. Yunus ÇERÇİ

Instructor Contact
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical
Engineering, Main Campus, Aytepe, 09010 Aydın. Tel
: (256) 218 2000 (ext. 1258) e
-
mail:ycerci@adu.edu.tr

Course Objective and
brief Description

The course offers the modeling of various types of heat transfer problems, and the
solution of these models by employing software packages and programming langua
ges.

Textbook and Supplementary readings

1

Myers, G.E.,
A
nalytical Methods in Conduction
Heat Transfer
,
Amcht Publications, 2nd edition, 1998.

2

Moaveni, S.,
Finite Element Analysis Theory and Application with ANSYS, Prentice Hall, 3rd edition, 2007
.

3

Lewis, R. W. Fundamentals of the Finite Element Method for Heat and Fluid Flow, 1
st

edition, Wiley, 2004.


COURSE CALANDER / SCHEDULE

Week

Lecture topics

Laboratory

1

Introduction to heat tranfer


2

Finite difference equations in cartesian koor.


3

Finite difference equations in cartesian koor.


4

Finite difference eq
uations in cartesian koor.


5

Computer aided solution of steady heat transfer problems


6

Computer aided solution of unsteady heat transfer problems


7

Midterm Exam



8

Computer aided solution of unsteady heat transfer problems


9

Introduction to fini
te elements in heat transfer problems


10

Solution of one
-
dimensional steady heat transfer problems


11

Computer aided solution of one
-
dimensional steady heat transfer
problems


12

Solution of two
-
dimensional steady heat transfer problems


13

Solution
of unsteady heat transfer problems


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the final exam. Depending on instructor’s
preference, assessment may be by written or/and oral examination, homework, lab assay, projec
ts, group
presentation, or a combination of these.


16










Course Title

Roboti
cs

Department

Mechanical Engineering

Division in the Dept.

Mechanical Engineering


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

MME
512

Spring

MSc

Optional

English

3

0

3

7




Name of
Instructors

Assoc. Prof. Dr. İsmail BÖĞREKCİ

Instructor
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical Engineering,
Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 12
81
)


e
-
mail:
ibogrekci
@adu.edu.tr

Cours
e Objective
and brief
Description

The
aim of this course is to teach the Fundamentals of Robot technology and Robot design.

Textbook and Supplementary readings

1

Reza N. Jazar
, “
Theory of Applied Robotics: Kinematics, Dynamics, and Control


Springer; 2nd

ed. edition
(July 1, 2010) ISBN
-
10: 1441917497 ISBN
-
13: 978
-
1441917492

2

David Cook
, “
Robot Building for Beginners (Technology in Action)

Apress; 2 edition (January 6, 2010)

ISBN
-
10: 1430227486 ISBN
-
13: 978
-
1430227489

3

Maja J. Matari
, “
The Robotics P
rimer (Intelligent Robotics and Autonomous Agents)

The MIT Press
(September 30, 2007) ISBN
-
10: 026263354X ISBN
-
13: 978
-
0262633543

COURSE CALANDER / SCHEDULE

Week

Lecture topics

Laboratory

1

Robotics and robotic manipulators


2

Rotation matrices


3

Hom
ogeneous transformations


4

Direct and inverse kinamatics


5

Jacobian matrix


6

Velocity and acceleration analyses


7

Midterm
Exam


8

Dynamic force analysis via Newton
-
Euler formulation


9

Motion equations


10

Trajectory planning


11

Independent j
oint control with computed torque method


12

Compliant motion control


13

Hybrid control with position and force feedbacks


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the final exam. Depending on instructor’s
pre
ference, assessment may be by written or/and oral examination, homework, lab assay, projects, group
presentation, or a combination of these.


17



Course Title

Sensor Materials and Design

Department

Mechanical Engineering

Division in the Dept.

Mechanical Eng
ineering


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

M
M
E 514

Spring

MSc

Optional

English

3

0

3

7




Name of
Instructors

Assoc. Prof. Dr.

İsmail BÖĞREKCİ

Instructor
Information

Adnan Menderes University, Faculty

of Engineering, Department of Mechanical Engineering,
Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 1281)

e
-
mail:ibogrekci@adu.edu.tr

Course Objective
and brief
Description

The
aim of this course is to give information regarding t
he sensor materials and sensors. Also
the aim is to teach the design stages for a sensor.

Textbook and Supplementary readings

1

Jacob Fraden
, “
Handbook of Modern Sensors: Physics, Designs, and Applications

Springer; 3rd edition
(December 4, 2003) ISBN
-
1
0: 0387007504 ISBN
-
13: 978
-
0387007502

2

Graham M.
Broker, “
Introduction to Sensors

SciTech Publishing; First edition (August 25, 2008)

ISBN
-
10: 189112174X ISBN
-
13: 978
-
1891121746

3

Jon S. Wilson
, “
Sensor Technology Handbook

Newnes (December 22, 2004)


ISBN
-
10: 0750677295 ISBN
-
13: 978
-
0750677295

COURSE CALANDER / SCHEDULE

Week

Lecture topics

Laboratory

1

Sensor materials (Physical sensor materials, chemical sensor materials)


2

Sensor materials (Biological sensor materials)


3

Data acquisition and
signals


4

Sensor characteristics (transfer functions, span, accuracy, precision,
hysteresis, linearity, Saturation

etc.
)


5

Sensor characteristics (Dynamic characteristic,
resolution, excitation,
reliability, uncertanity etc.)


6

Physical principle of

sensors


7

Midterm
Exam


8

Optical component of sensors


9

Interface electronic circuits


10

Position, displacement, level, velocity, accelaration sensors


11

Force, strain, tactile, pressure, flow, acoustic, light, radiation sensors


12

Temperature

sensors, chemical sensors


13

Sensor design project


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the final exam. Depending on instructor’s
preference, assessment may be by written or/and oral examination, homework
, lab assay, projects, group
presentation, or a combination of these.




18



Course Title

Precision Engineering and Production Metrology

Department

Mechanical Engineering

Division in the Dept.

Mechanica Engineering


Code

Term

Level

Type

Language

Credit ho
urs/week

Lecture

Lab

Credit

ETSC
Credit

MME 516

Spring

MSc

Optional

English

3

0

3

7



Name of
Instructors

Ass. Prof. Dr. Pınar DEMİRCİOĞLU

Instructor
Contact
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical
Engineering, Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 12
42
)

e
-
mail:
p
i
nar.demircioglu
@
adu.edu.tr

Course Objective
and brief
Description

The aim of this course is to inform students about precision engineering and production
metrology.


Textbook and Supplementary readings

1

Whitehouse D.J.,


Handbook of Surface and Nanometrology
”,

Institu
te of

Physics, Bristol, (published in 19
94),
2003, ISBN: 0
-
7503
-
05835,
1150.


2

Durakbasa M.N., “
Geometrical Product Specifications and Verification for the

Analytical Description of
Technic
al and Non
-
Technical Structures”,

November 2003,

printed in Austr
ia (TU Wien:
Abteilung
Austauschbau und Mes
stechnik), ISBN: 3
-
901888
-
26
-
8,
152.


3

Pfeifer T.,

“Production Metrology”,

München, Wien: Oldenbourg

Wissenschaftsverlag, Augu
st 2002, ISBN: 3
-
486
-
25885
-
0,
421.


4

Smith G.T.,


Industrial Me
trology: Surfaces an
d Roundness”,

Springer Verlag,

2002, ISBN: 1
-
85233
-
507
-
6,
336.

COURSE CALENDAR / SCHEDULE

Week

Lecture topics

Laboratory

1

Development tendencies in precision engineering and metrology


2

Precision machining production techniques


3

Precision machining

limits and measurement sensitivities


4

Geometrical product specifications and verification


5

Geometrical tolerances


6

Statistical tolerancing in interchangeable manufacturing


7

Midterm Exam


8

Coordinate metrology and coordinate measuring machine
s


9

Measurement on CMMs


10

Coordinate measurement for intelligent manufacturing environment


11

Surface analysis and evaluation of non
-
technical structures


12

Industrial applications of coordinate measuring machines


13

Coordinate metrology for eva
luation of non
-
technical surfaces


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the final exam. Depending on
instructor’s preference, assessment may be by written or/and oral examination, homework, lab assay, project
s,
group presentation, or a combination of these.


19



Course Title

Engineering Metrology a
nd Quality Control

Department

Mechanical Engineering

Division in the Dept.

Mechanical Engineering


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

MME 518

Spring

MSc

Optional

English

3

0

3

7


Name of
Instructors

Ass. Prof. Dr. Pınar DEMİRCİOĞLU

Instructor
Contact
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical
Engineering, Main Campus, Ay
tepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 12
42
)

e
-
mail:
p
i
nar.demircioglu
@adu.edu.tr

Course Objective
and brief
Description

The aim of this course is to inform the students about metrology and quality control.

Textbook and Supplementary rea
dings

1

Whitehouse D.J., “Handbook of Surface and Nanometrology”, Institute of Physics, Bristol, (published in 1994),
2003, ISBN: 0

2

“Measurement in Technology”. A textbook from the multimedia courseware METROMEDIA

3

Pfeifer T., “Production Metrology”,

München, Wien: Oldenbourg Wissenschaftsverlag, August 2002, ISBN: 3


COURSE CALANDER / SCHEDULE

Week

Lecture topics


Laboratory

1

Introduction to concept of metrology and quality


2

Analysis of errors in measurement


3

Statistical quality control


4

Control charts


5

Linear measurement, tool used


6

Angular measurement, tool used


7

Midterm Exam


8

Other measurement techniques (optical, laser etc.)


9

Measurement of geometrical shape (roundness, flatness etc.)


10

Measurement of surface text
ure (surface roughness and waviness)


11

Measurement of screw threads


12

Measurement of gears


13

Limits and limit gauges


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the final exam. Depending on
instructor’s pr
eference, assessment may be by written or/and oral examination, homework, lab assay, projects,
group presentation, or a combination of these.






20



Course Title

Measurement Technology

Department

Mechanical Engineering

Division in the Dept.

Mechanical Eng
ineering


Code

Term

Level

Type

Language

Credit hours/week

Lecture

Lab

Credit

ETSC
Credit

MME 520

Spring

MSc

Optional

English

3

0

3

7



Name of
Instructors

Ass. Prof. Dr. Pınar DEMİRCİOĞLU

Instructor
Contact
Information

Adnan Menderes University, Faculty of Engineering, Department of Mechanical
Engineering, Main Campus, Aytepe, 09010 Aydın. Tel: (256) 218 2000 (ext. 12
42
)

e
-
mail:
p
i
nar.demircioglu
@
adu.edu.tr

Course Objective
and brief
Description

The aim of this course is to inform the students about measurement science and technology.

Textbook and Supplementary readings

1

Whitehouse D.J.,

“Surfaces and their measurement”, Hermes Penton Science,
London, 2002,
ISBN
: 1
-
9039
-
9660
-
0,
395
.

2

“Measurement in Technology”. A textbook from the multimedia courseware METROMEDIA
-
ONLINE, ISBN:
80
-
89112
-
05
-
6.

COURSE CALENDAR / SCHEDULE

Week

Lecture topics

Laboratory

1

History of measu
rement and measuring principles


2

Quantities and units


3

Measuring instruments


4

Properties of measuring instruments


5

Design and manufacturing of measuring instruments


6

Design criteria for instrumentation


7

Midterm Exam


8

Imaging and comput
er vision


9

Optical and Tactile imaging


10

Measurement of length, position and dimension


11

Measurement of surface roughness, waviness and the primary profile


12

Measurement of geometrical properties


13

Uncertainty of measurement


14

Final Exam

Course assessment will be weighted 40 % for
Midterm Exam and
60 % for the final exam. Depending on
instructor’s preference, assessment may be by written or/and oral examination, homework, lab assay, projects,
group presentation, or a combination of these.