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4. 3. UNDERGRADUATE PROGRAM IN MECHANICAL ENGINEERING Program Speciication
1.
Awarding Institution Universit as Indonesia
Double Degree: Universit as Indonesia and Part ner Universit y
2. Teaching Institution
Universit as Indonesia Double Degree: Universit as Indonesia and Part ner Universit y
3. Programme Tittle
Undergraduate Program in Mechanical Engineering
4. Class
Regular, Parallel and International
5. Final Award
Sarjana Teknik S.T Double Degree: Sarjana Teknik S.T and
Bachelor of Engineering B. Eng
6. Accreditation Recognition
BAN-PT: A Accredited - AUN-QA
7. Languages of Instruction
Bahasa Indonesia and English
8. Study Scheme Full Time Part
Time Full Time
9. Entry
Requirements
High school equivalent, or D3 Polytechnique equivalent, AND pass the entrance exam.
10. Study Duration
Designed for 4 years Type of Semester
Number of Semester Number of weeks semester
Regular 8
17 Short optional
3 8
11.
Graduate Proiles:
Engineering graduates who have abilities to design and analyze in the ield of mechanical engineer
-
ing with excellent leadership and professional characters.
12.
List of Graduates Competency: Capable to understand and apply basic knowledge of mathematics, numerical methods, statis
-
1. tical analysis and the basic sciences physics and chemistry required to achieve competence
in the discipline of Mechanical Engineering. Capable of describing the problems with carrying out scientiic research and report the results
2. of experiments, including analysis of statistical data obtained.
Capable to solve technical problems in the ield of thermo-luid systems and mechanical 3.
design.
Able to carry out product design innovations, including the identiication of needs for prod
-
4. ucts, preparation of product speciications, developing design concepts, selection of design,
engineering calculations and economic analysis, detail designand design aggregate compo
- nent s, and design drawings.
Able to design components, operate and manage the systems engineering-related aspects tak
-
5.
ing int o account energy conservat ion, manuf act uring, cost , saf et y, and sust ainabilit y.
Able to utilize the methods, skills, and modern engineering equipment that suit the needs of 6.
engineering work.
Able to perform the selection of materials, processes, and automation systems that suit the 7.
needs of engineering work.
Capable of supervising, and able to make decisions. 8.
Able to utilize and develop systems and computer-aided mechanical design. 9.
Professional responsibility and commitment. 10.
Able to identify entrepreneurial efforts, characterized by innovation. 11.
Able to work effectively both individually and in multi-disciplinary or multi-cultural teams. 12.
Explain the social and contemporary issues, such as social diversity and culturalappreciation, 13.
communicate with various segments of society, the strategic beneits of lobbying, negotiation
and mediat ion.
Able to communicate effectively both in visual, written or verbal, including proiciency in a 14.
f oreign language.
Able to carry out the lifelong learning process. 15.
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13
Classiication of Subjects
No.
Classiication
Credit Hours SKS Percentage
i
University General Subjects 18
12,5
ii
Basic Engineering Subjects 30
20,8
iii
Core Subjects 68
47,2
iv
Elective Subjects 16
11,1
v
Internship, Seminar, Undergraduate Thesis, Project
12 8,4
Tot al 144
100
14.
Total Credit Hours to Graduate 144 SKS
Career Prospects
Graduates of Mechanical Engineering has devoted itself in various ields, including automotive industry, oil and gas, heavy machinery, educat ional inst it ut ions, research inst it ut ions and ot her indust ries
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Learning Outcomes Flow Diagram
Graduates Profile
Have the commitment in ethic profession also responsibility and
professional commitment Capable
of supervising , and able to make
decisions .
Capable of describing the problems with carrying
out scientific research and report the results
of experiments , including anal ysis of statistical
data obtained Able to design products
with innovations , including the identification of needs for
products , preparation of product specifications ,
developing design concepts , selection
of design , engineering calculations and economic
analysis , detail design of components and design
of the aggregates , as well as design drawings
Able to design components , operate a
nd manage the systems engineering -
related aspects taking into account energy
conservation , manufacturing , cost, safety, and
sustainability . Able to carry
out the lifelong learning process .
Able to perform the selection of
materials , processes , and automation systems that suit
the needs of engineering work Able to utilize the
methods , skills, and modern engineering
tools necessary for engineering work
Able to solve technical problems in th
e field of thermo - fluid systems and
mechanical design Able to
utilize and develop systems a nd computer -
aided mechanical design .
Capable to understand and apply basic knowledge of mathematics , numerical methods , statistical analysis and the basic sciences physics and chemistry required to achieve competence in the discipline of Mechanical Engineering .
Able to identify entrepreneurial efforts,
characterized by innovation . Able to communicate
effectively both in visual, written
or verbal , including proficiency in a foreign language .
Able to work effectively both individually and in multi-
disciplinary or multi-cultural teams
Explain the social and contemporary issues, such
as social diversity and cultural appreciation , communicate with various s
egments of society , the strategic benefits of lobbying , negotiation and mediation .
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analysis and
the and
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Flow Diagram of Subj ects
The basic structure of Mechanical Engineering Undergraduat e Program shows t he cat egory and
relation between courses in outline. In practice, groups of subjects distributed into the semester
and each semester subject to the intake of sci -
ence and t he f oundat ion f or t he next semest er, either directly or indirectly, so that a complete
science of mechanical engineering at t he end of t he course.
Before completing the undergraduate engineer -
ing program with 144 credit units, the students of Mechanical Engineering Study Program have
to accomplish: University Courses 18 credit units, Basic Engineering Courses 30 credit
units, Basic Mechanical Engineering Courses 44 credit units,Mechanical Engineering Core
Courses 40 credit units which consist of Manda
- tory Core Courses 24 credit units and Elective
Core Course 16 credit units and 12 credits units consist of Design Project, Internship and Under
- graduat e Thesis.
University courses are a group of subjects who provide the knowledge base and opening depth
of knowledge and common knowledge at t he level of university higher education with an
emphasis on knowledge, among others, social cult ural, art and hist ory t o st udent s and gradu-
ates can understand, and interact with aspects of and non-t echnical areas t o be t he basis f or
the development of engineering skills. Basic Engineering Courses are a group of courses
that provide the basic knowledge to think logi -
cally and systematically by utilizing the basic principles of science mathematics, physics, and
chemistry and aspects of health, safety and en -
vironment to be able to solve problems and de -
velopment of mechanical engineering. at t he same t ime and cont inuously wit h The Ba-
sic Engineering Courses, The Basic Mechanical Engineering designed to provide the knowledge,
comprehension and basic competence in the ield of mechanical engineering with an empha
- sis on the ability of designing and planning of
mechanical systems with emphasis on the areas of energy conversion, design and production
manuf act uring. The Mechanical Engineering Mandatory Core
Courses is broadly follow The Basic Mechanical Engineering Courses given to increase the abil
- ity and competence in Mechanical Engineering
ield and rules in the application of these com -
petencies, as well as provide an understanding in the ield of managerial and entrepreneurship
development. The Mechanical Engineering Elective Core
Courses given to increase the ability and com
- petence speciically in Mechanical Engineering
Field to build the more speciic competence or in the ield with a wider mechanical engineering
knowledge. Further development of skills and capabilities
in innovation and implementation ofmechani -
cal engineering sciences, subjects administered through Design Project, Internship and Under
- graduate Thesis. In an effort to give oppor
- t unit ies t o st udent s who want t o increase and
broaden their horizons, skills, knowledge and capabilities, then the student may be allowed
to take subjects across departments faculties are offered by departments faculties in ac
- cordance wit h t he t erms and condit ions set out .
Apart from that, the Department of Mechanical
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Basic Courses
Basic Engineering Courses
27 Credit Units Basic Mechanical
Engineering Courses 48 Credit Units
University Courses 18 Credit Units
Mechanical Engineering Core Courses 43 Credit Units
Mandatory Core Courses
23 Credit Units Elective Core
Courses 20 Credit Units
On The Job Training , Design Project , Undergraduate Thesis 12 Credit Units
Internship
30 44
40
24 16
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Engineering, also offers some of the subjects as subjects of cross department ofice that can be
taken and open to students with different aca -
demic disciplines to add insight and knowledge. The Curriculum was designed and developed so
that the learning process can produce well com -
petent graduates with the characteristic accord -
ing to the education purpose, which are: Have a strong engineering knowledge.
1. The abilit y t o design and conduct t he re-
2. search and also the ability to analyze the
dat a. The abilit y t o ident if y, f ormulat e and solve
3. the problems in mechanical engineering
ield according to the study of new cases. The ability to design a system, component
4. or process of a mechanical system to fulill
the requirement with considering and ap -
plying the economical aspect. Leadership knowledge, a good communica
- 5.
t ion skill, t eamwork, knowledge and self improvement.
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The groups of the courses can be seen according to the characteristic and the education purposes that are
expected as shown in igure below.
1
st
SEMESTER 2
nd
SEMESTER 3
rd
SEMESTER 4
th
SEMESTER 5
th
SEMESTER 6
th
SEMESTER 7
th
SEMESTER 8
th
SEMESTER Calculus
Heat Mechanic Physic
Engineering Drawing
Basic Chemistry
MPKT A English
Linear Algebra
Electrical, Magnetic, Wave
Optical Physic Engineering
Mathematics
Statistics and Probability
HSE
Engineering Ethics
Design Project
Industrial Seminar
Technopreneurship
On the Job Training
Undergraduate Thesis
Sports and Arts Religion
MPKT B
Visualization and Mechanical
Modelling Basic
Mechanical Design
Basic Thermodynamic
Engineering Materials
Basic Fluid Mechanics
Kinematics and Dynamics
Mechanical Design
Material Selection and
Manufacturing Process
Introduction to Computer
Heat and Mass Transfer
Fluid System Mechanical
Vibration System Control
Metrology and Measurement
Electrical Power Engineering
Energy Conversion
Conservasion Maintenance
and Condition Monitoring
Mechatronics
Elective 1
Elective 2 Elective 3
Elective 4
Internship Engineering
Computation
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KODE MATA AJARAN
SUBJECT SKS
Semester 1 1 st Semester
UIGE 6 0 0004 MPK Terintegrasi B
Integrated Character Building Subject B 6
UIGE 6 0 0002
Bahasa Inggris English
3 ENGE 6 0 0001
Kalkulus
Calculus 4
ENGE 6 0 0009 Menggambar Teknik
Engineering Drawing
2 ENGE 6 0 0003
Fisika Dasar 1 Mekanika dan Panas
Basic Physics 1 4
Subtotal 19
Semester 2 2 nd Semester
UIGE 6 0 0001 MPK Terintegrasi A
Integrated Character Building Subject A 6
UIGE 6 0 0005-9
Agama
Religious Studies 2
UIGE 6 0 0003 OlahragaSeni
SportsArts 1
ENGE 6 0 0002 Aljabar Liniear
Liniear Algebra
4 ENGE 6 0 0004
Fisika Dasar 2 Basic Physics 2
4 ENME 6 0 0001
Visualisasi dan Permodelan Mesin Mechanical Visualization and Modelling
3
Subtotal 20
Semester 3 3 rd Semester
ENME 6 0 0002 Matematika teknik
Engineering Matematics 4
ENGE 6 0 0005
St at ist ik dan Probabilit as St at ist ic and Probabilit y
2 ENGE 6 000010
Kimia Dasar
Basic Chemistry 2
ENME 6 0 0003 Material Teknik
Material Engineering 4
ENME 6 0 0004
Termodinamika Dasar Basic Thermodynamics
4 ENME 6 0 0005
Dasar Perancangan Mekanikal Fundamental of Mechanical Design
4
Subtotal 20
Semester 4 4 th Semester
ENEE 6 0 0031 Komputasi Teknik
Engineering Computation 2
ENME 6 0 0007 Proses Manufaktur dan Pemilihan
Material Material Selection and Manuf. Process
6 ENME 6 0 0008
Kinemat ika dan Dinamika Kinemat ics and Dynamics
4 ENME 6 0 0009
Mekanika Fluida Dasar Basic Fluid Mechanics
4 ENME 6 0 0010
Perancangan Mekanikal Mechanical Design
4
Subtotal 20
Semester 5 5 th Semester
ENME 6 0 0011 Getaran Mekanis
Mechanical Vibration 2
ENME 6 0 0012 Pengukuran dan Metrologi
Measurement and Metrology 3
ENME 6 0 0013 Perpindahan Kalor dan Massa
Heat and Mass Transfer 4
ENEE 6 0 0017
Teknik Tenaga List rik Elect rical Power Engineering
2 ENME 6 0 0015
Pengendalian Sist em
Control System 4
ENME 6 0 0016
Sist em Fluida Fluid Syst em
3
Subtotal 18
Semester 6 6 th Semester
ENME 6 0 0024 Etika Enjiniring
Engineering Et hics
2 ENGE 6 0 0008
K3L Kesehatan, Keselamatan,
dan Lindung Lingkungan
Healthy, Safety and Enviroment 2
ENME 6 0 0017
Pemeliharaan dan Pemant auan
Kondisi Mesin Maintenence and Condition Monitoring
3 ENME 6 0 0018
Konversi dan Konservasi Energi
Energy Conversion and Conservation 4
ENME 6 0 0019 Mekatronika
Mechatronics 4
ENME 6 0 0020 Tugas Merancang
Design Assignment
4
Subtotal 19
Semester 7 7 th Semester
ENME 6 0 0025 Kapita Selekta Industrial
Indust rial Seminar
2 ENME 6 0 0021
Teknoprneurship Technoprneurship
2
Course Structure Undergraduate Program in Mechanical Engineering Regullar and Parallel
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ENME 6 0 0022 Kerja Praktik
Internship 2
Pilihan 1 Elective 1
4 Pilihan 2
Elective 2 4
Subtotal 14
Semester 8 8 th Semester
ENME 6 0 0023 Skripsi
Final Project 6
Pilihan 3 Elective 3
4 Pilihan 4
Elective 4 4
Subtotal 14
Electives can be taken from other department or selected from the Master Program, please see the following table. Fast Track students must take electives from a particular stream only
Energy Conversion Stream 1.
Code Mata Kuliah
Subj ect Credits
Semester 7 7th Semester
ENME 8 0 0114
Teknik Pembakaran
Combustion Engineering 4
ENME 8 0 0115 Motor Pembakaran Dalam
Internal Combustion Engineering 4
ENME 8 0 0116 Pengukuran dan Visualisasi AliranTerapan
Applied Flow Measurement and Visualiza
- t ion
4 ENME 8 0 0117
Aplikasi CFD CFD Application
Semester 8 8 th Semester
Credits
ENME 8 0 0111 Rekayasa Penukar Kalor dan Massa
Heat and Mass Transfer Engineering 4
ENME 8 0 0112
Teknik Aerodinamika Aerodynamics Engineering
4 ENME 8 0 0113
Pembangkit an Daya
Power Generation 4
Building Utility System and Fire Safety Stream 2.
Code Mata Kuliah
Subj ect Credits
Semester 7 7 th Semester
ENME 8 0 0214 Teknik Refrijerasi
Refrigeration Engineering 4
ENME 8 0 0215
Teknik Keselamat an dan Prot eksi Kebakaran
Fire Saf et y and Prot ect ion Engineering
4 Semester 8
8 th Semester Credits
ENME 8 0 0211
Sist em Vent ilasi dan Tat a Udara
Air Conditioning and Ventilation System 4
ENME 8 0 0212
Perancangan Sist em Ut ilit as Bangunan Building Ut ilit y Syst em Design
4 ENME 8 0 0213
Audit Energi Energy Audit
4 ENME 8 0 0202
Sistem Mekanikal dan Elektrikal Gedung Building Mechanical and Electrical System
4
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Design and Product Manufacturing Stream 3.
Code Mata Kuliah
Subj ect Credits
Semester 7 7 th Semester
ENME 8 0 0314 Fabrikasi Mikro dan Manufaktur Presisi
Microfabrication and precision manufac
- t uring
4 ENME 8 0 0315
Dinamika Sistem Mekanikal Dynamics of Mechanical System
4 ENME 8 0 0316
Pengembangan Produk Komposit Composite Product Development
4 ENME 8 0 0317
Finite Element dan Multiphysics Finite Element and Multiphysics
4 Semester 8
8 th Semester Credits
ENME 8 0 0311 Perancangan untuk Manufaktur dan
Perakit an
Design For Manufacture and Assembly 4
ENME 8 0 0312 Kegagalan Mekanikal
Mechanical Failure 4
ENME 8 0 0313 Kebisingan dan Getaran
Noise and Vibration 4
Automation and Manufacturing System Stream 4.
Code Mata Kuliah
Subj ect Credits
Semester 7 7 th Semester
ENME 8 0 0413 System Machine Vision
System Machine Vision 4
ENME 8 0 0414 Sistem Manajemen Produksi dan Mutu
Quality and Production Management
Syst em
4
Semester 8 8 th Semester
Credits
ENME 8 0 0411 CADCAM
CADCAM 4
ENME 8 0 0412 Penilaian Kinerja Manufaktur
Manufacturing Performance Assesment 4
ENME 8 0 0402 Otomasi dan Robotika
Automation and Robotics 4
Vehicle Engineering and Heavy Equipment Stream 5.
Code Mata Kuliah
Subj ect Credits
Semester 7 7 th Semester
ENME 8 0 0513 Teknologi Mutakhir Kendaraan
Modern Vehicle Technolgy 4
ENME 8 0 0514 Peralatan Pengeboran Minyak dan
Gas
Oil and Gas Drilling Equipment
4 Semester 8
8 th Semester Credits
ENME 8 0 0511 Teknik Kendaraan Rel
Railway Vehicle Engineering 4
ENME 8 0 0512 Mesin dan Peralatan Pengangkat
Handling and Construction Equip
- ment
4
For students who are willing and capable to continue the education program to pursue Masters in Engineering through the Fast track program, credit transfer can be performed as many as 20 credits.
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The numbers of credits that can be transferred consist of: 4 credits from Engineering Mathematic course, 8 credits from 2 Mandatory Core Courses and 8 credits from 2 Elective Core Courses.
Terms and conditions to become the participant of Fast Track program are: Expressed a desire to follow the Fast Track Program, by writing an application to the Head of
1. the Department of Mechanical Engineering with Study Plan includes a plan-making subjects in
Semester 6 to 8 in the Bachelor of Engineering and subject Semester 1 to 4 the Master of Engineering Program in accordance with the Master of Engineering Program Specialisation, no
later than the end of 5
t h
Semester the undergraduate program. Have an excellent academic record, with 3.0 GPA until 5
2.
t h
semester and have passed all the
basic courses.
The students that follow the Fast Track program expressed their willingness to join this program 3.
on f ull t ime basis.
If the application of the fast track program can be approved by the Head of Department Study 4.
Program, the student will be discussed along with the Academic Advisor for the finalization of the study plan in undergraduate and graduate program.
The students from the undergraduate program that have the aggrement to join the fast track pro
-
gram have to reschedule their study in 7th and 8th semester to get along with their 1st and 2nd semester in graduate program.
Mechanical Engineering Undergraduate International Program Curriculum
The international program of mechanical engineering study is divided into two phase which are the irst will be done at University of Indonesia and the other phase will be completed at partner universities
in Australia. There will be option to continue the second phase at UI. A student at the Department of Mechanical Engineering - Univesity of Indonesia must complete and pass 72 - 74credits over 4 semester
before continuing to partner universities. The courses are classiied into General courses 7 credits; Basic courses 65 credits that consist of Basic Engineering courses 28 credits and Basic Mechanical
Engineering courses 37credits.
Table 6. Course Structure of Mechanical Engineering at QUT + Semester 5 s d 8 Basic Courses
Basi c Engi neeri ng Courses
27 Credits Basic Mechanical
Engi neeri ng Courses
48 Credits
University Courses 7 Credits
To be completed at patner universities 72 credits
Mechanical Engi neeri ng
Competence Course -
Compulsory Mechanical
Engi neeri ng Competence Courses
- El ect i ve
Undergraduat e Thesi s Final Project
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CODE SUBJECT
SKS 1 st Semester
UIGE 6 1 0002
Academic Writ ing
3 ENGE 6 1 0001
Calculus 4
ENGE 6 1 0010 Basic Chemistry
2 ENGE 6 1 0009
Engineering Drawing
2 ENGE 6 1 0003
Basic Physics 1 Mechanic Heat 4
ENGE 6 1 0005
St at ist ics and Probabilit y
2 ENME 6 1 0024
Engineering Et hics
2
Subt ot al
19
2 nd Semester
ENGE 6 1 0002
Liniear Algebra
4 ENGE 6 1 0004
Basic Physics 1 Elec, Magnet, Wave, and Optic 4
ENME 6 1 0001 Mechanical Visualization and Modelling
3 ENME 6 1 0003
Material Engineering 4
ENME 6 1 0005 Fundamental of Mechanical Design
4 SportsArts
1
Subt ot al
20
3 rd Semester
ENME 6 1 0002 Engineering Matematics
4 ENME 6 1 0004
Basic Thermodynamics
4 ENME 6 1 0010
Mechanical Design 4
ENME 6 1 0008
Kinemat ics and Dynamics
4 ENEE 61 0017
Elect rical Power Engineering
2
Subt ot al
18
4 th Semester
UIGE 6 1 0005-9 Religious Studies
2 ENGE 6 1 0008
Healthy, Safety and Enviroment 2
ENME 6 1 0006 Engineering Computation
2 ENME 6 1 0007
Material Selection and Manuf. Process 6
ENME 6 1 0009 Basic Fluid Mechanics
4 ENME 6 1 0011
Mechanical Vibration 2
Subt ot al
18
5 th Semester
UIGE 6 1 0001 Integrated Character Building Subject A
6 ENME 6 1 0012
Metrology and Measurement 3
ENME 6 1 0013 Heat and Mass Transfer
4 ENME 6 1 0015
System Control 4
ENME 6 1 0016
Fluid Syst em
3
Subt ot al
20
6 th Semester
UIGE 6 1 0004 Integrated Character Building Subject B
6 ENME 6 1 0017
Maintenance and Condition Monitoring 3
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CODE SUBJECT
SKS 6th Semester
ENME 6 1 0019 Mechatronics
4 ENME 6 1 0021
Teknoprneurship 2
ENME 6 1 0020
Design Assignment
4
Subt ot al
19
7 th Semester
ENME 6 1 0025 Capita Selecta
2 ENME 6 1 0018
Energy Conversion and Conservation 4
ENME 6 1 0022 Internship
2 Elective 1
4 Elective 2
4
Subt ot al
16
8 th Semester
ENME 6 1 0023 Final Project
6 Elective 3
4 Elective 4
4
Subt ot al
14
ELECTIVES
ENME 8 0 0411 CADCAM
4 ENME 8 0 0113
Power Generation 4
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Year 3 Semester 5 UQ July
Credits Year 3
Semester 6 UQ March Credits
KODE Course Title
KODE Course Title
ENB222 ENB231
ENB311 MAB233
Thermodynamics 1 Materials and Manufacturing 1
St ress Analysis
Engineering Mathematics 3,
or Elect ives
12 12
12 12
ENB215 ENB321
ENB331
Fundament als of
Mechanical Design Flu
- ids Dynamics
Materials and Manufac
-
turing 2 Elective Minor
12 12
12 12
subt ot al
48
subt ot al
48 Year 4
Semester 7 UQ July Credits
Year 4 Semester 8 UQ March
Credits KODE
Course Title KODE
Course Title ENB312
ENB316 ENB421
Dynamics of Machinery Design of Machine Elements
Thermodynamics 2 12
12 12
BEB801 ENB313
ENB317 Project 1
Automatic Control Design and Mainte
- nance of
Machinery Electives Minor
12 12
12 12
subt ot al
36
Subt ot al
48
Table 7. Course Structure of Mechanical Engineering at University of Queensland
For July Int ake Year 3
Semester 5 UQ July Credits
Year 3 Semester 6 UQ March
Credits KODE
Course Title KODE
Course Title MECH2700
MECH3100 MECH3200
MECH3410
Engineering Analysis I
Mechanical and Space
Syst em Design Advanced Dynamics and
Vibrat ion
Fluid Mechanics 2
2 2
2 MATH2010
STAT2201 MECH3300
MECH3400 MECH3600
Analysis of Ordinary
Dif f erent ial Equat ion Analysis of Engineering and
Scientiic Data Finite Element Method and
Fracture Mechanics Thermodynamics and Heat
Transf er
Engineering Management and Communication
1 1
2 2
2
subt ot al
8
subt ot al
8 Year 4
Semester 7 UQ July Credits
Year 4 Semester 8 UQ March
Credits KODE
Course Title KODE
Course Title MECH4501
Engineering Thesis Elect ive
Elect ive Elect ive
4 2
2 2
MECH4501 METR3200
Engineering Thesis
Introduction to Control
Syst em Elect ive
Elect ive
4 2
2 2
subt ot al
10
subt ot al
10
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List of Electives at UQ is called Part B Electives B2 - Advanced Electives
Code Course Title
Credits AERO3100
CHEE4302 ELEC2003
ENGG4101 ENGG4102
ENGG4103 MECH3250
MECH3305 MECH3750
MECH4301 MECH4304
MECH4450 MECH4460
MECH4470 MECH4480
MECH4552 MECH4800
MECH4950 MECH4951
METR3100 METR4202
TIMS3309 Aerospace Materials
Electrochemistry Corrosion Electromechanics Electronics
Systems Engineering Design Management Advanced Product Design Methods
Engineering Asset Management
Engineering Acoust ics
Science Engineering of Metals
Engineering Analysis II
Materials Selection Net Shape Manufacturing
Aerospace Propulsion Energy Environment
Hypersonics Rareied Gas Dynamics Computational Fluid Dynamics
Major Design Project [5] Space Engineering
Special Topics C Special Topics D
Sensors Actuators Advanced Control Robotics
Fundamentals of Technology and Innovation Management 2
2 2
2 2
2 2
2 2
2 2
2 2
2 2
4 2
2 1
2 2
2
List of Electives at UQ is called Part B Electives B3 - Other Electives
Code Course Title
Credits MATH1050
SCIE1010 Mathematical Foundations [6]
Introduction to Research Practices - The Big Issues 2
2
Table 8. Course Structure of Mechanical Engineering at Curtin University
For July Int ake Year 3
Semester 5 Curtin July Credits
Year 3 Semester 6 Curtin March
Credits KODE
Course Title KODE
Course Title 307660
307664 308803
308810 308815
3864
Engineering Sust ainable
Development
Engineering Law
Mechanical Design Fluid Flow Modelling
Automatic Control
Elect rical Plant
12.5 12.5
25 25
12.5 12.5
308801 308812
308813 308814
Thermal Engineering Processes
Indust rial Technology
Materials
Dynamic Syst ems
25 25
25 25
subt ot al
100
subt ot al
100
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Year 4 Semester 7 Curtin July
Credits Year 4
Semester 8 Curtin March Credits
KODE Course Title
KODE Course Title
5051 Mechanical Project
Optional Unit Optional Unit
Optional Unit 25
25 25
25 308821
310544 Mechanical Project
Prof essional Pract ice
Optional Unit Optional Unit
37.5 12.5
25 25
subt ot al
100
subt ot al
100
List of Optional Units at Curtin
Year 4 Semester 7 Curtin July
Credits Year 4
Semester 8 Curtin March Credits
KODE Course Title
KODE Course Title
12907 12911
12925 302862
302866 Design For Manufacturing
Automatic Control Fluid Mechanics
Finit e Element Analysis
Noise 25
25 25
25 25
12926 302863
302864 310545
312200 4282
Materials
Vibrat ion
Heat Transfer Design Methodology
Sust ainable Energy Syst ems and Technologies
Mechanical Measurements 25
25 25
25 25
25
Transition Policy from the 2008 to the 2012 Curriculum
For the Mechanical Engineering Undergraduate Program there are no speciic transition rules
to adjust the previous curriculum with the
new curriculum. The change wit hin t he new curriculum is t he addit ion of The Int egrat ed
Character Building B MPKT B course with 6
credit s. In t he new curriculum t he st udent s
have to take 4 elective courses with 16 total
credit s.
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Course Description UIGE600001
UIGE610001 MPKT A
INTEGRATED CHARACTER BUILDING A
6 SKS Refer to Page 78
UIGE600004 UIGE610004
MPKT B
INTEGRATED CHARACTER BUILDING B
6 SKS Refer to Page 78
UIGE600002 ENGLISH
UIGE610002 ACADEMIC WRITING
3 SKS Refer to Page 78
UIGE600003 UIGE610003
SPORTS ARTS 1 SKS
Refer to Page 81
ENGE600001 ENGE610001
CALCULUS 4 SKS
Refer to Page 78
ENGE600010 ENGE610010
BASIC CHEMISTRY Refer to Page 79
ENGE600003 ENGE610003
BASIC PHYSICS 1 4 SKS
Refer to Page 79
ENGE600004 BASIC PHYSICS 2
4 SKS Refer to Page 81
ENGE600002 ENGE610002
LINEAR ALGEBRA 4 SKS
Refer to Page 79
UIGE600005-9 UIGE610005-9
RELIGIOUS STUDIES
2 SKS Refer to Page 80-81
ENGE600005 ENGE610005
STATISTICS AND PROBABILITY 2 SKS
Refer to Page 82
ENGE600008 ENGE610008
HEALTH, WORK SAFETY, AND ENVIROMENT 2 SKS
Refer to Page 82
ENGE600009 ENGE610009
ENGINEERING DRAWING 2 SKS Learning Obj ectives:
Course participants are able to transfer geometric component by drawing
according to standard draw which is recognized by International Standard Organization ISO.
Students understand the theory and procedure of engineering drawing based on ISO standard.
Students are able to read, interpret, and transfer 2D3D geometric draw from component or con
- st ruct ion. St udent s are able t o draw t he ort hogo-
nal projection based on ISO standard.
Syllabus:
Illustration: Function and beneit of Engineering Drawing; SAP; Measurement and
Evaluation; Introduction to drawing equipment; Basic definition of geometric, paper format,
draw regulation, line, ield, line coniguration, basic geometric form; Visualization geometric:
Skew projection and isometric, function and line types, coniguration geometric form; Orthogonal
Projection: Projection standard, viewing concept, width display principle; Advanced orthogonal
projection: Circle region concept, special region concept, trimming concept, display width, refrac
- t ion.
Pre-requisites: - Text Books:
ISO 1101, Technical Drawings, International 1.
Organization for Standardization. A.W. Boundy, Engineering Drawing , McGraw-
2. Hill Book Company
Colin Simmons Dennis Maguire, Manual of 3.
Engineering Drawing, Edward Arnold Warren J. Luzadder, Fundamentals of Engi
- 4.
neering Drawing, Prentice-Hall, Inc. Giesecke-Mitchell-Spencer-Hill-Dygdon-No
- 5.
vak, Technical Drawing, Prentice Hall Inc.
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ENME600001 ENME610001
MECHANICAL VISUALIZATION AND MODELLING 3 SKS
Course Obj ective:
Students have the basic ability to visualize the information content of one component
effectively, capable to create a model for 2D and 3D visualization with utilize the software
and interprete the subject into a drawing that
can be used as working guidance and can be underst and clearly by t he user.
Syllabus:
The purpose and the advantage of the drawing in the design and manufacturing process, sur
- f ace working qualit y and t olerance, st andard
and marking classiication of working quality, standard and marking classiication of working
t olerance, Welding const ruct ion, st andard and
marking of kampuh seam? and welding, line diagram, 2D and 3D representation method,
int roduct ion t o modeling sof t ware int erf ace,
modeling, manipulation and 2D 3D visual
-
ization.
Requirement: Engineering Drawing
References:
A. W. Bou n d y, En gi n e e r i n g Dr aw i n g,
1. McGraw-Hill Book Company
Colin Simmons Dennis Maguire, Manual 2.
of Engineering Drawing 4
t h
edition 2012,
Elsevier.
ISO 1101, Mechanical Engineering 3.
Drawings, International Organization for Standardization.
Japanese Industrial Standard, Technical 4.
Drawing for Mechanical Engineering, Japanese Standards Association.
Warren J. Luzadder, Fundamentals of 5.
Engineering Drawing, Prentice-Hall, Inc..
ENME600002 ENME610002
ENGINEERING MATHEMATICS 4 SKS Course Obj ective:
Complete student’s anylitical ability. Students
under st and and abl e t o use t he advances
mathematical concepts in order to solve the engineering problems.
Syllabus:
Introduction to differential equation, 1
st
order
differential equation, 2
nd
order di f f erent i al equat ion, higher order dif f erent ial equat ion,
vector analysis, vector differential, grad opera
- t ion, divergence and culr, vect or int egrat ion,
laplace transform, laplace transform to solve
t he dif f erent ial equat ion, f ourrier t ransf orm, convulsion, numerical met hod, root of equa-
t i on, numer i cal di f f er ent i at i on, numer i cal int egral.
Requirement:
Calculus, Linear Algebra
References:
Croft, A, et.al, Mathematics for Engineers, 1.
3rd Edition, 2008, Prentice Hall Chapra S.C., Canale, Numerical Methods
2. for Engineer, 6th Edition, 2010, Mc Graw
Hill Kreyszig, E, Advanced Engineering
3. Mathematics 10th Edition, John Wiley
and Sons
ENME600003 ENME610003
ENGINEERING MATERIALS 4 SKS Course Obj ective:
Engi neer i ng mat er i al s ar e one of t he basi c
knowledge in ield of design, especially in
mechanical engineering. From t he discussion of t he behavior of several mat erials, t he st u-
dents are expected to have the overview about
several t hing t hat has t o be t he concern relat ed
to the working process or the speciic need. The students are expected to have the basic
ability to identify and explain the nature and
behavior of mat erials relat ed t o t he t reat ment
in working process and speciic need.
Syllabus:
Introduction to the importance of the engineer
- ing mat erial science in mechanical engineering,
at omic st ruct ure, cryst alic mat erial, met al and
non metal material, process, phase diagram and solidiicatiom, heat treatment process,
mechani cal behavi or of cr yst al i c mat er i al ,
elastic material, plastic deformation, crystal plasticity, method of material mechanical
t est i ng, di sl ocat i on, st r engt heni ng, f ai l ur e and remaining lif et ime of mat erial, int roduc-
t ion t o mechanical crack and st eel mechanical st ruct ure behavior, mat erial st ruct ure degrada-
tion, corrosion process, corrosion prevention, Oxidation, wear and erotion, concrete mate
- rial behavior, wood, cement and it s st ruct ure
behavior. Requirement:
-
References:
Kalpakjian, Manufacturing Engineering and 1.
Technology, Addison Wesley- 2008 Thomas H. Courtney, Mechanical Behavior
2. of Materials, 2
nd
Edition McGraw-Hill Book Co. - 2005
R.A. Higgins, Property of Engineering 3.
Materials, Edward Arnold - 1994 Flinn Trojan, Engineering Materials and
4. Their Applications, John Wiley Sons,
Inc.- 1995 James A. Jacobs Thomas F. Kilduff,
5. Engineering Material Technology, Prentice-
Hall, Inc. - 2001
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ENME600004 ENME610004
BASIC THERMODYNAMICS 4 SKS Course Obj ective:
This course introduces the basic concept of thermodynamics and its application in real life
and gives t he underst anding about t he design of t hermodynamics syst em.
Syllabus:
Scope and basic understanding of thermody
-
namics system, temperature concept, pres
-
sure, thermodynamics equilibrium, reversible irreversible process, zero law of thermody
-
namics and absolute temperature, irst law
of t hermodynamics, second law of t hermody-
namics, thermodynamics equation, gas power cycle, gas compressor, combustion engine
cycle, internal combustion engine , simple gas
t urbine cycle, brayt on’ s cycle, st irling’ s cycle,
steam power cycle, refrigeration, carnot’s cycle, simple rankine’s cycle, rankine’s cycle
with modiication, biner cycle, phsycometrich
chart , cooling t ower, real gas, real gas equa-
tion, enthalpy and entrophy.
Requirement: -
Referencess:
Michael J. Moran, Howard N. Shapiro, 1.
F u n d a m e n t a l s o f E n g i n e e r i n g
Thermodynamics, 5th Edition, John Wiley Sons, 2004.
Reynolds W.C., Perkins H.C., Engineering 2.
Thermodynamics, Mc. G. Hill . Zemansky , Aboot , van Ness, Basic
3. Engineering Thermodynamics, McGraw
Hill
Kennet h War k Jr. Ther m odynam i cs ,
4. Mc.Graw Hill
H.D. Baehr, Termodynamik , Springer 5.
Verlag
ENME600005 FUNDAMENTAL OF MECHANICAL DESIGN 4
SKS Course Obj ective:
Thi s cour se gi ves t he basi c know l edge i n mat erial st rengt h and mechanics of syst em
t hat will be needed in engineering of machine element s.
Syllabus:
Design consept, load and support reaction in
t he const ruct ion, normal f orce diagram, shear and moment in beam, cal cul at ions in beam
construction, Trusses, Frame Machine, 2
nd
Area Moment and Intertia, stress and strength,
normal st ress, t orsion and bending, def orma- t ion, beam wit h indet erminat e st at ic l oad,
Buckling, solid st at e mat erials, f ailure analysis f or st at ic load, f ailure analysis f or cyclic load
and shock load, basic and simple application of FEM in design, Final Assignment : Application of
calculation and FEM in simple axis design.
Requirements:
Mechanical Visualization and Modeling ; Engineering Materials
References:
1. Beer, Ferdinand P, Mechanics for Engineers: STATICS, Mc GrawHill.
2. Hibbeler RC, Mechanics of Materials, 5th ed., Prentice Hall, 2003.
3. Riley, F William, Engineering mechanics: STATICS, John wiley sons
4. Hamrock, Fundamental of Machine Element, Mc Graw-Hill.
5. Shigley, Joseph Edward, Mechanical Engi
-
neering Design, McGrawHill. 6. Kurowski, P.M., Finite Element Analysis for
Design Engineers, SAE International,2004
ENEE 6 0 0031 ENEE 6 1 0031
NUMERICAL COMPUTATION 2 SKS Refer to Page 179
ENME600007 ENME610007
MATERIAL SELECTION and MANUFACTURING PROCESS 6 SKS
Course Obj ective: To give t he knowledge, underst anding and com-
petence about the theory, application method and product manufacturing process technology
t hat consist of : charact erist ic and how t he
process work, process constraint, force and energy that needed in process, the effect of
the process parameter to the product quality and the relation between process and mate
- rial t o t he mat erial charact erisc t hat needed
in every process.
Syllabus:
Manufacturing process and production system,
mat erials in manuf act ur, t heory and met hod in met al cast ing, t heory and met hod of bulk
f ormat ion, t heory and met hod of sheet met al
forming, theory and method of powder met
-
allurgy, theory and method of machining metal cutting process, theory and precess of
product surface quality improvement, theory and method of joining, theory and method
of prototyping process, characteristic of en
- gineering mat erial s, correl at ion of mat erial
and process characteristic, process parameter
cont rol of mat erial, Desing of mat erial selec-
tion and manufacturing process that related
t o t he market needs assignment , Laborat ory act ivit y.
Requirement:
Engineering Material
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Referencess:
Ashby, Material selection in Mechanical 1.
Design, Butterworrth Heinneman, 2005 Ashby, Material selection in Mechanical
2. Engineering, Pergamon Press, 2004
John A. Schey, Introduction to Manufacturing 3.
Processes, McGraw Hill, 1999 Degarmo, E. Paul, Materials and Processes
4. in Manufacturing, Prentice Hall Int. Inc,
8th edition, 2005 Kalpakjian, S, Manufacturing Engineering
5. and Technology, McGraw Hill 4th edition,
2001.
Buku Panduan Prakt ikum Proses Produksi,
6. Departemen Teknik Mesin FTUI.
ENME600008 ENME610008
KINEMATICS and DYNAMICS 4 SKS Course Obj ective:
The st udent s have t he abilit y t o underst and
the key concept of kinematics and dynamics of mechanical system and capable to analyse
t he movement , vel ocit y, accel erat ion f orca and equilibrium.
Syllabus: Vect or velocit y analysis, f ree body diagram,
linier motion, velocity polygon, 2D motion, rectangular coordinates, N-T and pole, rela
-
tive motioan and velocity of 2 coinciderelate point, Coriolis acceleration and stiff body
kinematics, Inertia Force, Statics, particle system, works, energy, impuls, linear-angular
moment um, st if f body mot ion, works and en- ergy, relat ive mot ion, rot at ing mass balancing
and back forth motion, cam dynamics and Giroscope.
Requirements:
Mechanical visalization and modeling, Fun
-
damental of Mechanical Design, Mechanical
Design References:
Meriam Kraige, Engineering Mechanics. 1.
Vol-2, Wiley New York.4th, 1998. Holowenko, Dynamics of Machinery, John
2. Wiley, 1995.
Beer Johnston, Mechanics for Engineer, 3.
Dynamics, Mc Graw-Hill, 1976.
ENME600009 ENME610009
BASIC FLUID MECHANICS 4 SKS Course Obj ective:
Fluid meachanic are one of the applied me
- chanical science branch t hat will be used t o
i nvest i gat e, anal yse, and l ear n t he nat ur e
and the behavior of luids. Fluid that will be explored could be a moving or stationary luid.
Fluid Mechanics course intends to complement the ability of a student to be able to apply
the basic laws of luid mechanics in practical engineering calculations of luid mechanics
and be able to analyze the behavior of the luid and developing knowledge in the ield of
luid mechanics.
Syllabus:
Fluid and its nature, luid statics, the relative balance, concept and basic equations of luid
low, dynamic of low, the equation of luid motion Newton, Euler, Navierstokes, Basic
Equation of Fluid Dynamics Continiuty, Energy
and moment um, diment ional anal ysist and
hydraulic similarity, ideal luid low, viscous low, viscous low: transition from laminar
into turbulent low, fully developed turbulent low, low around submerged objects, general
characteristic of outside low, concept and characteristic of layer in closed low, mea
-
surement and visualization of low, pressure measurement concept, low and capacity, low
measurement devices Pit ot t ube, Vent uri,
oriice, Nozzel, HWA, LDV, Flow visualization
met hod. Requirement:
-
References:
Munson, B.R., Fundamentals of Fluid 1.
Mecha-nics 4th Ed, John Wiley Sons, Inc. 2000
Smit s, A. J. , A, Physical Int roduct ion t o
2. Fluid Mechanics, John Wiley Sons, Inc.
2000 Kumar, K.L., Engineering Fluid Mechanics,
3. Eurasia Publishing House Ltd., 2000
ENME600010 ENME610010
MECHANICAL DESIGN 4 SKS Course Obj ectives:
Give the understanding about the application
of engineering mechanic science and mat erial st rengt h in machine el ement . The st udent s
have the basic competence to design the ma
- chine element .
Syllabus:
Basic mechanical design review, design of joint : welding, solder, adhesive bonding, rivet, pin,
bolt, nut, thread, axel, shaft, hub, roller
lauch bearing, lubricat ion, wear and f rict ion,
spring, break, ixed and unixed clutch, chain, belt, basic of gear, straight tilt bearing, Fi
-
nal Assignment : Design process consist of the understanding of purpose, load and calculation
of machine element . Requirement:
Mechanical Visualization and Modeling; Engi
-
neering Materials; Fundamental of Mechanical
Design.
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References:
Hamrock, Fundamental of Machine 1.
Element, Mc Graw-Hill, 2004 Shigley, Joseph Edward, Mechanical
2. Engineering Design, McGrawHill., 2003
Sularso, Dasar Perencanaan Pemilihan 3.
Elemen Mesin, Pradnya Paramita, 1994 Hibbeler RC, Mechanics of Materials, 5th
4. ed., Prentice Hall, 2003.
Riley, F William, Engineering Mechanics: 5.
STATICS, John wiley sons
ENME600011 ENME610011
MECHANICAL VIBRATION 2 SKS Course Obj ective:
The st udent s have an underst anding of t he key
points and concepts of the mechanical vibra
- t ions of mechanical syst ems and have t he basic
competence to analyze the vibration behavior and what parameters can be controlled in order
to vibration damping.
Syllabus: Fundament al of mechanical vibrat ion in me-
chanical syst em, oscillat ory mot ion, f ree vibra- t ion, harmonic vibrat ion, t ransient vibrat ion,
system with 2 degree of freedom and system witih multi degree freedom, lumped param
- et ers syst em and cont inue syst em, Lagrange
equat ion, random and non-linier vibrat ion. Re quir e me nt s:
Engineering Mathematics,
Kinemat ics and Dynamics Referencess:
Meriam Kraige. Engineering Mechanics. 1.
Vol- 2, Dynamics. Wiley New York.4th eds.1998.
Holowenko. Dynamics of Machinery.John 2.
Wiley.1995.
William T.Thomson. Theory of Vibrat ion wit h
3. application. Prentice Hall India.1972.
Beer Johnston.Mechanics for Engineer- 4.
Dynamics.Mc-Graw-Hill.1976.
ENME600012 ENME610012
METROLOGY AND MEASUREMENT 3 SKS Course Obj ective:
Introduce students to modern experimental techniques for mechanical engineering; pro
-
vide exposure to and experience with a variety
of sensors used in t hermo-mechanical syst ems,
including sensors to measure temperature, pressure, displacement, velocity, acceleration
and st rain; examine t he role of error and uncer-
tainty in measurements and analysis; exposure to and experience in using commercial soft
- ware f or dat a acquisit ion and analysis; discuss
the role and limitations of spectral analysis of digital data; provide experience in working in a
team in all aspects of the laboratory exercises, including set-up, data collection, analysis and
report writing
Syllabus:
the basic concept of measurement and metrol
- ogy, measurement t erminology and syst ems,
indust rial measurement and syst em t erminol-
ogy, temperature measurement, pressure and low measurement, force, stress, data acquisi
-
tion, motion measurement : position, velocity, vibration and acceleration, types of sensors
transducer, transfer function, FFT and iltering,
uncert aint y analysis, geomet ric and dimension calibrat ion, room diment ion, met rology lengt h
measurement , surf ace t ext ure, roughnes and
roundness, latness and straightness, angle measurement, introduction to CMM
Requirement: -
References:
Busch, Ted, Fundament als of Dimensional
1. Metrology, 4th Ed, Delmar Publishers
Fargo F.T., Curtis, M.A., Handbook of 2.
Dimensional Measurement, 3rd Ed,
Indust rial Press.
Slocum, A., Precision Machine Design, SME 3.
Press, 1992. Raldi Artono Koestoer, Pengukuran Teknik,
4. Departemen Teknik Mesin FTUI.
ENME600013 ENME610013
HEAT AND MASS TRANSFER 4 SKS Course Obj ective:
This course st udies about t he heat and mass t ransf er mechanism wit hin a volume cont rol
system due to the temperature gradient, this
course st rict ly relat ed t o t he basic t hermody-
namics course. The purpose of this course is to develop the understading from the students
about several heat and mass t ransf er mecha-
nism between two systems if the temperature
gradient ocure and t he st udent s able t o cal- cul at e t he heat t ransf er rat e. The st udent s
capable to solve numbers of heat transfer probles using non-dimensional parameter.
Syllabus: Fundament al of heat t ransf er, conduct ion heat
transfer 1 dimentional and 2 dimentional,
numerical analysis in conduct ion heat t rans-
ferunsteady state, forced convection heat
t ransver, f ree convect ion heat t ransf er, boiling and condensat ion, heat exchanger, radiat ion,
f undament al of mass t ransf er, st eady st at e mol ecul di f f usi on, unst eady st at e mol ecul
dif f usion, convect ion mass t ransf er, convec- t ion mass t ransf er correlat ion, mass t ransf er
apparatus.
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Requirement: Basic Thermodynamic
Referencess:
Frank P Incropere, David P De Witt, 1.
Fundamental heat and mass transfer, 5th Ed., John Wiley Sons, 1996, New York
Holman JP, Heat Transfer, 9th, Mc Graw 2.
Hill, 2003. Koestoer, RA, Perpindahan Kalor untuk
3. Mahasiswa Teknik, Salemba Teknika,
2003. Welty R James, Wicks Charless, Wilson
4. Robert, Fundamentals of Momentum,
Heat, and Mass Transfer, 3rd Ed. John Wiley Sons, 1996, New York
Cengel, Yunus, Heat Transfer a Practical 5.
Approach, 2nd Ed. Mc Graw Hill, 2003, Singapore.
Kreith Frank, Bohn Mark, Principles of Heat 6.
Transfer, 6th Ed. Brookscole, 2001, USA
ENEE600017 ENEE610017
ELECTRICAL POWER ENGINEERING 2 SKS Refer to Page 179
ENME600015 ENME610015
SYSTEM CONTROL 4 SKS Course Obj ective:
Syst em cont rol is one of t he sciences discussed
about the method to control the value of pa
- ramet ers wit hin a syst em. Paramet ers wit hin
the system in this course are base on physic that could be position, velocity, rotation,
pressure, acceleration low rate, tempera
- t ure and ot her variables. This course aims f or
st udent s t o underst and t he basics, analysis, and engi neer i ng desi gn and cont r ol syst em
compensation techniques, and be able to
choose a cont rol syst em cont roller is right f or a mechanical syst em.
Syllabus:
Introduction to system control, laplace trans
-
form, reverse laplace transform, solution for
l inier ordinary dif f erent ial equat ion, mat h- emat i cal model i ng I-IV, cont r ol act i on, PID
controller, electronic controller, pneumatic and hydraulic control, transient response analysis
I and II, root place analysis, design of system control with root place analysis method, fre
-
quency response analysis, stability analysis, MATLAB laboratory activity, design of control
system with response frequency method, dis
- cret e t ime syst em and Z-Transf orm, PID con-
trol and introduction to robust control, space
condit ion analysis I-II, design of cont rol syst em
within space condition, liapunove stability analysis and omptimum square control.
Requirements:
Physic 1mechanical and heat, Physic 2 electric, magnetic, wave and optic,
engineering mat hemat ic. References:
Ogata, Katsuhiko., Modern Control 1.
Engineering, Prentice-Hall Int., Inc. 1997 Francis H, Raven., Automatic Control
2. Engineering. McGraw-Hill,1987.
Cheng, David K., Analysis of Linear System, 3.
Addison–Wesley P. C., Inc.
ENME600016 ENME610016
FLUID SYSTEM 3 SKS
Fluid system is applied science and engineering of basic luid science which studies the utiliza
-
tion of characteristic, behavior and properties of luid and its low behavior in various luid
machines i.e. rotodynamics, reciprocating, hydraulic and pneumatic system. The course
is intended to equip student to understand characteristic of turbo luid machines, hydrau
-
lic and pneumatic system and to be able to calculate and design a luid system.
Syllabus:
Basic Thermo luid in a Fluid System; Energy Transfer from Fluid to Rotor; Lagrangian and
Eularian Approach; Energy Transfer Compo
-
nents; Impulse and Reaction; Turbo machinery Analysis with Flow; Operational Aspects of
Rotodynamic Machinery; Hydraulic Similarities on Fluid Machinery; Reciprocating Machinery:
Classiication, Main Component and Operating; Discharge and Coeficient Discharge; Work and
Power; Basic Hydraulic Machines; Hydraulic Machines; Hydraulic Accumulator; Hydraulic
Intensiier, Hydraulic Press; Hydraulic Crane; Hydraulic lift; Pneumatic System: Basic Laws,
Pressure Drop Losses, Basic Control Valve of Pneumatic Circuit.
Pr er equi si t e: Basi c Ther modynami cs, Basi c
Fluid Mechanics References:
Dixon, S.L, Fluid Mechanics and 5.
Thermodynamics of Turbo machinery, 4th Edition, Pergamon Press, 2005
Esposito, A., Fluid Power with Application, 6.
5th Edition, Prentice Hall, 2003 Mobley, R.K, Fluid Power Dynamics,
7. Newnes Butterworth-Heinemann, 1999
Giles, R.V, Fluid Mechanics and Hydraulics, 8.
2nd Edition Schaum’s Outline Series, Mc- Graw-Hill, 1994
ENME600017 ENME610017
MAINTENANCE AND CONDITION MONITORING 3 SKS
Course Obj ective: This course gives t he underst anding and t he
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ability to analyze a system and design a system for maintenance and its procedure to improve
the eficiency and reliability within a system. To give the understanding and competence
to develop and implementation of vibration
monit oring and engine condit ion so t hat t he
mechanical system reach the optimum per
-
f ormance. Syllabus:
Quality, Reliability and Maintainability, main
- t enance syst em st r at egy, f ai l ur e anal ysi s,
design of maint enance syst em and scheduling,
maintenance system organization, condition
monit oring and condit ion based maint enance,
computer based maintenance system, total productive maintenance TPM and its imple
- ment at ion, t he ef f ect iveness measurement of
total productive maintenance, reliability based maintenance system, planning;measurement
and standardization of maintenance work,
qualit y of maint enance syst em, basic t heory of vibrat ion and engine condit ion, basic of engine
condit ion monit oring, vibrat ion monit oring de- vice in several mechanical syst ems and engine
condit ion analysis. Requirements:
Mechanical Vibration
References:
Niebel, B.W., Engineering Maintenance 1.
Management, Marcel Dekker, Inc. 1994 Higgin, L.R., Maintenance Planning and
2. control, Mc Graw Hill Book Company,
1998 Mishra, R.C., and K. Pathak, Maintenance
3. Engineering and Management, PHI, 2002
Bruel Kjaer. Handbook of Vibration 4.
Condition Monitoring
ENME600018 ENME610018
ENERGY CONVERSION AND CONSERVASION 4 SKS
Course Obj ectives: This course discusses about t he energy resourc-
es, type and classiication of energy, energy conversion, energy consumption, basic concept
of energy conversion, power resources and classiication of energy conversion enginess.
The st udent s underst and t he energy source,
type of energy conversion engine, conversion
and conservasion of energy syst em, and also ca-
pable to perform a basic calculation of energy conversion engine performance and critical
considerat ion of energy conversion. Syllabus:
Deinition of energy and energy resources, type and energy classiication, law and equation in
energy conversion, energy proile resources,
reserves and t he world’s and Indonesia’s energy
needs, basic concept of energy conversion system, power resources and classiication
of energy conversion engine, f uel in energy conversion, renewable energy, non-renewable
energy, classiication of combustion engine, calculation for internal combustion engine per
-
formance, steam power plant, luid machinery, cooling engine classiication, thermodynamic
cycl e of cool i ng engi ne, ener gy conver si on met hod i n vehi cl e, i ndust r y and bui l di ng,
laborat ory act ivit y. Requirements:
Basic Thermodynamics, Basic
Fluid Mechanics, Heat and Mass Transfer
Referencess:
Kreith, F, Goswami, DY, Energy Conversion 1.
Mechanical Engineering, CNC Press, 2007
Kreith, F, Goswami, DY, Energy management 2.
and Conservation Handbook, CNC Press, 2007
Patrick, D.R., et.al, Energy Conservation 3.
Guidebook, 2nd, 2007 Dincer, I., Rosen, Thermal Energy Storage:
4. Systems and Applications, John Wiley,
2002 Panduan Praktikum Prestasi Mesin Konversi
5. energi, Departemen Teknik Mesin versi
2003. Depok 2003.
ENME600019 ENME610019
MECHATRONICS 4 SKS Course Obj ective:
This course provides the ability to design electrical-mechanical that properly meet the
needs of a process speciication and a design
t hat given in a laborat ory scale wit h t he me- chani cal , el ect r i cal t heor y and aut omat i on
cont rol. Syllabus:
Mechatronics concept and theory, electronics analog system, electronis analog components,
elect ronics digit al syst em, analog and digit al i nt er f ace, sensor s and act uat or s el ect r i c
motor, pneumatic, hydraulic, principles of microprocessor and microcontroller, micro
-
controller based control system theory, C C
++
programming for electrical-mechanical for control, programmable logic controller PLC,
Laborat ory act ivit y. Re qui r e me nt s:
Physic 1Mechanical and Heat, Physics electrical, magneticm wave
and optic
References:
Smaili A. dan Mrad F., Applied Mechatronics, 1.
Oxford University Press, 2007 Sabri Cetinkunt, Mechatronics, Wiley,
2. 2006
Histand, M.B., Alciatore, D.G., 3.
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Introduction to Mechatronics and Measurement System, McGraw-Hill,
Singapore, 1999. Fraser, C. dan Milne, J, Electromechanical
4.
Engineering, An Int roduct ion, IEEE Press,
McGraw-Hill, New York, 1994. Gandjar K, Hand-out Mekatronika, DTMUI,
5. 2007
ENME600020 ENME610020
DESIGN ASSIGNMENT 4 SKS Course Obj ective:
The st udent s have t he abi l i t y t o desi gn a
mechanical system or product by using the knowledge and skills that previously obtained.
The students capable to work in a team, com
-
municate, report and defend and presenting the inal project.
Syllabus:
Fundamental of problems and mechanical design process, teamwork in design, design
process planning, understand the problem and develop engineering speciications, concept
generation, evaluation and selection, product design phase, product generation, evalua
-
tion and performance, product evaluation or
mechani cal syst em f or cost , manuf act ur e, assembling and ot hers.
Requir ement s:
Engineering Materials, Me
-
chanical Design, Material Selection and Manu
- f act uring Process.
References:
David G.Ullman. The mechanical design 1.
process. Mc.Graw Hill.1997. George Dieter. Engineering Design: A
2. Material and Processing Approach.2000.
G.Pahl and W.Beitz. Engineering Design: 3.
A Systematic Approach. Springer Verlag.1991.
ENME600025 ENME610025
CAPITA SELECTA 2 SKS Course Obj ective:
Able to understand industrial development and its problems.
Syllabus:
Special topics in industries which are not cov
- ered in ot her courses.
Requirement:
-
References: - ENME600022
ENME610022 INTERNSHIP 2 SKS
Course Obj ective:
The course is intended to provide opportunity for gaining experience in industries and apply
- ing mechanical engineering knowledge. Able t o
perform management tasks and engineering technique according to ield of interest.
Syllabus:
Management and Engineering according to the ield of interest. Presentation of on the job
training results and report.
Requirement:
Passed 95 SKS and GPA 2.00
ENME600021 ENME610021
TECHNOPRENEURSHIP 2 SKS Course Obj ective:
To give insight in increasing st udent ’ s abilit y
who has not only high comptency in Mechanical Engineering but also enterpreneurship spirit,
hence achieving excellence among t heir com-
petitors and also dare to initiate new ideas as enterpreneurs. The student is expected to be
able to develop commercial business for him
- self and ot hers in order t o be excellent and has
broader choices in t eh real world. Syllabi:
Business: Enterpreneurship; Business and Ethics; Introduction on Business Fields. Man
-
agement: Corporate Leadership; Innovative Product-based Company, Innovative Product-
based Busi ness Admi ni st r at i on. Fi nanci ng:
Introduction on Capital and Financing, Practical Accounting for Non-Accountant; Financing Man
- agement ; Int roduct ion on Pricing Technique;
Bankable- Business Proposal Development.
Syllabus:
Basic Mechanical Design; Manufac
-
ture and Material Selection Processes; Design
Assignment . References:
Richard C. Dorf, Thomas H. Byers, 1.
Tech- nol ogy Vent ur es, f r om i dea t o ent er pr i se
,
McGraw Hill, 2008 Robert G. Cooper,
2.
Wi nni ng at New Pr od- uct s
, l at est edit ion, Basic Books-Perseus
Group, 2003 Arman H.N., Bustanul A.N., M. Suef,
3.
“ Mem-
bangun Spi r i t Teknopr eneur shi p ”
, penerbit Andi, Yogyakarta, 2007
Arman H.N., Indung S., Lantip T., 4.
“ Mana-
j emen Pemasar an unt uk Engi neer i ng ”
,
penerbit Andi, Yogyakarta, 2006
ENME 6 0 0023 ENME 6 1 0023
FINAL PROJECT 4 SKS
Learning Obj ectives:
Students are able to 1 prepare a research pro
- posal based on good understanding of research
methodology, 2 prepare a well-written research
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report in Bahasa Indonesia, and 3 present and def end research result s.
Syllabus :
Synthesizing various lectures taken by st udent s t o design or t o sol ve engineering
problems. Preparing a written report of the synt hesis.
Prerequisites :
Passing 128 credits with GPA = 2,00 and without grade of E
ENME 6 0 0024 ENME 6 1 0024
ENGINEERING ETHICS 2 SKS
Learning Obj ectives: Syllabus:
Pre-requisites: Textbooks:
ELECTIVE COURSE FROM MASTER PROGRAM ENERGY CONVERSION STREAM
ENME800114 COMBUSTION ENGINEERING 4 SKS
Refer to Page 415
ENME800115 INTERNAL COMBUSTION ENGINE 4 SKS
Refer to Page 415
ENME800116 APPLIED FLOW MEASUREMENT AND
VISUALIZATION 4 SKS Refer to Page 415
ENME80117 CFD APPLICATIONS 4 SKS
Refer to Page
ENME800111 HEAT AND MASS TRANSFER ENGINEERING
4 SKS Refer to Page 413
ENME800112 AERODYNAMIC ENGINEERING 4 SKS
Refer to Page 414
ENME800113 POWER GENERATION 4 SKS
Refer to Page 414
BUILDING UTILITY SYSTEM AND FIRE SAFETY STREAM
ENME800202 BUILDING MECHANICAL AND ELECTRICAL
SYSTEM 4 SKS Refer to Page 417
ENME800214 REFRIGERATION ENGINEERING 4 SKS
Refer to Page 418
ENME800215 FIRE SAFETY AND PROTECTION ENGINEERING
4 SKS Refer to Page 419
ENME800211 VENTILATION AND AIR CONDITIONING SYSTEM
4 SKS Refer to Page 417
ENME800212 BUILDING UTILITY SYSTEM DESIGN 4 SKS
Refer to Page 418
ENME800213 ENERGY AUDIT 4 SKS
Refer to Page 418
DESIGN AND PRODUCT MANUFACT URING STREAM
ENME800314 MICROFABRICATION AND PRECISION MANU-
FACTURING 4 SKS
Refer to Page 421 ENME800315
DYNAMICS OF MECHANICAL SYSTEM 4 SKS Refer to Page 422
ENME800316 COMPOSITE PRODUCT DEVELOPMENT
4 SKS Refer to Page 422
ENME800317 FINITE ELEMENT AND MULTIPHYSICS 4 SKS
Refer to Page 422
ENME800311 DESIGN FOR MANUFACTURE AND ASSEMBLY
4 SKS Refer to Page 420
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ENME800312 MECHANICAL FAILURE 4 SKS
Refer to Page 420
ENMEB00313 NOISE AND VIBRATION
Refer to Page 421
AUTOMATION AND MANUFACTURING SYSTEM STREAM
ENME800413 SYSTEM MACHINE VISION 4 SKS
Refer to Page 423
ENME800414 QUALITY AND PRODUCTION MANAGEMENT
SYSTEM 4 SKS Refer to Page 421
ENME800411 CAD CAM 4 SKS
Refer to Page 423
ENME800412 MANUFACTURING PERFORMANCE ASSESMENT
4 SKS Refer to Page 423
ENME800402 AUTOMATION AND ROBOTICS 4 SKS
Refer to Page 428
VEHICLE ENGINEERING AND HEAVY EQUIPMENT STREAM
ENME800513 MODERN VEHICLE TECHNOLOGY 4 SKS
Refer to Page 425
ENME800514 OIL AND GAS DRILLING EQUIPMENT 4 SKS
Refer to Page 426
ENME800511 RAILWAY VEHICLE ENGINEERING 4 SKS
Refer to Page 424
ENME800512 HANDLING AND CONSTRUCTION EQUIPMENT
4 SKS Refer to Page 424
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4. 4. UNDERGRADUATE PROGRAM IN NAVAL ARCHITECTURE AND MARINE ENGINEERING Program Speciication