114 The groups of the courses can be seen according to the char acteristic and the education purposes that are expected as shown in figure below
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 Subject
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-
tion 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 Pembangkitan Daya Power Generation 4
Building Utility System and Fire Safety Stream 2.
Code Mata Kuliah Subject
Credits Semester 7
7 th Semester
ENME 8 0 0214 Teknik Refrijerasi Refrigeration Engineering 4
ENME 8 0 0215 Teknik Keselamatan dan Proteksi
Kebakaran Fire Safety and Protection
Engineering 4
Semester 8 8 th Semester Credits
ENME 8 0 0211 Sistem Ventilasi dan Tata Udara Air Conditioning and Ventilation System 4 ENME 8 0 0212 Perancangan Sistem Utilitas Bangunan Building Utility System 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 Subject
Credits
Semester 7 7 th Semester
ENME 8 0 0314 Fabrikasi Mikro dan Manufaktur Presisi Microfabrication and precision manufac-
turing 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
Perakitan 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 Subject 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
System 4
Semester 8 8 th Semester Credits
ENME 8 0 0411 CAD/CAM CAD/CAM 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 Subject 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 5th Semester the undergraduate program.
Have an excellent academic record, with 3.0 GPA until 5
2. th 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 full time 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 first 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 classified 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
Basic Engineering Courses (27 Credits)
Basic Mechanical Engineering
Courses (48 Credits)
University Courses (7 Credits)
To be completed at patner universities (72 credits)
Mechanical Engineering Competence Course -
Compulsory
Mechanical Engineering Competence Courses
- Elective
Undergraduate Thesis/Final Project
UNDERGRADUA TE PROGRAM
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CODE SUBjECT
1 st Semester SKS
UIGE 6 1 0002 Academic Writing 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 Statistics and Probability 2
ENME 6 1 0024 Engineering Ethics 2
Subtotal 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
Sports/Arts 1
Subtotal 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 Kinematics and Dynamics 4
ENEE 61 0017 Electrical Power Engineering 2
Subtotal 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
Subtotal 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 System 3
Subtotal 20 6 th Semester
UIGE 6 1 0004 Integrated Character Building Subject B 6 ENME 6 1 0017 Maintenance and Condition Monitoring 3
UNDERGRADUA TE PROGRAM
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CODE SUBjECT
6th Semester SKS
ENME 6 1 0019 Mechatronics 4
ENME 6 1 0021 Teknoprneurship 2
ENME 6 1 0020 Design Assignment 4
Subtotal 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
Subtotal 16 8 th Semester
ENME 6 1 0023 Final Project 6
Elective 3 4
Elective 4 4
Subtotal 14
ELECTIVES
ENME 8 0 0411 CAD/CAM 4
ENME 8 0 0113 Power Generation 4
UNDERGRADUA TE PROGRAM
121
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 Stress Analysis
Engineering Mathematics 3, or Electives
12 12 12 12
ENB215 ENB321 ENB331
Fundamentals of Mechanical Design Flu- ids Dynamics
Materials and Manufac- turing 2
Elective / Minor
12 12 12 12
subtotal 48 subtotal 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
subtotal 36 Subtotal 48
Table 7. Course Structure of Mechanical Engineering at University of Queensland For July Intake
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 System Design
Advanced Dynamics and Vibration
Fluid Mechanics
2 2 2 2
MATH2010 STAT2201 MECH3300 MECH3400 MECH3600
Analysis of Ordinary Differential Equation Analysis of Engineering and Scientific Data
Finite Element Method and Fracture Mechanics Thermodynamics and Heat Transfer
Engineering Management and Communication
1 1 2 2 2
subtotal 8 subtotal 8
Year 4 Semester 7 (UQ) July Credits Year 4 Semester 8 (UQ) March
Credits
KODE Course Title KODE Course Title
MECH4501 Engineering Thesis Elective
Elective Elective
4 2 2 2
MECH4501
METR3200 Engineering Thesis Introduction to Control System
Elective Elective
4 2 2 2
subtotal 10 subtotal 10
UNDERGRADUA TE PROGRAM
122
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 Acoustics
Science & Engineering of Metals Engineering Analysis II
Materials Selection Net Shape Manufacturing Aerospace Propulsion Energy & Environment
Hypersonics & Rarefied 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 Intake
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 Sustainable Development
Engineering Law Mechanical Design Fluid Flow Modelling Automatic Control Electrical Plant
12.5 12.5 25 25 12.5 12.5
308801 308812 308813 308814
Thermal Engineering Processes
Industrial Technology Materials
Dynamic Systems
25 25 25 25
subtotal 100 subtotal 100
UNDERGRADUA TE PROGRAM
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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 Professional Practice Optional Unit Optional Unit
37.5 12.5 25 25
subtotal 100 subtotal 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 Finite Element Analysis Noise
25 25 25 25 25
12926 302863 302864 310545 312200 4282
Materials Vibration Heat Transfer Design Methodology Sustainable Energy Systems and Technologies
Mechanical Measurements
25 25 25 25 25 25
UNDERGRADUA TE PROGRAM
124
Course Description UIGE600001 UIGE610001
MPKT A / INTEGRATED CHARACTER BUILDING A 6 SKS
Refer to Page 74 UIGE600004 UIGE610004
MPKT B / INTEGRATED CHARACTER BUILDING B 6 SKS
Refer to Page 74 UIGE600002 ENGLISH UIGE610002 ACADEMIC WRITING 3 SKS
Refer to Page 74 UIGE600003 UIGE610003 SPORTS / ARTS 1 SKS
Refer to Page 77 ENGE600001 ENGE610001 CALCULUS 4 SKS
Refer to Page 74 ENGE600010 ENGE610010 BASIC CHEMISTRY Refer to Page 75 ENGE600003 ENGE610003 BASIC PHYSICS 1 4 SKS
Refer to Page 75 ENGE600004 BASIC PHYSICS 2 4 SKS
Refer to Page 77 ENGE600002 ENGE610002 LINEAR ALGEBRA 4 SKS
Refer to Page 75 UIGE600005-9 UIGE610005-9 RELIGIOUS STUDIES
2 SKS
Refer to Page 76-77 ENGE600005 ENGE610005
STATISTICS AND PROBABILITY 2 SKS
Refer to Page 78 ENGE600008 ENGE610008
HEALTH, WORK SAFETY, AND ENVIROMENT 2 SKS
Refer to Page 78 ENGE600009 ENGE610009
ENGINEERING DRAWING (2 SKS)
Learning Objective(s): 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 2D/3D geometric draw from component or con- struction. Students are able to draw the orthogo- nal projection based on ISO standard.
Syllabus: Illustration: Function and benefit of Engineering Drawing; SAP; Measurement and Evaluation; Introduction to drawing equipment;
Basic definition of geometric, paper format, draw regulation, line, field, line configuration, basic geometric form; Visualization geometric:
Skew projection and isometric, function and line types, configuration 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- tion.
Pre-requisite(s): - Text Book(s):
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.
UNDERGRADUA TE PROGRAM
125
ENME600001 ENME610001
MECHANICAL VISUALIZATION AND MODELLING (3 SKS)
Course Objective:
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 understand clearly by the user.
Syllabus:
The purpose and the advantage of the drawing in the design and manufacturing process, sur- face working quality and tolerance, standard and marking classification of working quality, standard and marking classification of working tolerance, Welding construction, standard and marking of kampuh (seam?) and welding, line diagram, 2D and 3D representation method, introduction to modeling software interface, modeling, manipulation and 2D & 3D visual- ization.
Requirement: Engineering Drawing References:
A.W. Boundy, Engineering Drawing, 1. McGraw-Hill Book Company
Colin Simmons & Dennis Maguire, Manual 2. of Engineering Drawing 4th 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 Objective:
Complete student’s anylitical ability. Students understand and able to use the advances mathematical concepts in order to solve the engineering problems.
Syllabus:
Introduction to differential equation, 1st order differential equation, 2nd order differential equation, higher order differential equation, vector analysis, vector differential, grad opera- tion, divergence and culr, vector integration, laplace transform, laplace transform to solve the differential equation, fourrier transform, convulsion, numerical method, root of equa- tion, numerical differentiation, numerical
integral.
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 HillKreyszig, E, Advanced Engineering 3. Mathematics 10th Edition, John Wiley
and Sons ENME600003 ENME610003
ENGINEERING MATERIALS (4 SKS) Course Objective:
Engineering materials are one of the basic knowledge in field of design, especially in mechanical engineering. From the discussion of the behavior of several materials, the stu- dents are expected to have the overview about several thing that has to be the concern related to the working process or the specific need.
The students are expected to have the basic ability to identify and explain the nature and behavior of materials related to the treatment in working process and specific need.
Syllabus:
Introduction to the importance of the engineer- ing material science in mechanical engineering, atomic structure, crystalic material, metal and non metal material, process, phase diagram and solidificatiom, heat treatment process, mechanical behavior of crystalic material, elastic material, plastic deformation, crystal plasticity, method of material mechanical testing, dislocation, strengthening, failure and remaining lifetime of material, introduc- tion to mechanical crack and steel mechanical structure behavior, material structure degrada- tion, corrosion process, corrosion prevention, Oxidation, wear and erotion, concrete mate- rial behavior, wood, cement and its structure behavior.
Requirement: - References:
Kalpakjian, Manufacturing Engineering and 1. Technology, Addison Wesley- 2008
Thomas H. Courtney, Mechanical Behavior 2. of Materials, 2nd 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
UNDERGRADUA TE PROGRAM
126
ENME600004 ENME610004
BASIC THERMODYNAMICS (4 SKS) Course Objective:
This course introduces the basic concept of thermodynamics and its application in real life and gives the understanding about the design of thermodynamics system.
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, first law of thermodynamics, second law of thermody- namics, thermodynamics equation, gas power cycle, gas compressor, combustion engine cycle, internal combustion engine , simple gas turbine cycle, brayton’s cycle, stirling’s cycle, steam power cycle, refrigeration, carnot’s cycle, simple rankine’s cycle, rankine’s cycle with modification, biner cycle, phsycometrich chart, cooling tower, 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
Kenneth Wark Jr. Thermodynamics , 4. Mc.Graw Hill
H.D. Baehr, Termodynamik , Springer 5. Verlag
ENME600005
FUNDAMENTAL OF MECHANICAL DESIGN (4 SKS)Course Objective:
This course gives the basic knowledge in material strength and mechanics of system that will be needed in engineering of machine elements.
Syllabus:
Design consept, load and support reaction in the construction, normal force diagram, shear and moment in beam, calculations in beam construction, Trusses, Frame & Machine, 2nd Area Moment and Intertia, stress and strength, normal stress, torsion and bending, deforma- tion, beam with indeterminate static load, Buckling, solid state materials, failure analysis for static load, failure analysis for 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 Objective:
To give the knowledge, understanding and com- petence about the theory, application method and product manufacturing process technology that consist of: characteristic and how the 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 to the material characterisc that needed in every process.
Syllabus:
Manufacturing process and production system, materials in manufactur, theory and method in metal casting, theory and method of bulk formation, theory and method of sheet metal 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 materials, correlation of material and process characteristic, process parameter control of material, Desing of material selec- tion and manufacturing process that related to the market needs (assignment), Laboratory activity.
Requirement: Engineering Material
UNDERGRADUA TE PROGRAM
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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 Praktikum Proses Produksi, 6. Departemen Teknik Mesin FTUI.
ENME600008 ENME610008
KINEMATICS and DYNAMICS (4 SKS) Course Objective:
The students have the ability to understand the key concept of kinematics and dynamics of mechanical system and capable to analyse the movement, velocity, acceleration forca and equilibrium.
Syllabus:
Vector velocity analysis, free body diagram, linier motion, velocity polygon, 2D motion, rectangular coordinates, N-T and pole, rela- tive motioan and velocity of 2 coincide/relate point, Coriolis acceleration and stiff body kinematics, Inertia Force, Statics, particle system, works, energy, impuls, linear-angular momentum, stiff body motion, works and en- ergy, relative motion, rotating 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 Objective:
Fluid meachanic are one of the applied me- chanical science branch that will be used to investigate, analyse, and learn the nature and the behavior of fluids. Fluid that will be explored could be a moving or stationary fluid.
Fluid Mechanics course intends to complement the ability of a student to be able to apply the basic laws of fluid mechanics in practical engineering calculations of fluid mechanics and be able to analyze the behavior of the fluid and developing knowledge in the field of fluid mechanics.
Syllabus:
Fluid and its nature, fluid statics, the relative balance, concept and basic equations of fluid flow, dynamic of flow, the equation of fluid motion (Newton, Euler, Navierstokes), Basic Equation of Fluid Dynamics (Continiuty, Energy and momentum), dimentional analysist and hydraulic similarity, ideal fluid flow, viscous flow, viscous flow: transition from laminar into turbulent flow, fully developed turbulent flow, flow around submerged objects, general characteristic of outside flow, concept and characteristic of layer in closed flow, mea- surement and visualization of flow, pressure measurement concept, flow and capacity, flow measurement devices ( Pitot tube, Venturi, orifice, Nozzel, HWA, LDV), Flow visualization method.
Requirement: - References:
Munson, B.R., Fundamentals of Fluid 1. Mecha-nics 4th Ed, John Wiley & Sons,
Inc. 2000
Smits, A.J., A, Physical Introduction to 2. Fluid Mechanics, John Wiley & Sons, Inc.
2000Kumar, K.L., Engineering Fluid Mechanics, 3. Eurasia Publishing House Ltd., 2000
ENME600010 ENME610010
MECHANICAL DESIGN (4 SKS) Course Objectives:
Give the understanding about the application of engineering mechanic science and material strength in machine element. The students 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, lubrication, wear and friction, spring, break, fixed and unfixed 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