Course - University of Malaya

Transcription

Course - University of Malaya
Guidebook for
UNDERGRADUATE
SESSION2014/2015
BACHELOR OF ENGINEERING (CHEMICAL)
DEPARTMENTOFCHEMICALENGINEERING
FACULTYOFENGINEERING,UNIVERSITYOFMALAYA
GUIDEBOOK FOR UNDERGRADUATE
DEPARTMENT OF
CHEMICAL ENGINEERING
ACADEMIC SESSION 2014/2015
Table of Contents
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UM Statements: Mission, Vision and Core Values
Faculty of Engineering Statements: Mission,
Vision, Student and Academic Programmes
Message From The Dean
Management Team
Administrative Staff
Academic Schedule
Prohibition Against Plagiarism
Engineering Library
Brief Profile of Department
Introduction of Outcome Based Education (OBE)
Programme Educational Objectives (PEO) And
Programme Outcomes (PO)
Academic Staff
Supporting Staff
Curriculum Structure
Academic Planner
Requirements For Graduation
Course Pro-Forma
University of Malaya STATEMENTS
Mission
To advance knowledge and learning
through quality research and
education for the nation and for
humanity
Vision
To be an internationally renowned
institution of higher learning in
research, innovation, publication
and teaching
Core values
*Integrity *Respect * Social
* Responsibility * Open-mindedness
* Academic Freedom * Professionalism
* Accountability * Teamwork
*Creativity *Meritocracy
Faculty of Engineering STATEMENTS
Mission
To advance engineering knowledge and learning
through quality education and research in the
pursuit of fulfilling the aspirations of the University and nation .
To be an internationally renowned Faculty of Engineering in research , innovation , publication
and teaching.
Quality Products


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


Produce highly competent and skilled individuals with leadership qualities and good interpersonal skills.
Produce good citizens who respect universal
human values.
Produce students with diverse backgrounds
who respect and internalize diversity.
Produce students incalculated with social
awareness and obligation values.
Produce students with international outlook
and outreach.
Produce highly competent engineers capable
of identifying, formulating, and solving problems in a creative and innovative manner.
Vission
Academic
Programmes

Ensure academic programmes are
relevant, current, innovative and internationally recognized to meet national and global needs.

Continuously develop academic programmes that inspire and tap student’s potential.

Ensure academic programmes are
accredited by local and international engineering professional bodies.

Continuously develop programmes
that are relevant to industrial requirements.
Message from the DEAN
Assalamualaikum w.b.t and warm greetings
Welcome to the Faculty of Engineering
E
ngineering education at the tertiary
level began in Malaysia in 1956 with the establishment of the Engineering Department at University of Malaya’s Bukit timah campus in Singapore. Only a Bachelor Degree
course in Civil Engineering was offered then. The
department was upgraded to a faculty when University of Malaya relocated to its campus in Lembah Pantai in 1958.
In the same year, the second bachelor degree
course in Mechanical Engineering was introduced.
A year later, a Bachelor Degree course in Electrical
Engineering was added to the number of courses
available to undergraduates.
In 1970, the Faculty introduced the fourth course,
a bachelor degree in Chemical Engineering. All four
courses were turned into respective departments
in 1974. In the 1996/97 session, the Faculty introduced six other courses namely in Telecommuncation Engineering, Environmental Engineering, Materials Engineering, Computer Aided Design and Manufacturing Engineering and Biomedical Engineering.
To-date, the Faculty has six departments, Civil Engineering, Biomedical Engineering, Chemical Engineering, Electrical Engineering, Mechanical Engineering and Engineering Design & Manufacture.
The Faculty now offers 12 programmes, with the
lates addition of the Bachelor of Biomedical Engineering (Prosthetics and Orthotics) which was introduced in the 2009/2010 session.
All engineering courses, offered by University of
Malaya, have been accredited by the Engineering
Accreditation Council (EAC), the Board of Engineers,
Malaysia (BEM) in order for all undergraduate engineering students to register with them, upon grad-
uation. All programmes have been structured such,
that they meet the nation and the stakeholder’s
vision of producing responsible, multi-talented and
highly qualified engineers of excellent leadership
quality. This is evident from the Programme Outcome and Programme Educational Objectives
mapped out for each course offered.
In line with the global tertiary education scenario,
efforts are in place to drive the Faculty towards excellence and to ensure that the human capital produced
by the university meets current needs.
Towards this direction, the Faculty has adopted the
National Tertiary Education Strategic Plan and inputs
from various stakeholder programmes as the basis to
improve the quality, competitiveness and creativity
of each course offered. As a preliminary step to ensure that all courses offered are relevant to market
needs, the Faculty is reviewing the overall curriculum
in order to produce engineering graduates of high
calibre.
PROFESOR IR.DR. NOOR AZUAN BIN ABU OSMAN
Dekan
The Management TEAM
DEAN
Prof. Ir. Dr. Noor Azuan Bin Abu Osman
E: azuan@um.edu.my
DEPUTY DEAN
(POSTGRADUATE STUDIES)
Assoc. Prof. Dr. Hazlie Mokhlis
E: hazli@um.edu.my
DEPUTY DEAN
(UNDERGRADUATE STUDIES)
Prof. Ir. Dr. Abdul Aziz Bin Abdul Raman
E: azizraman@um.edu.my
DEPUTY DEAN (DEVELOPMENT)
Dr. Noor Azizi Bin Mardi
E: azizim@um.edu.my
DEPUTY DEAN (RESEARCH)
Prof. Ir. Dr. Ramesh Singh
E: ramesh79@um.edu.my
HEAD OF DEPARTMENT
MECHANICAL ENGINEERING
Prof. Dr. Masjuki Hj. Hassan
E: masjuki@um.edu.my
HEAD OF DEPARTMENT
CIVIL ENGINEERING
Prof. Ir. Dr. Mohd Zamin Bin Jumaat
E: zamin@um.edu.my
HEAD OF DEPARTMENT
CHEMICAL ENGINEERING
Prof. Ir. Dr. Mohd Azlan Hussain
E: mohd_azlan@um.edu.my
HEAD OF DEPARTMENT
ELECTRICAL ENGINEERING
Prof. Dr. Hamzah Bin Arof
E: ahamzah@um.edu.my
HEAD OF DEPARTMENT
BIOMEDICAL ENGINEERING
Dr. Ahmad Khairi Abdul Wahab
E: khairi@um.edu.my
Office DIRECTORY
DEAN’S OFFICE
(UNDERGRADUATE STUDIES)
T: (603) - 7967 5200
F:(603) - 7967 1378
DEPUTY DEAN’S OFFICE
(DEVELOPMENT)
T: (603) - 7967 5202
F:(603) - 7967 7621
DEPARTMENT OF
CIVIL ENGINEERING
T: (603) - 7967 5203
F:(603) - 7967 5318
DEPARTMENT OF
ELLECTRICAL ENGINEERING
T: (603) - 7967 5205
F:(603) - 7967 5316
DEPUTY DEAN’S OFFICE
(UNDERGRADUATE STUDIES)
T: (603) - 7967 5201
F:(603) - 7967 5781
DEPUTY DEAN’S OFFICE
(RESEARCH)
T: (603) - 7967 4471
F:(603) - 7967 4478
DEPARTMENT OF
BIOMEDICAL ENGINEERING
T: (603) - 7967 4581
F:(603) - 7967 4579
DEPARTMENT OF
MECHANICAL ENGINEERING
T: (603) - 7967 5204
F:(603) - 7967 5317
DEPUTY DEAN’S OFFICE
(POSTGRADUATE STUDIES)
T: (603) - 7967 4471
F:(603) - 7967 4478
DEPARTMENT OF
CHEMICAL ENGINEERING
T: (603) - 7967 5206
F:(603) - 7967 5319
Administrative STAFF
ACTING PRINCIPAL ASSISTANT REGISTRAR /
SENIOR ASSISTANT REGISTRAR (POSTGRADUATE)
Mrs. Shahzatul Ermiza Johol
E: ermiza@um.edu.my
T: (603) - 79675356
F: (603) - 79561378
ASSISTANT REGISTRAR (UNDERGRADUATE)
Ms. Salbiah Samsudin
E: ssalbiah@um.edu.my
T: (603) - 79677636
F: (603) - 79561378
FINANCE OFFICER
Mrs. Siti Farhah Marhaini Binti Zainal Abidin
E: farhah_marhaini@um.edu.my
T: (603) - 79675225
F: (603) - 79561378
Academic Schedule SESSION 2014/2015
Induction
01.09.2014 – 07.09.2014
1 week
Lecture Week
08.09.2014 – 17.10.2014
6 weeks *~
18.10.2014 -26.10.2014
1 week@#
Lecture Week
27.10.2014 – 19.12.2014
8 weeks
Study Week
20.12.2014 – 28.12.2014
1 week+
Examination
29.12.2014 – 16.01.2015
3 weeks∧>
Semester Break
17.01.2015 – 22.02.2015
5 weeks©
Mid-Semester Break / Special Break
25 WEEKS
SEMESTER 1
Lecture Week
23.02.2015 – 10.04.2015
7 weeks
Mid-Semester Break
11.04.2015 – 19.04.2015
1 week
Lecture Week
20.04.2015 – 05.06.2015
7 weeks
Study Week
06.06.2015 – 14.06.2015
1 week
Examination
15.06.2015 – 03.07.2015
3 weeks
19 WEEKS
SEMESTER 2
Session break / special semester
Semester Break
Lecture and Examination
*
~
@
#
+
∧
>
<
©
04.07.2015 – 06.09.2015
9 weeks
04.07.2015 -28.08.2015
8 weeks
OR
Hari Malaysia
Hari Raya Aidil Adha Public Holiday
Deepavali Public Holiday
Maal Hijrah Public Holiday
Christmas Public Holiday
New Year Public Holiday
Maulidur Rasul Holiday
Thaipusam
16.09.2014
05.10.2014
23.10.2014
25.10.2014
25.12.2014
01.01.2015
03.01.2015
03.02.2015
Chinese New Year Public Holiday
19 & 20.02.2015
Prohibition Against PLAGIARISM
extract from University of Malaya (Discipline of Students) Rules 1999
(1)
A student shall not plagiarize any idea/writing, data or invention belonging to another person.
(2)
For the purposes of this rule, plagiarism includes:a) the act of taking an idea, writing, data or
invention of another person and claiming that
the idea, writing, data or invention is the result
of one’s own findings or creation; or
(3)
b) an attempt to make out or the act of making out,
in such a way that one is original source or the
creator of an idea, writing, data or invention
which has actually been taken from some other
resources
Without prejudice to the generality of sub-rules (2) a student plagiarizes when he
a) publishes, with himself as the author, an
abstract, article, scientific or academic paper
or book which is wholly or partly written by
some other person;
b) incorporates himself or allows himself to be
incorporated as a co-author of an abstract,
article, scientific or academic paper, or book,
when he has not at all made any written
contribution to the abstract, article, paper, or
book;
c) forces another person to include his name in the
list of co-researchers for a particular research
project or in the list of co-authors for a
publication when he has not made any
contribution which may qualify him as a coresearcher or co-author;
d) extracts academic data which are the results of
research undertaken by some other person, such
as laboratory finding or field work findings or
data obtained through library research, whether
published or unpublished, and incorporate those
data as part of his academic research
Without Giving due acknowledgement
to the actual Source;
e) uses research data obtained through
collaborative work with some other person,
whether or not that other person is a staff
member or a student of the University, as part of
another distinct personal academic, research of
his, or for a publication in his own name as sole
author without obtaining the consent of his
personal research or prior to publishing the data;
f)
transcribes the ideas of creations of others kept
in whatever form whether written, printed or
available in electronic form, or in slide form, or in
whatever form of teaching or research apparatus
or in any other form, and claims whether directly
or indirectly that he is the creator of that idea or
creation;
g) translates the writing or creation of another
person from one language to another whether or
not wholly or partly, and subsequently presents
the translation in whatever form or manner as
his own writing or creation; or
h) extracts ideas from another person’s writing or
creation and makes certain modification due
reference to the original source and rearranges
them in such a way that it appears as if he is the
creator of those ideas.
Engineering LIBRARY
Introduction
The Engineering Library is situated on level 6, Laboratory Wing of the Engineering Tower at the Faculty of
Engineering. It started out as a Reading Room at the Faculty of Engineering. In 1985 this library was absorbed
under the University of Malaya Library System and is known as the Engineering Library. The library provides
services and facilities for lecturers, researchers, students and staffs of the Engineering Faculty, including the
Faculty of Built Environment. This library also open to all students in campus, and registered members of the
UM Library.
General Collection
This library has a general collection of text and reference books, encyclopaedias, dictionaries, manuals, guide
books and technical reports. A large portion of the collection can be borrowed.
Books in this library are
arranged according to subject
matter, based on the Library of
Congress Classification System,
i.e. according to alphabetical
order.
Final Year Project Reports, Dissertations and Thesis
The collection is the result of research undertaken by students of the
Faculty of Engineering. A large portion of the collection is the Final Year
Project Report. The collection is used for reference purposes only.
Standards
This library has a collection of standards including that of, the British Institute (BSI) (until the year 2000),
some Malaysian standards from the Standards Industrial Research Institute of Malaysia (SIRIM), and other
standards such as the American Standards for Testing Material (ASTM). These standards are arranged
according to the index arrangement provided by the issuing bodies for these standards, such as the British
Standards Institute or SIRIM. These standards are for reference purpose only.
Audio Visual Materials
The audio visual material available at the Library include film rolls, film strips, diskettes, compact discs,
audio tapes, videos and slides on topic related to Engineering and Architecture. Facilities to view these
materials are provided by the library.
Loans
All registered students are allowed to borrow from the library.
USER CATEGORIES
Postgraduate Student
Undergraduate Student
NO OF BOOKS
6
4
PERIOD OF LOAN
14 days
7 days
Renewal of reading materials can be done through the internet (Pendeta Web PAC) according to the rules
and regulations.
Inter-Library Loan Service
The facility is available to lecturers, researchers and postgraduates at the Faculty of Engineering. This facility
is to allow them to obtain articles which are not available in the UM Library collection. Service conditions are
according to the rules stated.
Information Services
The Library offers reference and information services. This includes attending to queries and obtaining
information from the database for users of UM Library within and outside the campus.
User Services
Induction programmes are conducted at the Main Library and Engineering Library at the beginning of each
academic session. The main aim of this programme is to introduce the use of the Online Public Access
Catalogue, Pendeta Web PAC, and library facilities to new students. Special information search sessions are
also offered to postgraduate students, lecturers and staffs from time to time. In these sessions, emphasis is
given to the use of Pendeta Web PAC, CD-ROM and online database to search for reference materials in
engineering and related fields.
Electronic Sources (online access via internet)
The UM Library subscribes to a number of online databases, including those related to engineering.
Registered library users may access these databases via the UM Library website http://www.umlib.edu.my,
in the ‘online databases’ section. The user is required to key in the ‘user ID’ before being allowed to access.
Catalogues in the online Engineering Library are a part of the online catalogue of the UM Library and
may be accessed through the UM Library website http://www.pendetaumlib.um.edu.my.
Service Hours
Monday – Thursday
Friday
8.30 am – 5.30 pm
8.30 am – 12.30 noon
2.45 pm – 5.30 pm
The library is closed on Saturday, Sunday and Public Holiday
For enquiries please contact
Mrs. Adida Md Amin
Librarian
Engineering Library
University of Malaya
50603 Kuala Lumpur
T: (603)-7967 4591
F: (603)-7967 5259
E: adida@um.edu.my
BRIEF PROFILE
DEPARTMENT OF
CHEMICAL ENGINEERING
The Department of Chemical Engineering has its roots in the Chemical
Technology course which was established in the Department of Chemistry
in 1965. The first intake of students was in 1967 and the first group of
graduates emerged in 1971. In 1975 the course in Chemical Technology was
renamed Chemical Engineering and was placed under the wings of the
Faculty of Engineering, University of Malaya.
The Department runs an eight semesters (4 years) undergraduate
programme in Chemical Engineering. The curriculum leading to the degree
of Bachelors of Engineering (Chemical) is designed to provide a proper
balance between the fundamental aspects of Chemical Engineering and
applications to the operation, design, analysis of engineering systems.
The degree is recognized and
accredited by Engineering
Accreditation Council (EAC)
under the Board of Engineers,
Malaysia (BEM) and the
Institution of Chemical Engineers
(IChemE, UK). Recently the
Department’s programme has
been accredited as Masters of
Engineering (Chemical) by the
IChemE and all freshmen will be
inducted in this new programme.
The Department also offers
postgraduate programmes by
research leading to the degrees
of Masters of Engineering
Science in Chemical Engineering
and Doctor of Philosophy.
INTRODUCTION OF
OUTCOME-BASED
EDUCATION (OBE)
Outcome-Based Education (OBE) had been
implemented in the Faculty of Engineering
since 2004, in accordance with the directives
of the Ministry of Higher Education and the
Board of Engineers, Malaysia (BEM). This is
also one of the requirements for Malaysia to
become a full member of the Washington
Accord, an international agreement to
mutually recognize Bachelor degrees in
engineering. The implementation of OBE, as
outlined below, is based on guidelines
prescribed by the Engineering Accreditation
Council (EAC) of Malaysia.
Unlike the traditional teacher-centred
method, OBE is an educational approach that
is more concerned about the outcome (what
students can do) rather than the process
(what instructors did). This is believed to
enhance learning, and hence produce better
graduates. For OBE to be successful, it is
critical to prescribe the expected outcomes, to
measure them objectively, and to take
corrective actions where required.
The outcomes are prescribed at two levels:
(a) Course Outcomes (CO) --- what students
should be able to perform at the end of
each course
(b) Programme outcomes (PO) --- a
composite set of abilities after students
finished all courses
All COs will contribute to some of the POs.
This is to ensure that upon completion of the
courses, all POs are sufficiently covered.
Programme Educational
Objectives (Peo)
The PEO is a set of objectives that the academic programme aspires
that the graduates would achieve in their career and professional life a
few years after graduation.
To guide the formation and fine-tuning of these outcomes, the
Department has formulated the Programme Educational Objectives
(PEO). These are aspirations for graduates to attain 3 to 5 years upon
graduation. The POs are designed to produce graduates who are wellprepared to achieve these PEOs.
The PEOs and POs had been formulated in consultation with all major
stakeholders (employers, alumni and students), to meet the demands
of a challenging and globalized workplace. Any material changes will
also require their views.
A critical component of OBE is the objective measurement of the
outcomes. This is done via multiple channels and methods. At the
course level, there is formative assessment via discussion, assignment,
quizzes etc., in addition to the summative assessment in the final
examination. Students also have the opportunity to provide feedback
through course evaluation, meetings with their academic advisors,
annual surveys, and student-lecturer meetings.
Opinions and
feedback from external parties, e.g. employers, alumni, Industrial
Advisory Panel, are also routinely sought to further calibrate the
outcome measurements.
Based on the input and trends received, the Department will take the
necessary corrective actions, and the results monitored. In short, OBE
is a dynamic, student-centred educational process which incorporates
continuous improvement.
PROGRAMME OUTCOMES (PO)
PROGRAMME EDUCATIONAL
OBJECTIVES (PEO)
PEO 1 Become competent engineers in
various local and international
chemical and process industries
and become important
contributors to national
development
PEO 2 Become versatile and adaptable
persons regardless of their
position either as leaders or team
players in their work place in
diverse fields including business,
consultancy, research and
education
PEO 3 Contribute to the environmental
well-being, sustainable
development and the
development of their profession.
PO 1
Apply knowledge of mathematics, science, engineering
fundamentals and Chemical Engineering specialization to
solve complex engineering problems.
PO 2
Identify, formulate, research, analyse and reach
substantiated conclusions along with recommendations for
complex Chemical Engineering problems, using principles of
mathematics, natural science and engineering science.
PO 3
Develop solutions for complex Chemical Engineering
systems, components or processes to meet specified needs
with appropriate consideration for public health and safety,
culture, society and the environment.”
PO 4
Conduct investigations using relevant research
methodology including literature review, design of
experiments, analysis and interpretation of results to derive
scientifically sound conclusions
PO 5
Utilize systematic approach to select/create appropriate IT
tools, with full understanding of their limitations, to model,
simulate and solve complex Chemical Engineering problem.
PO 6
Apply reasoning informed by contextual knowledge to
assess societal, health, safety, legal and cultural issues and
the consequent responsibilities relevant to professional
engineering practice
PO 7
Understand the impact of professional engineering
solutions towards society and the environment, and
demonstrate knowledge of and the need for sustainable
development.
PO 8
Apply norms of professional engineering practice ethically.
PO 9
Communicate effectively on complex engineering activities
with both engineers and the community at large through
discussions, reports and presentations.
PO 10
Function effectively as an individual, and as a team member
or leader in a multi-disciplinary environment.
PO11
Recognise the need to undertake life-long learning and
possess the capacity to do so independently.
PO12
Demonstrate knowledge and understanding of engineering
and management/finance principles and apply these to
one’s own work as an individual, team member or leader in
a multi-disciplinary environment.
14
PROFILE DIRECTORY
ACADEMIC STAFF
DEPARTMENT OF CHEMICAL
ENGINEERING
AcademicStaff
Ir. Dr. Mohamed Azlan Bin Hussain
B.Sc.Tech. (Sheffield, UK), M.Sc. (Tulsa, USA), Ph.D. (Imperial, UK)
P.Eng, MIEM,
HEAD OF DEPARTMENT / PROFESSOR
Specialization Computer Aided Design & Simulation, Process Control &
Automation.
Tel 03-79675214 Email mohd_azlan@um.edu.my
B.Sc. (Aston, UK), M.Sc, Ph.D. (Birmingham, UK)
C.Eng., FIChemE, P.Eng., FIEM, FASc
PROFESSOR
Specialization Separation Processes, Environmental Engineering.
Tel 03-79675296 Email alihashim@um.edu.my
Dr. Nik Meriam Binti Nik Sulaiman
B.Eng, M.App.Sc. (UNSW), Ph.D (Birmingham, UK)
PROFESSOR / DEAN OF SUSTAINABILITY SCIENCE RESEARCH CLUSTER
Specialization Membrane Science and Technology, Sustainability Science,
Resource Efficiency and Cleaner Production, Environmental Management.
Tel 03-79675299 Email meriam@um.edu.my
Dr. Mohamed Kheireddine Taieb Aroua
B.Eng. (ENIG, Tunisia), M.Sc.Eng., Ph.D. (Nancy, France)
PROFESSOR / HEAD OF CENTER FOR SEPARATION SCIENCE AND
TECHNOLOGY (CSST)
Specialization Separation Processes, CO2 Capture, Biodiesel Production,
Electrochemical Processes.
Tel 03-79675313 Email mk_aroua@um.edu.my
Dr. Wan Mohd Ashri bin Wan Daud
B.Eng. (Leeds, UK), M.Sc, Ph.D. (Sheffield, UK)
PROFESSOR
Specialization Catalyst & Reaction Engineering, Polymerisation Process,
Separation Process.
Tel 03-79675297 Email ashri@um.edu.my
Academic Staff
Ir. Dr. Mohd. Ali Bin Hashim
Academic Staff
Ir. Dr. Abdul Aziz Bin Abdul Raman
B.Eng. (Chem), M.Eng.Sc. (Chem), Ph.D. (Chem) (Malaya)
P.Eng., MIEM, C. Eng., FIChemE
PROFESSOR / DEPUTY DEAN (ACADEMIC)
Specialization Three Phase Mixing, Biodiesel Production,
Cleaner Production.
Tel 03-79675300/2312 Email azizraman@um.edu.my
Dr. Che Rosmani Binti Che Hassan
B.Eng. (UTM),M.Eng, Ph.D. (Sheffield)
ASSOCIATE PROFESSOR
Specialization Process Safety Management, Qualitative & Quantitative Risk
Assessment, Construction Waste, Membrane Technology,
Tel 03-79675314 Email rosmani@um.edu.my
Dr. Rozita Yusoff
B.Eng. (Nova Scotia, Canada), M.Sc. (Manchester), Ph.D. (UMIST)
ASSOCIATE PROFESSOR
Specialization Separation: CO2 Capture by Alkonalamine / Ionic Liquid and
Microwave Assisted Extraction, Advanced Materials (Carbon/Epoxy
Composites), Life Cycle Analysis, Process Integration.
Tel 03-79675206/6891 Email ryusoff@um.edu.my
Dr. Ngoh Gek Cheng
B.Eng. (QUB, UK), Ph.D. (QUB, UK)
ASSOCIATE PROFESSOR
Specialization Biochemical Engineering, Biomass Pretreatment, Solid State
Fermentation, Herbal Plant Extraction.
Tel 03-79675301 Email ngoh@um.edu.my
Dr. Adeline Chua Seak May
B.Eng. (UM, Malaya), M.Eng., Ph.D. (Tokyo)
SENIOR LECTURER
Specialization Environmental Biotechnology, Biological Wastewater
Treatment, Microbial Community Structure, Solid State Fermentation.
Tel 03-79675291 Email adeline@um.edu.my
Dr. Anantharaj Ramalingam
B.Tech. (PEC, India), M.E (Annamalai, India), Ph.D. (IIT, Guwahati
SENIOR LECTURER
Specialization Zero Emission, Separation Process with Ionic Liquid,
Molecular Simulation dan Characterization Of Molecules.
Tel 03-79677687 Email anantharaj@um.edu.my
B.Sc., M.Sc., Ph.D. (NMIMT, USA)
SENIOR LECTURER
Specialization Low Density Completion Fluid, Fluid Flow in Porous
Media.
Tel 03-79676896 Email badrules@um.edu.my
Dr. Brahim Si Ali
B.M.Eng. (Chem), Ph.D. (Chem),(Malaya)
SENIOR LECTURER
Specialization Reaction Engineering & Separation.
Tel 03-79676896 Email brahim@um.edu.my
Dr. Ho Pei Yee
B.Eng. (Chem), (UM), M.Eng.Sc. (UM), Ph.D. (Kyushu, Japan)
SENIOR LECTURER
Specialization Process Control, Modeling and Optimization.
Tel 03-79677685 Email peiyee@um.edu.my
Engr. Mohamad Iskandr Bin Mohamed Nor
B.Eng. (Lakehead), M.Sc (Queen’s,Canada), Grad.IEM
SENIOR LECTURER
Specialization Computational Fluid Dynamics, LAN/Internet, PC
Software/Hardware, Web System, Database System.
Tel 03-79676895 Email misk@um.edu.my
Academic Staff
Dr. Badrul Hisham Bin Mohd Jan
Academic Staff
Dr. Monash Purushothaman
B.Tech. (AEC Tiruvannamalai, India), M.Tech. (CIT Coimbatore, India), Ph.D. (IITG,
India)
SENIOR LECTURER
Specialization Membrane Separation dan Absorption, Catalyst
Tel 03-79675292 Email monash@um.edu.my
Dr. Nur Awanis Binti Hashim
B.Eng. (Osaka), M.Sc. (UMIST, UK), PhD. (Imperial, UK)
SENIOR LECTURER
Specialization Polymerisation Process, Membrane Technology,
Separation Process.
Tel 03-796796892 Email awanis@um.edu.my
Engr. Dr. Yeoh Hak Koon
B.Eng.(Chemical) (Hons) (UM), M.Eng.Sc. (UM), Ph.D (Purdue, USA), MAIChE, MAPS,
AMIChemE, Grad.IEM
SENIOR LECTURER
Specialization Electrohydrodynamics, Free Surface Flows, CFD.
Tel 03-79675360 Email yeohakoon@um.edu.my
Dr. Jegalakshimi A/P Jewaratnam
B.Eng. (Chem) (UM), M.Eng.Sc. (UM), Ph.D. (Newcastle)
SENIOR LECTURER
Specialization
Tel 03-79677691 Email jegalaxmi24@um.edu.my
Dr. Mahar Diana Binti Abdul Hamid
B.Eng (Malaya), M.Sc, (Sheffield), Ph.D, (Sheffield)
SENIOR LECTURER
Specialization Combustion and flame technology, Process safety and risk
assessment, Computational Fluid Dynamics
Tel 03-79677690 Email mahar.diana@um.edu.my
Teoh Wen Hui
B. Chem. Eng (UKM), MPhil (Cambridge)
SENIOR LECTURER
Specialization Dense Gas Technologies, Thermodynamic Modelling
Tel 03-79675206 Email whteoh@um.edu.my
M.Eng, Ph.D (IIT, India)
SENIOR RESEARCH FELLOW
Specialization Reaction, Process Systems Engineering & Separation
Process.
Tel 03-79675294 Email jaya_kumar@um.edu.my
Dr. Ahmad Shamiri
B.Eng. (Chem), M.Eng (Azad Uni., Iran), Ph.D (UM)
FELLOW RESEARCH
Specialization Process Modeling And Control, Olefin Polymerization
Process, Fluidization Engineering, CO2 Capture, Petrochemical,oil And Gas
Industries.
Tel 03-79677657 Email a.shamiri@um.edu.my
Academic Staff
Dr. Jayakumar Natesan Subramaniam
Nayagar
PROFILE DIRECTORY
SUPPORTING STAFF
DEPARTMENT OF ELECTRICAL
ENGINEERING
SupportingStaff
Lailah binti Hamzah
ADMINISTRATIVE STAFF
Tel 03-79675206 Email lailah@um.edu.my
Lee Ching Shya
BSc (UM), MSc. (UPM)
Specialization Organic Synthesis, Analytical Chemistry
Tel 03-79677656 Email leecs@um.edu.my
Azira Binti Idris
ASSISTANT SCIENCE OFFICER
Tel 03-79675286 Email azira@um.edu.my
Fazizah Binti Abdullah
ASSISTANT SCIENCE OFFICER
Tel 03-79675310 Email fazizah@um.edu.my
Norhaya Binti Abdul Rahim
ASSISTANT SCIENCE OFFICER
Tel 03-79675290 Email norhaya@um.edu.my
Supporting Staff
RESEARCH OFFICER
Supporting Staff
Jalaluddin Bin Zainuddin
ASSISTANT ENGINEER
Tel 03-79675327 Email jalaluddin@um.edu.my
Ishak Bin Mohammad
ASSISTANT ENGINEER
Tel 03-79675309 Email ishakmohd@um.edu.my
Kamarudin Bin Hassan
ASSISTANT ENGINEER
Tel 03-79675327 Email kdin@um.edu.my
Osman bin Sadikin
ASSISTANT ENGINEER
Tel 03-79675215 Email meto@um.edu.my
Rustam Bin Ramlan
ASSISTANT ENGINEER
Tel 03-79675308 Email ras64@um.edu.my
Azaruddin Bin Ibrahim
ASSISTANT ENGINEER
Tel 03-79675327 Email azrdin@um.edu.my
ASSISTANT ENGINEER
Tel 03-79675277 Email rizman2009@um.edu.my
Sazali Bin Mohd Sapie
ASSISTANT ENGINEER
Tel 03-79675327 Email sazly@um.edu.my
Ismail Hakim Nasirin
ASSISTANT ENGINEER
Tel: 03-79675309 Email ismile@um.edu.my
Muhammad Kamarul Ariffin bin Mohd
Shariffuddin
ASSISTANT ENGINEER
Tel 03-79675277 Email kamalrul@um.edu.my
Supporting Staff
Rizman Bin A.Lateff
Supporting Staff
Exram bin Masroh
COMPUTER TECHNICIAN
Tel: 03-79675347 Email exram@um.edu.my
CURRICULUM STRUCTURE
SESSION 2014/2015
DEGREE IN BACHELOR OF ENGINEERING (CHEMICAL)
COURSES
CONTENT
UNIVERSITY
COURSES
(15%)
Information Skills
Islamic and Asian Civilizations (TITAS)*
Ethnic Relations* / Introduction to Malaysia**
Basic of Entrepreneurship Culture
Thinking and Communication Skills
English Communication Programme
Social Engagement
Co-Curriculum
Elective Course (outside faculty)
FACULTY
COURSES
(85%)
CREDIT HOURS
1
2
2
2
3
6
2
2
2* / 4**
Sub-Total Credit Hours
24
Faculty Core Courses
Department Compulsory Courses
Department Elective Courses
17
97
8
Sub-Total Credit Hours
122
Total Credit Hours
146
Note:
* For Malaysian Students
** For International Students
ACADEMIC PLANNER FOR BACHELOR OF ENGINEERING (CHEMICAL) PROGRAMME 2014/2015 SESSION
Code
Courses
UNIVERSITY COURSES
GXEX1401
Information Skills
GXEX1412
Basics of Entrepreneurship Culture
GXEX1411*
Ethnic Relation
GXEX1413*
Introduction to Malaysia
GXEX1414
TITAS
GXEX1417
Social Engagement
#
Fundamentals of English
GTEE1101
#
English for Academic Purposes
GTEE1102
#
Professional Writing in English
GTEE1103
#
Effective Presentation Skills
GTEE1104
KXEX2163
Thinking and Communication Skills
KXEX2165
Moral and Ethics in Engineering Profession
Elective Courses (Outside Faculty)
Co-Curriculum
Sub-Total Credit Hours
FACULTY COURSES
KXEX1144
Fundamentals of Engineering Calculus
KXEX1145
Fundamentals of Engineering Algebra
KKEK2110
Basic Material Science for Chemical Engineering
KXEX2166
Law and Engineer
KXEX2244
Ordinary Differential Equations
KXEX2245
Vector Analysis
KXEX3244
Partial Differential Equations
Sub-Total Credit Hours
DEPARTMENT COURSES
KKEK1111
Chemical Engineering Thermodynamics l
KKEK1123
Chemical Process Principles l
KKEK1135
Physical and Analytical Chemistry I
KKEK1136
Organic Chemistry
KKEK1141
Statistics for Engineers
KKEK1142
Numerical Methods for Engineers l
KKEK1153
Fluid Mechanics
KKEK1174
Physical Chemistry Laboratory
KKEK1222
Chemical Process Principles ll
KKEK2111
Chemical Engineering Thermodynamics ll
KKEK2142
Numerical Methods for Engineers ll
KKEK2154
Heat Transfer
KKEK2157
Mass Transfer
KKEK2158
Separation Processes l
KKEK2171
Laboratory and Communication l
KKEK3161
Process Safety
KKEK2220
Reaction Engineering l
KKEK2233
Physical and Analytical Chemistry ll
KKEK3151
Biochemistry
KKEK3152
Modelling of Chemical Processes
KKEK3153
Simulation of Chemical Processes
KKEK3154
Process Control
KKEK3155
Particle Technology
KKEK2156
Momentum Transfer
KKEK3156
Plant Engineering
KKEK3157
Process Synthesis
KKEK3159
Separation Processes ll
KKEK3171
Laboratory and Communication ll
KKEK3192
Industrial Training
KKEK3221
Reaction Engineering ll
KKEK3282
Design Exercise
KKEK4163
Environmental Management
1st yr
S1 S2
SS
1
2nd yr
S3 S4
SS
2
3rd yr
S5 S6
SS
3
4rd yr
S7 S8
SS
4
1
2
2
2
2
2
2
3
3
6
3
11
0
2
2
3
3
2
3
1
0
2
2
7
2
0
2
2
7
0
2
0
0
2
0
0
0
0
0
0
2
3
3
3
2
2
0
2
2
3
2
2
2
2
15
2
2
2
2
0
3
2
2
2
22
2
3
2
4
PRE-REQUISITES
1
2
2
0
Total
credit
2
2
3
2
3
3
2
2
3
2
2
3
3
3
2
3
5
3
3
2
3
3
2
2
2
3
2
1
2
3
2
3
2
3
2
3
3
2
3
2
2
3
3
3
3
2
3
2
5
2
3
3
KXEX1144
KXEX1144, KKEX1145
KXEX2244
KKEK1123
KKEK1111
KXEX3244, KKEK1142
KKEK1153, KXEX2245, KXEX3244
KKEK1222
KKEK1141
KKEK1222
KKEK2111
KKEK2111
KKEK3152
KKEK1141
KKEK1153, KXEX2245, KXEX3244
KKEK2154, KKEK2220, KKEK2158
KKEK1222
KKEK2171
KKEK2220, KKEK2157
KKEK2154, KKEK2220, KKEK2158
GRADUATION REQUIREMENT CHART
BACHELOR OF ENGINEERING (CHEMICAL) PROGRAMME
INTAKE SESSION 2014/2015
CODE
COURSE
UNIVERSITY COURSES
GXEX1401
Information skills
GXEX1414
Islamic and Asian Civilizations
GXEX1411/
Ethnic Relations/
GXEX1413
Introduction to Malaysia
GXEX1417
Social Engagement
GTEE11xx
English Communication Programme I
GTEE11xx
English Communication Programme II
Co-curriculum
KXEX2163
Thinking and Communication Skills
GXEX1412
Basic of Entrepreneurship Culture
Elective Courses (Other Faculty)
Sub-total Credit Hours
FACULTY COURSES
Foundation of Materials Science for
KKEK2110
Chemical Engineering
KXEX1144
Basic Engineering Calculus
KXEX1145
Basic Engineering Algebra
KXEX2244
Ordinary Differential Equations
KXEX3244
Partial Differential Equations
KXEX2245
Vector Analysis
KXEX2166
Law and Engineer
KXEX2165
Moral and Ethics in Engineering Profession
Sub-total Credit Hours
CREDIT
PASSING
GRADE
1
2
S
C
2
2
3
3
2
3
2
2
22
C
C
C
C
S
C
C
C
3
C
2
2
2
2
2
2
2
17
C
C
C
C
C
C
C
MARKING SCHEME
Marks
Grade
80 – 100
75 – 79
70 – 74
65 – 69
60 – 64
55 – 59
50 – 54
45 – 49
40 – 44
35 – 39
< 35
A
AB+
B
BC+
C
CD+
D
F
Grade
U
S
Grade
Points
4.0
3.7
3.3
3.0
2.7
2.3
2.0
1.7
1.5
1.0
0.0
Remarks
Unsatisfactory / Fail
Satisfactory / Pass
GRADUATION REQUIREMENT CHART
BACHELOR OF ENGINEERING (CHEMICAL) PROGRAMME
INTAKE SESSION 2014/2015
CODE
COURSE
DEPARTMENTAL COURSES
KKEK1111
Chemical Engineering Thermodynamics l
KKEK1123
Chemical Process Principles l
KKEK1135
Physical and Analytical Chemistry I
KKEK1136
Organic Chemistry
KKEK1141
Statistics for Engineers
KKEK1142
Numerical Methods for Engineers l
KKEK1153
Fluid Mechanics
KKEK1174
Physical Chemistry Laboratory
KKEK1222
Chemical Process Principles ll
KKEK2110
Chemical Engineering Thermodynamics ll
KKEK2142
Numerical Methods for Engineers ll
KKEK2154
Heat Transfer
KKEK2156
Momentum Transfer
KKEK2157
Mass Transfer
KKEK2158
Separation Processes l
KKEK2171
Laboratory and Communication l
KKEK2220
Reaction Engineering l
KKEK2233
Physical and Analytical Chemistry ll
KKEK3151
Biochemistry
KKEK3152
Modeling of Chemical Processes
KKEK3153
Simulation of Chemical Processes
KKEK3154
Process Control
KKEK3155
Particle Technology
KKEK3156
Plant Engineering
KKEK3157
Process Synthesis
KKEK3159
Separation Processes ll
KKEK3161
Process Safety
KKEK3171
Laboratory and Communication ll
KKEK3192
Industrial Training
KKEK3221
Reaction Engineering ll
KKEK3282
Design Exercise
KKEK4163
Environmental Management
KKEK4165
Project Management
KKEK4167
Process Engineering Economics
KKEK4281
Design Project
KKEK4283
Research Project
KKEK43XX
Technical Elective l
KKEK43XX
Technical Elective ll
KKEK43XX
Technical Elective lll
KKEK43XX
Technical Elective lV
Sub-total Credits
TOTAL CREDITS
CREDIT
3
3
2
2
2
3
2
1
2
3
2
3
3
2
3
2
3
2
3
2
2
3
3
3
2
3
3
2
5
2
3
3
2
3
6
4
2
2
2
2
105
PASSING
GRADE
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
S
C
C
C
C
C
C
C
C
C
C
C
142
MARKING SCHEME
Marks
Grade
80 – 100
75 – 79
70 – 74
65 – 69
60 – 64
55 – 59
50 – 54
45 – 49
40 – 44
35 – 39
< 35
A
AB+
B
BC+
C
CD+
D
F
Grade
U
S
Grade
Points
4.0
3.7
3.3
3.0
2.7
2.3
2.0
1.7
1.5
1.0
0.0
Remarks
Unsatisfactory / Fail
Satisfactory / Pass
FACULTY OF ENGINEERING
COURSE PRO-FORMA
UNIVERSITY COURSES
Course Pro-forma
University Course
Code
GTEE1107
Title
Communication in English III
Pre-requisite
Student Learning Time (SLT)
MUET Band 2
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
This course is designed for students with an elementary
proficiency in English. It provides basic communication skills to
students with an emphasis on vocabulary building and accuracy
in grammar at the post-elementary level. The course enables
students to speak and write moderately well.
70 % Continuous Assessments
30 % Final Examination
1.
2.
3.
4.
5.
Soft Skills
Speak accurately and fluently at post- elementary level
Apply grammar correctly at post-elementary level
Write a coherent and cohesive paragraph
Use words at 750 headword level
Johannsen, K. L., & Chase, R.C. (2010). World English 2, USA:
Heinle, Cengage Learning.
Hornby, A.S.(ed) (2005). Oxford Advanced Learners’
Dictionary of Current English. Oxford, UK: Oxford University
Press.
Elbaum, S.N. (2010).Grammar in Context. 5th Edition. USA:
Heinle, Cengage Learning.
www.vocabulary.com
www.dictionary.cambridge.org
Communication Skills (CS1, CS2, CS3)
Teamwork Skills (TS1)
Course Pro-forma
University Course
Code
GTEE1109
Title
Speaking Skills in English
Pre-requisite
Student Learning Time (SLT)
MUET Band 3
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
Synopsis
Assessment
References
This course focuses on various speaking skills in English. It
develops students communication skills and strategies that
enable them to interact appropriately on topics of current
interest. Students will learn to speak fluently in a variety of
informal situations.
100 % Continuous Assessments
1.
2.
3.
4.
5.
Soft Skills
Express ideas clearly using appropriate communication
strategies
Converse effectively using appropriate communication
strategies
Discuss topics of current interest in informal settings
Liu, J., Davis,T., Rizzo S.(2008). Communication Strategies 3.
Singapore:Cengage Learning.
Hornby, A.S.(ed) (2005). Oxford Advanced Learners’
Dictionary of Current English. Oxford, UK: Oxford University
Press.
Web English.
www.brody.iif.hu/webenglish/Pages/mg_speaking.html
Windle, R. , Warren,S. Communication
Skills.www.directionservice.org/cadre/section4.cfm
www.dictionary.cambridge.org
Communication Skills (CS1, CS2, CS3)
Teamwork Skills (TS1)
Course Pro-forma
University Course
Code
GTEE1110
Title
Writing Skills in English
Pre-requisite
Student Learning Time (SLT)
MUET Band 3
122 hours
Credit
3
Learning Outcomes
1.
2.
3.
Synopsis
Assessment
References
This course introduces the process of paragraph development
and the generation of ideas in order to write within a variety of
rhetorical patterns. It does this by focusing on the elements of
good sentences within the context of a paragraph, the active use
of a wide range of vocabulary as well as the elements of a good
paragraph. The course helps students to understand the
relationship between paragraphs in an essay, to edit their work
and to produce different types of essays.
100 % Continuous Assessments
1.
2.
3.
4.
5.
Soft Skills
Express ideas clearly, appropriately and effectively through
the written mode
Develop different types of paragraphs coherently and
cohesively
Write different types of essays.
Folse, K S, Solomon E V, Clabeaux D. (2010). Great Writing
3,2nd Edition, USA: Heinle Cengage Learning.
Sinclair, J (Ed), (2009).Collins COBUILD Advanced Dictionary.
USA: Heinle Cengage Learning.
Elbaum, S.N. (2010).Grammar in Context. 5th Edition. USA:
Heinle, Cengage Learning.
www.vocabulary.com
www.dictionary.cambridge.org
Communication Skills (CS1, CS2, CS3)
Teamwork Skills (TS1)
Course Pro-forma
University Course
Code
GTEE1111
Title
Presentation Skills at the Work Place
Pre-requisite
Student Learning Time (SLT)
MUET Band 4
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
The course encompasses different aspects of communication
used in delivering effective impromptu speeches, oral
presentations and conducting interviews for presentations.
Appropriate examples from a variety of situations are used as
practice materials for students to analyse, discuss and apply the
communication strategies taught.
100 % Continuous Assessments
1.
2.
3.
4.
5.
Soft Skills
Employ appropriate interviewing techniques when collecting
information
Write speech outlines for presentations
Apply appropriate presentation skills and strategies when
delivering impromptu speeches to a selected audience
Apply appropriate presentation skills and strategies when
delivering prepared speeches to a selected audience
Dale, P. & Wolf, J.C. (2006). Speech Communication Made
Simple (3rd Edition). White Plains, NY: Pearson Education.
Comfort, J. (1995). Effective Presentations. Great Clarendon
Street, Oxford: Oxford University Press.
Jaffe, C.(2010). Public Speaking: Concepts and Skills for a
Diverse Society. Boston,MA: Wadsworth Cengage Learning.
Lucas, S. (2008).The Art of Public Speaking with Connect
Lucas.New York,NY: McGraw-Hill.
Articles and videos on Oral Presentations.
http://www.ehow.com/about_6324248_definition-_oralpresentation_.html
Communication Skills (CS1, CS2, CS3, CS4)
Critical Thinking and Problem Solving Skills (CT1, CT2)
Long Life Learning and Information Management (LL1)
Course Pro-forma
University Course
Code
GTEE1112
Title
Introduction to Critical Reading in English
Pre-requisite
Student Learning Time (SLT)
MUET Band 4
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
Synopsis
Assessment
References
This course aims at developing the critical reading fluency of
students towards meeting their academic needs. Students will
engage with reading selections which are complemented with
exercises and activities. Some of the skills that will be taught
include interrogating texts to understand the stance of the
author, the relationships between ideas in the texts, and the
supporting evidence.
100 % Continuous Assessments
1.
2.
3.
4.
5.
Soft Skills
Identify an authors purpose, assertions and assumptions
Comprehend ideas based on evidence
Analyze ideas from multiple sources and perspectives
Benz, Cheryl & Cynthia M. Shuemann (2006). College
Reading 4: English for Academic Success. Boston: Heinle.
The Cambridge Dictionary of English (1995). Cambridge
University Press
Fleming, L. (2012). Reading for Thinking. 7th ed. Australia:
Wadsworth
Mather, P. & McCarthy, R. (2009).The Art of Critical Reading.
2nd ed.Boston, MA: McGraw-Hill.
Metcalf, M. (2006). Reading Critically at University. London:
Sage Publications.
Communication Skills (CS1, CS2, CS3, CS4)
Critical Thinking and Problem Solving Skills (CT1, CT2)
Team Work Skills (TS1)
Long Life Learning and Information Management (LL1)
Course Pro-forma
University Course
Code
GTEE1113
Title
Technical Writing
Pre-requisite
Student Learning Time (SLT)
MUET Band 4
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
This course will introduce students to the importance of good
technical writing skills. Using materials related to their field,
students will be taught in stages to write a variety of technical
documents. Technical writing mechanisms will also be taught.
100 % Continuous Assessments
1.
2.
3.
4.
5.
Soft Skills
Determine audiences and purposes for written documents
Formulate appropriate messages for brief correspondence
Write informative reports
Produce a problem-solution report
Smith-Worthington, D. & Jefferson, S. (2011). 3rd Edition
Technical Writing for Success. USA: South Western Cengage
Learning.
Sargunan, R.A. et al. (2010) Report Writing for Business and
Professional Purposes: An Introduction. 2nd Edition.
Hornby, A.S.(ed) (2005). Oxford Advanced Learners
Dictionary of Current English. Oxford, UK: Oxford University
Press.
www.dictionary.cambridge.org
www.apastyle.org/
Communication Skills (CS1, CS2, CS3, CS4)
Critical Thinking and Problem Solving Skills (CT1, CT2)
Team Work Skills (TS1, TS2)
Long Life Learning and Information Management (LL1)
Course Pro-forma
University Course
Code
GTEE1205
Title
Communication in English II
Pre-requisite
Student Learning Time (SLT)
Passed GTEE 1105
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
Synopsis
Assessment
References
This course is designed for students with pre-elementary
proficiency in English. It aims to provide basic communication
skills to students, with an emphasis on vocabulary building and
accuracy in grammar as well as producing correct sentences at
the elementary level.
70 % Continuous Assessments
30 % Final Examination
1.
2.
3.
4.
5.
Soft Skills
Speak accurately and grammatically at the elementary level
Construct grammatical sentences appropriate to an idea
Use words at 500-headword level
Milner, M. (2010). World English 1, USA: Heinle,Cengage
Learning.
Hornby, A.S.(ed) (2005). Oxford Advanced Learners’
Dictionary of Current English. Oxford, UK: Oxford University
Press.
Elbaum, S.N. (2010).Grammar in Context. 5th Edition. USA:
Heinle,Cengage Learning.
www.vocabulary.com
www.dictionary.cambridge.org
Communication Skills (CS1, CS2)
Team Work Skills (TS1)
Course Pro-forma
University Course
Code
GTEE1207
Title
GTEE1207
Pre-requisite
Student Learning Time (SLT)
Passed GTEE1107
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
This course is designed for students with a post-elementary
proficiency in English. It provides basic communication skills to
students with an emphasis on vocabulary building and accuracy
in grammar at the pre-intermediate level. The course enables
students to speak and to write different types of paragraphs
fairly well.
70 % Continuous Assessments
30 % Final Examination
1.
2.
3.
4.
5.
Soft Skills
Speak accurately, fluently and appropriately at preintermediate level
Apply grammar correctly at pre- intermediate level
Write different types of coherent and cohesive paragraphs
Use words at 1200 headword level
Chase, R. T., & Johannsen, K.L. (2010).World English 3. USA:
Heinle, Cengage Learning.
Hornby, A.S.(ed) (2005). Oxford Advanced Learners’
Dictionary of Current English. Oxford, UK: Oxford University
Press.
Elbaum, S.N. (2010).Grammar in Context. 5th Edition. USA:
Heinle, Cengage Learning.
www.vocabulary.com
www.dictionary.cambridge.org
Communication Skills (CS1, CS2, CS3)
Team Work Skills (TS1)
Course Pro-forma
University Course
Code
GXEX1401
Title
Information Skills Course
Pre-requisite
Student Learning Time (SLT)
None
40 hours
Credit
1
Learning Outcomes
1.
2.
3.
Synopsis
Assessment
References
This course focus on the use of basic references sources in print
and electronic format, effective information search strategy,
information evaluation and preparing reference list.
50 % Continuous Assessments
50 % Final Examination
1.
2.
3.
4.
Soft Skills
State the various information and reference sources
Identify information from various sources such as OPAC
(Online Public Access Catalogue), Online Databases and
Internet
Prepare list of references based on the APA (American
Psychological Association) / Vancouver / CSLW (Citation Style
for Legal Works) citation style
Gash, S. (1998). Effective literature searching for studies.
Aldershot: Gowers.
Gates. J. K. (1994). Guide to the use of libraries and
information sources (7th ed.).New York: McGraw Hills
Irma Indayu Omar, & Yushiana Mansor. (2005). Panduan
mencari maklumat. Pahang: PTS Professional.
E-Learning website (http://adec.um.edu.my/main)
Life Long Learning and Information Management (LL1, LL2, LL3)
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
University Course
Code
GXEX1411
Title
Hubungan Etnik
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
Soft Skills
Menerangkan konsep asas dan teori hubungan etnik.
Mengaplikasi ilmu, konsep dan prinsip interaksi sosial dan
integrasi nasional.
Memaparkan kelakuan yang beretika dan sikap
bertanggungjawab terhadap masyarakat.
Menunjuk cara kemahiran interpersonal yang berkesan dan
bekerja secara berkumpulan.
Kursus ini akan memperkenalkan konsep asas dan teori
hubungan etnik. Pelajar juga akan didedahkan dengan sejarah
pluraliti masyarakat Alam Melayu dan masyarakat Malaysia
kontemporari. Selain itu, topik-topik tentang perlembagaan,
perkembangan ekonomi, politik dan Islam Hadhari dalam konteks
hubungan etnik juga akan diperjelaskan. Sehubungan itu
perbincangan tentang cabaran terhadap hubungan etnik di
Malaysia dan global juga perlu bagi membentuk masyarakat
berintegrasi.
40 % Continuous Assessments
60 % Final Examination
Modul Hubungan Etnik, Shamsul Amri Baharuddin (Ed.). Kuala
Lumpur: UPENA, 2007. (Modul yang ditetapkan oleh KPT)
Communication Skills (CS1, CS2, CS3)
Team Work Skills (TS1)
Life Long Learning and Information Management (LL1, LL2)
Professional Ethics and Moral (EM1)
Course Pro-forma
University Course
Code
GXEX1412
Title
Basic Entrepreneurship Culture
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
Synopsis
Assessment
References
This course will attempt to inculcate the basic elements of
entrepreneurship in the students. Initiatives are taken to open
their minds and motivate the entrepreneurial spirit in this
potential target group. The course encompasses concepts and
development of entrepreneurship, analysis of entrepreneurship
competency, ethics of entrepreneurship, creativity and
innovation in entrepreneurship, business opportunity, ability to
start a business, developing business plans, skills to run and
manage a business. The course also incorporates a practical
application of skills acquired through joint or individual setting up
and running of business stalls to inculcate interest in the
entrepreneurial spirit, provide meaningfull experience and
expose students to a semblance of the business world.
70 % Continuous Assessments
30 % Final Examination
1.
2.
3.
4.
5.
Soft Skills
Explain the concepts of entrepreneurship and its
importance.
Explain the meaning of entrepreneurial ethics.
Evaluate entrepreneurial spirit in themselves.
Apply creativity and innovation in entrepreneurship.
Develop a concrete business plan.
Ab. Aziz Yusof, Prinsip Keusahawanan, 2003, Malaysia :
Pearson Malaysia Sdn. Bhd.
Hisrich, R.D., Peters, M.P. & Shepherd, D.A, 2005,
Entrepreneurship, 6th. Edition, Singapore : McGraw Hill.
Kuratko, D.F. & Hodgetts, R.M. 2007, Entrepreneurships
theory, process, practice, 7th. Edition, Canada : Thomson
South-Western.
Lambing, P.A. & Kuehl, C.R. 2007, Entrepreneurship, 4th.
Edition, New Jersey : Pearson Education, Inc.
Rosli Mahmood & rakan-rakan, Prinsip-prinsip Asas
Keusahawanan, 2007, Malaysia : Thomson.
Communication Skills (CS1, CS2, CS3)
Team Work Skills (TS1)
Life Long Learning and Information Management (LL1, LL2)
Entrepreneneurial Skills (KK1, KK2)
Course Pro-forma
University Course
Code
GXEX1413
Title
Introduction to Malaysia
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
Synopsis
Assessment
References
This course will explain the history and formation of Malaysia. It
will also discuss the national administrative structure and system
of Malaysia, the Malaysian Constitution, culture, values, ethnic
orientation, national integration, unity and guidelines on social
interactions with Malaysians.
50 % Continuous Assessments
50 % Final Examination
1.
2.
3.
Soft Skills
Explain history, administrative structure and Constitution of
Malaysia.
Explain places, races, way of life, values and culture of
Malaysians
Demonstrate effective interpersonal skills and teamwork.
Multicultural Malaysia: Delights, puzzles & irritations, Kuala
Lumpur: Prentice Hall Pearson Malaysia Sdn. Bhd.
Cheah Boon Kheng. (2002), Malaysia: The Making of a
Nation, Singapore: Institute of Southeast Asian Studies.
Kahn, J. And Loh Kok Wah (eds). (1993), Fragmented Vision:
Culture and Politics in Contemporary Malaysia, Sydney: Allen
and Unwin.
Communication Skills (CS1, CS2, CS3)
Team Work Skills (TS1)
Course Pro-forma
University Course
Code
KXEX2167
Title
Thinking and Communication Skills
Pre-requisite
Student Learning Time (SLT)
Credit
Learning Outcomes
None
120 hours
3
1.
2.
3.
4.
Synopsis
Assessment
References
Introducing to students the objective, procedure, evaluation, and
explanation regarding critical thinking and communication skills.
Critical thinking skills include explaining and analyzing ideas;
analyzing and evaluating arguments; determining source
credibility; recognizing persuasive language; and recognizing
fallacy. Communication skills cover oral communication; listening
skills; non-verbal communication; interpersonal communication;
group interaction skills; and problem solving and decision
making. Students will also be brief on barriers in critical thinking
and communication. Interactive sessions will impose the students
to apply or practice critical thinking and communication skills to
engineering discipline effectively.
100 % Continuous Assessments
1.
2.
3.
4.
5.
Soft Skills
Recognise the basics of critical thinking skills and logic
Identify the methods of effective oral and written
communication skills
Debate or criticize arguments related to engineering
discipline successfully
Apply critical thinking and communication skills in
engineering practice
G. Bassham, W. I. Irwin, H. Nardone and J.M. Wallace,
Critical Thinking: A Student Introduction, Mc. Graw Hill.
Fishe. Critical Thinking: An Introduction. Cambridge
University Press.
S. Taylor, Essential Communication Skills, Pearson Longman.
T.K. Gamble & M. Gamble, Communication Works. Mc. Graw
Hill.
J. W. Davies, Communication For Engineering Students.
Longman
Communication Skills (CS1,CS2,CS3, CS4, CS7, CS8)
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Team Work Skills (TS1, TS2)
Continuous learning and Information Management (LL1, LL2)
Ethics and Professional Moral (EM1)
Leadership Skills (LS1)
Course Pro-forma
University Course
Code
GXEX 1417
Title
Social Engagement
Pre-requisite
Student Learning Time (SLT)
Credit
Learning Outcomes
None
80 hours
2
1.
2.
3.
Synopsis
Assessment
References
This course exposes the students on social engagement and their
role as volunteers. Students need to plan their social engagement
programme and will be placed at a specific location based on their
programme. Students have to write a report and make a
presentation on their experience with the society.
100 % Continuous Assessments
1.
2.
3.
Soft Skills
Demonstrate the awareness of the importance of
social engagement
Develop the ability to work in a team and with the
society
Show communication skill
Compton & Galaway, 1979. Social Work Process,, New
York: The Dorsey Press.
Reid K.E 1991. Social Work Practoce With Groups, Clinical
Perspective California: Brooks/Cole Pub.Co
Hepworth D.H & H Larsen J.A 1993. Direct Social Work
Practice, Theory and Skills. California : Brooks/Cole Pub.Co
Communication Skills (CS1 – CS3)
Team Work Skills (TS1 - TS2)
Leadership Skills (LS1)
FACULTY OF ENGINEERING
COURSE PRO-FORMA
FACULTY COURSES
Course Pro-forma
Faculty Course
Code
KXEX1110
Title
Fundamentals of Material Science
Pre-requisite
Student Learning Time (SLT)
None
122 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
Soft Skills
Explain the theory of basic atomic structure and the
imperfection.
Describe the phase diagram, materials characteristic and
mechanical testing
Discuss the characteristic, processing and application of
polymer, ceramic and composite
Give example of some electrical and magnetic properties of
materials
Introduction to Materials science and engineering, atomic
structure and atomic bonding. Crystal structure and
imperfection. Steel characteristic and processing, phase diagram
and engineering alloy. Characteristic. Processing and application
of polymer, ceramic and composite
40 % Continuous Assessments
60 % Final Examination
Foundation of Materials Science and Engineering, William F.
Smith, Javad Hashemi, McGraw Hill. 2005
Communication Skills (CS1, CS2)
Critical Thinking and Problem Solving Skills (CT1)
Teamwork Skills (TS1, TS2)
Life Long Learning and Information Management (LL1, LL2)
Course Pro-forma
Faculty Course
Code
KXEX1144
Title
Basic Engineering Calculus
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
Synopsis
Assessment
References
Functions. Trigonometric and hyperbolic functions, exponential
functions, logarithmic functions. Concept domain and range of
function, graphs of function, Inverse functions, combining
functions, composite functions, rational functions and partial
functions.
Limit continuity and differentiation. Concept of limit. Continuity
and types of discontinuity. Derivative of trigonometric and
hyperbolic functions. Increasing and decreasing functions.
Implicit differentiation and the chain rule. Higher
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
Soft Skills
Describe elementary special functions (e.g. exponential, log,
and trigonometric functions) which arise in engineering.
Practice the skills obtained from differential and integral
calculus to deal with models in engineering
Use the basic calculus concepts and apply knowledge gained
in subsequent engineering courses or others
Modern Engineering Mathematics, (4th edition), Glyn James
(Edison-Wesley), 2007
Engineering Mathematics, (5th edition), K. A. Stroud and D.J.
Booth (Palgrave), 2007
Further Engineering Mathematics, (3rd edition), K. A. Stroud
(MacMillan) 1992
Communication Skills (CS1, CS2, CS3)
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Teamwork Skills (TS1, TS2)
Life Long Learning and Information Management (LL1, LL2)
Course Pro-forma
Faculty Course
Code
KXEX1145
Title
Basic Engineering Algebra
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
Synopsis
Use DeMoivre Theorem and Euler Formula to determine the power
and roots of complex numbers.
Explain the concepts of matrices, determinants, ranks,eigenvalues
and eigenvectors.
Solve systems of linear equations and diagonalize square matrices.
Use the dot product, cross product and triple products of vectors to
determine the parametric equations and vector equations of lines
and planes.
Complex numbers: Addition, substraction, multiplication and division.
Complex numbers in polar form. Complex numbers in exponent form.
DeMoivre Theorem. Power and roots of complex number. Euler
Formula.
Matrices: Diagonal, symmetric, skew symmetric, orthogonal, Hermitian,
skew Hermitian and unit matrix. Transpose. Determinant. Minor,
cofactor and adjoint. Singular and non-singular matrices. Inverse of
matrix. Linearly dependent and linearly independent vectors. Rank of a
matrix. Homogenous and non-homogenous system of linear equations.
Existence of solutions and their properties. Gaussian Elimination
method. Cramers Rule. Eigenvalues and eigenvectors. Diagonalization.
Cayley-Hamilton Theorem.
Vector Algebra: Cartesian Vector in two and three dimension systems.
Dot and cross product. Parametric Equations and Vector Equations of
lines. Skew Lines. Equations of planes. Distance between a point and a
plane. Distance between two planes. Angle between two intersecting
lines an
Assessment
References
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
Soft Skills
Modern Engineering Mathematics, (4th edition), Glyn James
(Edison-Wesley), 2007
Theory and Problems of Vector Analysis, (2nd edition), Murray R.
Spiegel (Schaum's series) 2008
Engineering Mathematics, (5th edition), K. A. Stroud and D.J. Booth
(Palgrave), 2007
Further Engineering Mathematics, (3rd edition), K. A. Stroud
(MacMillan)) 1992
Communication Skills (CS1, CS2, CS3)
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Teamwork Skills (TS1, TS2)
Life Long Learning and Information Management (LL1, LL2)
Course Pro-forma
Faculty Course
Code
KXEX2162
Title
Economics, Finance and Engineers
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
This course introduces the economic principles and analytical
tools needed to think intelligently about economic problems. The
course begins by focusing on microeconomics, in which students
will examine the concept and principles of individual consumer
and firm behaviour. In the second part of the course deals with
the thought processes, concepts, methods, and knowledge bases
used by engineers to cost engineering projects and to evaluate
the merit of making a particular investment, and to chose
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
Soft Skills
recognize key ideas in economic analysis that address the
economic problem of how to allocate scarce resources
among unlimited wants.
to conceptualize the principles of demand and supply as well
as the analysis of competitive markets
to satisfy the very practical needs of the engineer toward
making informed financial decisions when acting as a team
member or project manager for an engineering projects.
apply the concept of Time Value of Money and discounted
cash flow in investment decision making and financial
management
McEachern, Economics- A Contemporary Introduction,
Seventh Edition, Thomson Learning
Pindyck Rubinfield, Micro Economics, Sixth Edition, Prentice
Hall, New Jersey
Blank Tarquin, Engineering Economy, Sixth Edition, McGrawHill.2005
Communication Skills (CS1, CS2, CS3)
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Teamwork Skills (TS1, TS2)
Life Long Learning and Information Management (LL1, LL2)
Course Pro-forma
Faculty Course
Code
KXEX2165
Title
Moral and Ethics in Engineering Profession
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
Soft Skills
Learn the implications of moral and ethics in engineering
works
Understand the basis of moral & ethics behind the
promulgation of codes of ethics(COE) which are adopted by
professional engineering bodies
Recognise the practical needs of COE to regulate engineering
practices
Understand COE of various organisation such as Institution
of Engineers , Malaysia(IEM) and National Society of
Professional Engineers(NSPE,USA) and the importance of
Registration of Engineers Act
Realise the implication of moral & ethics for engineers
behaviour through presentation of case studies
Assess between good and bad course of actions when facing
with corporate decision which need to be made in their
organisation
Introduction to engineering profession and implication of
engineering career. Moral, religious and ethical theories &current
Codes of Ethics. Responsibilities and right of Engineers and
implication of public welfare and loyalty to employer.
Environmental ethics, risks, liability and law. Roles of Engineers
on sustainable development and globalisation
100 % Continuous Assessments
Fleddermann,C.B. Engineering Ethics, 1999, Prentice Hall,N.J
Communication Skills (CS1, CS2, CS3, CS4)
Teamwork Skills (TS1, TS2)
Professional Ethics and Moral (EM1, EM2, EM3)
Leadership Skills (LS1, LS2)
Course Pro-forma
Faculty Course
Code
KXEX2166
Title
Law and Engineer
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
Soft Skills
Identify the effect of the law on the society with emphasis
on engineers.
Apply principles of law to a given situation and identify the
liability from a legal perspective.
Identify wrongdoings from the legal perspective and the
consequences of such wrongdoing
Analyse the principles of law in order to avoid conflicts in
society
Establish and analyse contractual obligations
Explain the dimensions of the law in relation to every human
behaviour
Introduction to law and its functions, the basis of laws in relation
to the area of engineering with emphasis on the laws of tort,
contract and intellectual property, Acts of Parliament that are
relevant to these areas
40 % Continuous Assessments
60 % Final Examination
The Law of Tort in Malaysia by Norchaya Talib
Communication Skills (CS1, CS2, CS3)
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Teamwork Skills (TS1, TS2)
Life Long Learning and Information Management (LL1, LL2)
Course Pro-forma
Faculty Course
Code
KXEX2244
Title
Ordinary Differential Equations
Pre-requisite
Student Learning Time (SLT)
KXEX1144
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
Synopsis
Assessment
References
Fundamental concepts and definitions in ODE, Initial value
problem, First order ODE: separable, linear, exact equations and
equations reducible to those forms. Integrating factor. Linear
equation of higher order: Linearly independent solutions,
Wronskian, Lagranges reduction of order, complementary
functions and particular solutions, the method of undetermined
coefficients, the variation of parameters, Euler-Cauchys equation.
Series solution method: power series, convergence, series soluti
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
Soft Skills
Ability to recognize the order and linearity of an ODE and
verifying whether a given function is a solution or not. Find
the solution of first order ODE.
Find the solution of linear second order ODE analytically.
Find the solution of linear second order ODE in series form.
Engineering Mathematics (5th Ed), K Stroud & D Booth,
Palgrave (2001)
Modern Engineering Mathematics (2nd Ed), Glyn James,
Addison-Wesley (1996)
Frank Ayres Jr, Schaum Outline Series: Differential Equations,
McGraw Hill, 1972
Communication Skills (CS1, CS2)
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Teamwork Skills (TS1)
Life Long Learning and Information Management (LL1)
DEPARTMENT OF CHEMICAL ENGINEERING
COURSE PRO-FORMA
BACHELOR OF ENGINEERING (CHEMICAL)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK 1111
Title
Chemical Engineering Thermodynamics I
Pre-requisite
Student Learning Time (SLT)
None
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
This is a core chemical engineering course in classical
thermodynamics. Equations of state will be used to model and
calculate thermodynamic properties of fluids. The laws of
thermodynamics are covered with particular emphasis on
application to chemical processes. The First Law of
Thermodynamics will be used for determining work, heat and
energy of open and closed systems. The Second Law of
Thermodynamics will be used for entropy. Heat engine,
refrigeration and heat pump will be analysed using the Second
Law of Thermodynamics. Common gas and vapour power cycles
will also be introduced.
40% Continuous assessment
60% Final examination
1.
2.
Soft Skills
Use the steam and property tables.
Identify and determine properties of pure substances.
Perform PVT calculations using the ideal gas law.
Apply the first law of thermodynamics to closed and open
systems.
Apply the second law of thermodynamics to closed and open
systems.
Perform calculations on reversible cyclic engines (e.g. Carnot,
Rankine).
Y.A. Cengel, M.A Boles, Thermodynamics: An Engineering
Approach, McGraw-Hill, 2002.
H.N. Moran, Fundamental Engineering Thermodynamics,
John Wiley 1996.
Critical thinking and problem solving skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK 1123
Title
Chemical Process Principles I
Pre-requisite
Student Learning Time (SLT)
None
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
Students are exposed to overall view of unit operations with the
description of processes. Use of basic engineering calculation,
unit conversion. Perform mass balance of non-reactive and
reactive systems using tables, charts and software.
40% Continuous Assessment
60% Final Examination
1.
2.
3.
Soft Skills
Identify unit operations involved in a process, draw process
flowcharts, and develop relationships between process
variables.
Perform simple degree-of-freedom analysis to identify the
number of unknowns relating to mass, mass flow rate,
composition, and energy, and develop the linearly
independent mass and energy balances needed to
determine unknown quantities.
Solve for the unknown variables using fundamental laws,
empirical relationships, and available data.
Solve material balances on chemical process systems.
Felder, R.M. & Rousseau, R.W. 2000. Elementary Principles
of Chemical Processes. 3rd. Ed. John Wiley & Sons.
G.V. Reklaitis. 1983, Introduction to Material and Energy
Balances, John Wiley & Sons.
David M. Himmelblau. 1996. Basic Pronciples and
Calculations in Chemical Engineering, 6th Ed, Prentice-Hall.
Critical Thinking and Problem Solving Skills (CT1-CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK1135
Title
Physical and Analytical Chemistry I
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
This course presents an introduction to the elements of physical
and analytical chemistry as a basic knowledge in chemical
engineering. It covers basic concepts of solution, mixture,
complete and limited solubility. The constructions of phase
diagrams using solubility limit or cooling curves is also another
important part in this course. Students are exposed to
quantitative measurement of gravimetric and volumetric
analyses, as well as thermal and radiation effects and their
applications in calorimetry and spectrophotometry, respectively.
Electrical effects such as conductivity and its applications, and
acid-base reaction, buffer solutions, ionic speciation are also
emphasized.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
Soft Skills
Explain concepts of solutions, mixture, complete and limited
solubility.
Construct and interpret simple phase diagrams of binary and
ternary mixtures.
Explain and interpret basic results of calorimetry, e.g. for the
determination of melting point, specific heat capacity and
heat of reaction.
Explain the effects of electromagnetic radiation on chemical
species (e.g. IR, UV-Vis), and interpret simple spectra.
Predict pH and species concentration in solutions, including
buffer solutions.
Explain and quantify conductivity and its applications.
Atkins, P.W. The Elements Physical Chemistry, 7th ed.,
Oxford Univ. Press, 2002.
Maron and Lando; Fundamentals of Physical Chemistry,
Macmillan Pub. Co., 1974.
D. A. Skoog, D. M. West, F. J. Holler & S. R. Crouch,
“Fundamentals of Analytical Chemistry”, Brooks Cole, 8th
ed., 2003.
G. D. Christian, “Analytical Chemistry”, Wiley, 6th ed., 2003.
Critical Thinking and Problem Solving Skills (CT1, CT2)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK1136
Title
Organic Chemistry
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
The course introduces to fundamentals of organic chemistry with
emphasis on the application to chemical engineering field. The
course exposed to nomenclature, molecular structures &
stereochemistry and reaction mechanisms viz nucleophilic and
electrophilic reagents and reactions (Nucleophilic substitution
and elimination reactions, electrophilic addition and aromatic
substitution reactions; oxidation and reduction reactions). The
students are finally exposed to organic chemical technology such
as organic feed stocks and production processes: coal,
petroleum, natural gas, animal and vegetable fats, production of
petrochemicals and oleo chemicals
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
Soft Skills
Draw structures and identify the names of organic
molecules.
Draw detailed mechanism of industrial important organic
reactions.
Identify routes and reactions for the production of organic
substances.
Identify and list the main raw materials and steps in the
production of petrochemicals and oleochemicals.
Organic Chemistry, Francis A. Carey, Fourth Edition,
McGraw-Hill, 2000.
Organic Chemistry, Graham Solomons, Seventh Edition, John
Willey & Sons, 2000.
Shreve’s Chemical process Industries, Fifth Edition,
McGraw-Hill, 1984.
Internet resources: patents, research paper, etc..
Critical Thinking and Problem Solving Skills (CT1, CT2)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK1141
Title
Statistics for Engineering
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
Synopsis
Assessment
References
Expose students with modern concepts of statistics with
emphasis on engineering applications. Use statistical charts and
tables to perform simple statistical analysis. Use software tools to
perform statistical analysis.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
5.
6.
Soft Skills
Identify and describe modern concepts of statistics and
probability, emphasizing applications to quality engineering
and improvement, process capability and control and
reliability assessment.
Use statistical and probability software tools to solve
problems.
Apply statistical methods and probability to perform
statistical quality control, design of experiments and
reliability analysis.
David M. Levine, Patricia P. Ramsey, & Robert K. Smidt.
Applied Statistics for Engineers and Scientists: Using
Microsoft Excel & Minitab. Prentice-Hall, 2001.
Douglas C. Montgomery, Design and Analysis of Experiments,
7th Edition, Wiley, July 2008.
Douglas C. Montgomery, George C. Runger, Norma Faris
Hubele. Engineering Statistics, 4th Edition,Wiley, 2007.
John Kinney. Statistics for Science and Engineering. AddisonWe sley, 2002.
Thomas J. Lorenzen & Virgil L. Anderson. Design of
Experiments: A No-name Approach.m.Dekker.1993.
William Mendenhall & Terry Sincich. Statistics for
Engineering and the Sciences, 5th Edition. Prentice-Hall,
2007.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK1142
Title
Numerical Methods For Engineering I
Pre-requisite
Student Learning Time (SLT)
None
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
Students will be introduced to computers and their roles in
numerical analysis. Three software packages will be introduced,
i.e. MATLAB, Excel and MathCAD, with emphasis on the first two.
Numerical differentiation is introduced together with array
manipulation in computer software. Truncation errors will be
used to provide error estimates. This is followed by numerical
integration, together with summation and looping in softwares.
Root finding of single non-linear equation will further require use
of logical operations in MATLAB or built-in functions in Excel.
Solution of linear systems via Gauss-Seidel and Gaussian
elimination uses nested loops with more complicated operations.
This paves the way for the Newton-Raphson method which
combines non-linear root finding algorithm with linear systems.
Throughout the various methods, there will be emphasis on error
estimates and proper use of significant digits.
50 % Continuous Assessments
50 % Final Examination
1.
2.
3.
4.
Soft Skills
Identify and describe different types of computer hardware
& software.
Outline, write and create computer programs based on
mathematical software.
Create and apply programs to solve numerical methods
problems of root finding, systems of equations, integration
and differentiation.
Perform error estimation associated with programs and
numerical methods.
S.C. Chapra & R.P. Canale. Numerical Methods For Engineers,
McGraw-Hill. 5th Edition, 2005.
H. Moore. Matlab for Engineers, Prentice-Hall, May 2006.
W. J. Palm III. Introduction to Matlab 7 for Engineers.
McGraw-Hill. July 2004.
William H.Press. Numerical recipes In C : The Art Of Scientific
Computing. Cambridge University Press. 1988-92.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK1153
Title
Fluid Mechanics
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
Synopsis
Assessment
References
The concepts of fluids through deformation under stress. Fluid
statics, concept of pressure and hydrostatic head and their
measurements. Fluid dynamics: description of laminar and
turbulent flow. Bernoullis equation describing frictionless
(inviscid) flow. Fluid friction and effects on pressure drop.
Measurement of flow rate and pressure. Concept of viscosity as
the source of friction. Calculation of major and minor losses,
pumping power. Pumps, valves and common piping accessories.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
Soft Skills
Explain the basic concepts pertaining to fluid statics and
dynamics.
Apply Bernoulli’s equation.
Estimate pressure drop for incompressible flow.
Explain working principles and features of basic piping
accessories.
Perform basic design of fluid transfer system for
incompressible flow.
Bruce R. Munson, Donald F. Young & Theodore H. Okiishi,
Fundamentals of Fluid Mechanics , 5th edition, John Wiley.
2010
James O. Wilkes & Stacy G. Bike. Fluid Mechanics for
Chemical Engineers, Prentice Hall.
Robert Fox, Alan T. McDonald & Philips J. Pritchard,
Introduction to Fluid Mechanics, 6th edition, John Wiley,
2010.
Ron Darby, Chemical Engineering Fluid Mechanics, 2nd
Edition, Marcel Dekker. 2011
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK1174
Title
Physical Chemistry Laboratory
Pre-requisite
Student Learning Time (SLT)
None
40 hours
Credit
1
Learning Outcomes
1.
2.
3.
4.
5.
Synopsis
Assessment
References
Soft Skills
Perform simple laboratory procedures such as solution
preparation, dilutions, and titrations.
Use basic laboratory measurement equipment such as
electronic balances, pycnometers, pH meter,
spectrophotometers, and surface tension meters.
Explain the interconnection between experimental
foundation and underlying theoretical principles.
Perform physical chemistry experiments covering a wide
range of principles such as solution chemistry, surface
chemistry, and environmental chemistry.
Communicate in written reports the results of their work in a
concise manner.
This laboratory course introduces to physical chemistry
experiments involving chemical solution tests (Conductance &
applications, activity & coefficient, acid-base reactions, ionic
solubility), Surface chemistry and colloid (surface tension, CMC,
liquid adsorption isotherms, sedimentation), environmental
chemistry (TSS, BOD, COD), Chloride value
50 % Continuous Assessments
50 % Final Examination
Refer to lab manual
Communication Skills (CS1, CS2, CS3)
Critical thinking and Problem solving skills (CT1, CT2, CT3)
Team Work Skills (TS1, TS2)
Life Long Learning and Information Management (LL1, LL2)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK1222
Title
Chemical Process Principles II
Pre-requisite
Student Learning Time (SLT)
KKEK 1121
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
Students are exposed to energy balance for closed and open
system. Perform detailed energy balance calculations for nonreactive ,and combustion processes with the help of steam
tables, other property tables for processes such as heat of
mixing, humiditcation, chemical reaction. Students are
encouraged to use computer software Excel, MathCAD, Matlab
for doing computer aided energy balance calculations.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
Soft Skills
Write simple phase equilibrium relationships and use phase
diagrams.
Extract data for pure compounds and mixtures from tables,
charts, graphs, or phase diagrams, and estimate these
through theoretical or empirical equations.
Apply the ideal gas rule and equations of state for real gases.
Use solubility data, miscibility charts, psychrometric charts
and phase relationships to calculate equilibrium composition
of multiphase, multi component systems.
Determine enthalpy and internal energy changes associated
with changes in temperature, pressure, mixing, phase
change, and chemical reaction from appropriate heat
capacities, heats of solution, latent heats, and heats of
formation or combustion.
Solve material and energy balances simultaneously on
chemical process systems.
Chemical and Energy Process Engineering, Sigurd Skogestad,
CRC press (2009)
Felder, R.M. & Rousseau, R.W. 2000. Elementary Principles
of Chemical Processes. 3rd. Ed. John Wiley & Sons
G.V. Reklaitis. 1983, Introduction to Material and Energy
Balances, John Wiley & Sons.
David M. Himmelblau. 1996. Basic Principles and Calculations
in Chemical Engineering, 6th Ed, Prentice-Hall
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK2110
Title
Fundamentals of Materials Science for Chemical Engineering
Pre-requisite
Student Learning Time (SLT)
None
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
6.
7.
Synopsis
Assessment
References
At the beginning of the course, the students will be exposed to
the basic materials science which comprises of atomic structures
& bonding and also crystal structures & geometry and their space
lattices. Important engineering materials such as metals, alloys,
polymer, ceramics and composites together with their
properties, phase diagrams, treatments and types of testing will
be introduced. In addition, the corrosion/degradation of
materials and preventions is also included.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
Soft Skills
Explain the atomic structure and types of primary and
secondary atomic and molecular bonding.
Explain the crystal structures and geometry and classify
different classes of space lattices in crystalline solids.
Perform different types of mechanical testing for evaluation
of mechanical properties of material.
Extract information of materials behaviour from phase
diagram.
Identify the structures, properties and applications of the
main engineering materials (metals, alloys, polymers,
ceramics and composites.
Describe various manufacturing methods to process
materials and treatments to improve the properties of
materials.
Explain corrosion mechanisms and types of corrosions and
also list methods of corrosion prevention.
Callister W D, 2007,Materials Science and Engineering: An
Introduction, John Wiley & Sons, 7th Edition.
Smith W F, 2004, ‘Foundations of Materials Science and
Engineering’, McGraw-Hill, 3rd Edition.
Askeland D R, 2006The Science and Engineering of
Materials, Thomson.
Shackelford J F, 2005,Introduction to Materials Science for
Engineers, Pearson Prentice Hall, 6th Edition.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK2111
Title
Chemical Engineering Thermodynamics II
Pre-requisite
KKEK 1111
Student Learning Time (SLT)
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
Theorem of Corresponding State and other major equations of
state (EOS). Phase equilibrium: Gibbs Phase Rule, ideal solution,
Henrys Law, Raoults Law, partial molar properties, chemical
potential, fugacity, activity and activity coefficients (including
ionic species). Thermodynamic models (e.g. NRTL, UNIQUAC) for
the estimation of thermodynamic properties and complex phase
equilibria. Helmholtzs and Gibbs free energy, Maxwell relations,
Gibbs-Duhem equation and their applications. Chemical
equilibrium: free energy of formation, standard enthalpy of
reaction, chemical equilibrium in real gas mixtures, chemical
equilibrium in condensed phases, effect of reaction conditions on
chemical equilibrium and conversion. Using simulation packages
e.g. HYSYS and ASPEN.
40 % Continuous Assessments
60 % Final Examination
1.
2.
Soft Skills
Predict phase behaviour of mixtures using Gibbs Phase Rule.
Estimate thermodynamic properties of binary vapour-liquid
and liquid-liquid mixtures, e.g. using Henry’s Law, Raoult’s
Law, activity & fugacity coefficients.
Determine thermodynamic properties and complex phase
equilibrium with suitable models in simulation packages.
Perform checks on thermodynamic consistency of
experimental data.
Calculate the equilibrium constant for a reaction.
Evaluate the effects of reaction conditions on equilibrium
and conversion of a reaction.
M. Smith, H.C. Van Ness and M.M. Abbott, Introduction to
Chemical Engineering Thermodynamics, 7th Edition,
McGraw-Hill, 2005.
M.D. Koretsky, Engineering and Chemical Thermodynamics,
John Wiley, 2004.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK2142
Title
Numerical Methods For Engineering II
Pre-requisite
Student Learning Time (SLT)
KKEK 1142
KXEX 3244
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
Synopsis
Assessment
References
The course consists of introduction to numerical methods used in
problems of ordinary differential equations, partial differential
equations and optimisation. It also involves the applications of
numerical methods and programming in solving common
engineering problems such as numerical error analysis and
appropriate output using MATLAB
50 % Continuous Assessments
50 % Final Examination
1.
2.
3.
4.
Soft Skills
Describe and distinguish numerical methods used in
problems of ordinary differential equations, partial
differential equations and optimisation.
Write and create programs to solve numerical methods
problems of ordinary differential equations, partial
differential equations and optimisation.
Apply and practice effective communication and team skills.
S.C. Chapra & R.P. Canale. Numerical Methods For
Engineers, McGraw-Hill. 5th Edition, 2005.
H. Moore. Matlab for Engineers, Prentice-Hall, May 2006.
W. J. Palm III. Introduction to Matlab 7 for Engineers.
McGraw-Hill. July 2004.
William H.Press. Numerical recipes In C : The Art Of Scientific
Computing. Cambridge University Press. 1988-92.
Critical thinking and problem solving skills (CT1, CT2, CT3)
Team Work Skills (TS1)
Life Long Learning and Information Management (LL1)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK2154
Title
Heat Transfer
Pre-requisite
Student Learning Time (SLT)
None
122 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
This course introduces to basics of three mode of heat transfer
i.e. conduction, convection and radiation (steady & unsteady
state) with importance to Problem-solving. Also introducing
various heat transfer phenomena like boiling and condensation
and giving exposure to experimental determination of heat
transfer coefficients, including familiarity with the basic
instrumentation such as temperature measurement. Heat
transfer equipment such as double-pipe, Shell and tube, plate
and spiral exchangers. Finally touching upon heat exchanger
design using LMTD and NTU-Effectiveness methods and energy
integration.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
Soft Skills
Analyse heat conduction, forced convection and natural
convection.
Explain basic physical processes of condensation and boiling.
Propose and analyse basic heat transfer experiments.
Analyse heat transfer by radiation using shape factors and
networks.
Use LMTD and NTU-Effectiveness methods to predict the size
and performance of heat exchangers.
Perform basic design of heat exchangers.
Holman J.P; Heat Transfer, McGraw-Hill.
F.P Incropera & D. P. Dewitt; Introduction to Heat Transfer,
John Wiley & Sons.
Y. A Cengel; Heat Transfer, McGraw-Hill.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK2156
Title
Momentum Transfer
Pre-requisite
Student Learning Time (SLT)
KKEK 1153, KXEX 2245, KXEX 3244
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
Macroscopic mass and linear momentum balance using vector
notation begins the course. This is followed by expression of
stresses due to fluid motion, leading to the viscous stress tensor for
compact representation.
The extended Divergence Theorem
enables conversion into the differential form, i.e. Cauchys first
equation of motion. The alternative approach based on differential
momentum balance yields identical result. Application of the
inviscid or Newtonian constitutive equation leads respectively to the
Euler equation and the Navier-Stokes equation. Discussions on
initial and boundary conditions follow. Sample problems amenable
to analytical solutions will be discussed. Software packages and
formulation to facilitate numerical solutions will also be touched.
The constitutive equations for non-Newtonian fluids widen the
applicability of Cauchys equation, allowing friction factor
expressions. The inability to compute even more complex flows
reasonably will require use of correlations; in which the caution
required must be highlighted.
40 % Continuous Assessments
60 % Final Examination
1.
2.
Soft Skills
Solve problems using overall momentum balances for
macroscopic systems.
Explain the basis for the derivation of the continuity and the
Navier-Stokes equation.
Apply Navier-Stokes equation to solve simple momentum
transfer problems analytically, i.e uni-directional flow, Stokes
flow, flow in one dimension.
Explain the basis of numerical solution of the Navier-Stokes
equation for more complicated cases, e.g. Blasius’s solution of
the laminar boundary layer equations.
Explain features and characterization of non-Newtonian fluids,
and know the inapplicability of the Navier-Stokes equation.
Explain the modelling and experimental approaches to complex
flow (e.g. turbulent flow, multiphase flow)..
Transport Phenomena, revised 2nd. Ed., R. B. Bird, W. E.
Stewart & E. N. Lightfoot, John Wiley & Sons, 2007.
“Fundamentals of Momentum, Heat, and Mass Transfer”, J. R.
Welty, C. E. Wicks, R. E. Wilson & G. L. Rorrer, John Wiley &
Sons, 5th. ed., 2008.
Critical Thinking and Problem Solving Skills (CT1-CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK2157
Title
Mass Transfer
Pre-requisite
Student Learning Time (SLT)
KKEK 1153
KXEX 2245
KXEX 3244
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
Synopsis
Assessment
References
Mass diffusion and Ficks Law. Diffusion in a stagnant gas film.
Equimolar diffusion. Diffusion with reaction. General mass
transport equation. Dimensional analysis, e.g. to obtain Sh =
Sh(Re, Sc) using Buckinghams ï °-Theorem. Momentum, heat and
mass transfer analogies. Mass and heat transfer coefficients for
multi-phase systems, e.g. mixing. Experimental techniques to
determine the mass transfer coefficient, including familiarity with
basic instrumentation such as concentration measurement.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
Soft Skills
Formulate and solve simple problems involving diffusion.
Formulate and solve more complex problems involving
diffusion, convection and reaction.
Apply analogies to obtain transport coefficients.
Obtain appropriate overall heat and / or mass transfer
coefficients for more complex general cases, e.g. sparged
stirred tanks.
Propose and evaluate experimental investigations on mass
transfer.
Transport Phenomena, R. Byron Bird, Warren E. Stewart,
Edwin N. Lightfoot, John Wiley & Son, 2007
Transport Processes and Unit Operations, Christie J.
Geankoplis, 3rd Ed., Prentice Hall, 2003.
Fundamentals of Momentum, Heat, and Mass Transfer,
James R. Welty, Charles E. Wicks, Robert E. Wilson, John
Wiley & Son, 2007
Heat and Mass Transfer Fundamental and Application, 4Th
Ed. Mc Graw Hill, 2007.
Critical thinking and problem solving skills (CT1, CT2, CT3)
Life Long Learning and Information Management (LL1, LL2)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK2158
Title
Separation Processes I
Pre-requisite
KKEK 1222
Student Learning Time (SLT)
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
Introduction to the separation process fundamental. Phase rules
and equilibrium concept. Equations involve in unit operations
such as distillation, gas absorption and liquid-liquid extraction.
Calculation of number of stages and height of column
(distillation, gas absorption and liquid extraction column).
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
5.
6.
Soft Skills
Differentiate type of unit operations which involve interphase mass transfer.
Use stage equations to perform basic calculation in binary
distillation and gas absorption designs.
Calculate number of stages in multi-components distillation
column.
Choose suitable methods to calculate number of stages or
height of distillation and gas absorption column.
Calculate number of stages in liquid extraction tower.
Integrate the knowledge and understanding in designing
separation columns with other unit operation.
Geankoplis C J, 1995, ‘Transport Process and Unit
Operations’, Prentice-Hall.
Mc.Cabe W L, Smith J C, 1993, ‘Unit Operations of Chemical
Engineering’, McGraw-Hill.
Seader & Henley, 1998, ‘Separation Process Principles’, John
Wiley & Son.
Coulson J M, Richardson J F , ‘Chemical Engineering Vol 2,
Butterworth-Heinemann.
Smith B D, Design of Equilibrium Stage Processes, McGraw
Hill.
Treybal R E, Mass Transfer Operations, McGraw-Hill.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK2171
Title
Laboratory and Communications I
Pre-requisite
Student Learning Time (SLT)
None
81 hours
Credit
2
Learning Outcomes
1.
2.
3.
Synopsis
Assessment
References
Soft Skills
Analyse and interpret experimental data from the
experiment conducted.
Write good technical reports.
Build up skill in communication through compulsory oral
presentation.
Students are exposed to performing various unit operation
experiments like centrifugal pump, fluid behaviour, heat effects
thermodynamics, mass transfer and other general experiments;
plate and frame filter, welding, viscosity measurement and
particle size analysis with emphasis is laid on safety aspects.
Students communication skill is improved by their oral
presentations. The students are grounded to prepare report in
accordance with standard format for doing calculations with
results and conclusion.
100 % Continuous Assessments
Lab Manual
Communication skills (CS1, CS2, CS3)
Critical thinking and problem solving skills (CT1, CT2, CT3)
Team work skills (TS1)
Life- long learning and Information management (LL1, LL2)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK2220
Title
Reaction Engineering I
Pre-requisite
KKEK 1222
Student Learning Time (SLT)
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
Synopsis
Assessment
References
This course introduces the concept of chemical reaction
engineering such as rate expressions, conversion and etc. These
concepts are used to derive equation for rate of reaction, based
on pseudo steady state assumption, rate limiting step
assumptions. The rate equations can be used to derive design
equation for different types of reactors (batch, CSTR, PFR, PBR)
and reaction schemes (constant and variable volume). Based on
the knowledge of types of reactors, the experimental data for
determination of kinetic parameters can be analysed. The course
also covers mass and energy balances to examine multiple steady
state phenomenon for non isothermal and adiabatic reactors.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
Soft Skills
Explain how to derive rate of reaction equation based on
elementary reaction, steady state approximation, rate
controlling step and experimental data, the concept of
conversion for changing & unchanging volume.
Analyze the rate for serial, multiple & complex reactions.
Derive reactor design equations for plug flow, CSTR & batch
reactors and determine the size of reactor required for single
or multiple reactors with different arrangements.
Derive energy equation & evaluate effect of heat on rate of
reaction and reactor size and identify multiple steady state
phenomena.
Practice effective teamwork practices.
S.H. Fogler, Element of Chemical Reaction Eng. Prentice Hall,
2006
J. M. Smith Chemical Engineering Kinetics. McGRAW-HILL,
1981
L.D. Schmidt,The Engineering of Chemical Reaction. 2nd Ed.
Oxford University press, 2005
G.W. Roberts, Chemical Reactions and Chemical Reactors,
John Wiley, 2009
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK2233
Title
Physical and Analytical Chemistry II
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
Expose students to the fundamentals of surface phenomena with
emphasis on engineering applications. This includes the nature
and characterization of heterogeneities on solid surfaces as well
as the properties, uses and issues, and production of colloidal
system. The methods of analytical techniques involving the
surface phenomena, which include GC, HPLC, BET equipment,
zeta potential meter, Langmuir through and voltammeter will be
introduced and the interpretation of these methods will be
elaborated in detail.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
Soft Skills
Explain surface phenomena such as capillarity, adsorption,
electrical double layer, electrode reactions.
Describe the nature and characterization of heterogeneities
on solid surfaces.
Explain the properties, uses and issues, and production of
colloidal systems.
Explain the methods and interpret simple results of
analytical techniques that involve surface phenomena, e.g.
GC, HPLC, BET equipment for adsorption isotherm, zeta
potential meter, Langmuir trough, and voltammeter.
Berg J.C.; An Introduction to Interfaces and Colloids: The
Bridge to Nanoscience, World Scientific, 2009.
Barrow G.M.; Physical Chemistry, 6th edition, McGrawHill,
1996.
Christian G.D.; Analytical Chemistry, 6th edition, Wiley, 2004.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK3151
Title
Biochemistry
Pre-requisite
Student Learning Time (SLT)
None
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
6.
7.
8.
Synopsis
Assessment
References
Expose students with basics of biochemistry with emphasis on
applications in various bioprocesses. Describe the structure and
functions of microorganisms and biomolecules in industrial
applications. Describe the mechanisms and inhibitions of
enzymatic reactions. Understand various factors affecting the cell
growth. Apply simple enzymatic and cell growth models to
describe kinetics of biological reactions. Understand the
functions of important metabolic pathways in cells
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
Soft Skills
Describe different types of living organisms and their
structure and function.
Explain the basic structure and functions of amino acids,
proteins, carbohydrates, lipids, DNA and RNA.
Explain the mechanisms and kinetic characteristics of
enzyme reaction.
Identify major metabolic pathways such as glycolysis and
citric acid cycle.
Relate the importance of metabolic pathways to various
bioprocesses.
Explain cell growth and quantify growth kinetics.
Describe the main methods utilized in molecular biology and
their applications to genetic engineering.
Describe the applications of biotechnology in various
industries.
Essential Biochemistry, by Pratt, Cornely, Wiley.
Concepts in Biochemistry (3rd Edition), by Boyer, Wiley,
2006.
M. Shuler and F. Kargi; Bioprocess Engineering: Basic
Concepts, Prentice Hall, 2002.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK3152
Title
Modelling of Chemical Processes
Pre-requisite
Student Learning Time (SLT)
KKEK 2111
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
Synopsis
Assessment
References
This course enables students to learn the key steps in carrying
out process modelling, degrees of freedom analysis, and solving
different types of models. Students will be exposed to usage of
Matlab and Simulink for process modelling analysis. Students will
practise the skills learnt at the different stages via short
presentations in class.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
5.
6.
Soft Skills
Perform first principles modelling for chemical process
systems.
Formulate degrees of freedom method to solve all types of
models for chemical processes.
Linearize and solve nonlinear models using Laplace
transform
Perform model sensitivity analysis for process models.
Programming and analyses of chemical process models using
Matlab and Simulink Software.
Process Systems Analysis and Control, Donald R.
Coughanowr, McGraw- Hill, Second Edition (1991).
Process Dynamics and Control, Dale E. Seborg, Thomas F.
Edgar and Duncan A. Mellichamp, John Wiley (1989).
Chemical Process Control: An Introduction to Theory and
Practice, George Stephanopoulos, Prentice Hall International
Edition (1984).
Process Dynamics, Modeling, Analysis and Simulation, B.W.
Bequette, Prentice- Hall International series (1998).
Elementary principles of Chemical Processes, Felder, R.M.,
and Rousseau, R.W., John Wiley & Sons (2000).
Unit Operations of Chemical Engineering, McCabe, Smith and
Harriot, McGraw-Hill International (2001).
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Team work skills (TS1, TS2)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK3153
Title
Simulation of Chemical Processes
Pre-requisite
Student Learning Time (SLT)
KKEK 2111
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
Exposes students with the use of computer simulation software
such as AspenOne or Promax to perform mass and energy
balance and simulate common unit operations such as heat
exchangers, distillation columns, reactors, etc. Use simulation
software to perform simulation of selected chemical processes
flow sheets.
100 % Continuous Assessments
1.
2.
3.
Soft Skills
Use commercially available softwares such as AspenPlus and
HYSYS to perform mass and energy balance calculations.
Perform analysis of chemical processes using HYSYS.
Perform analysis of chemical processes using AspenPlus.
Use AspenPlus and HYSYS to simulate the operation of major
unit operations such as reactors, distillation columns, heat
exchangers, absorbers, etc.
Felder, R. M., & Rousseau, R. W. 2000. Elementary Principles
of Chemical Processes. 3rd. Ed. John Wiley & Sons.
Mccabe, Smith, and Harriott, 2001.Unit Operations of
chemical Engineering. Sixth Edition, McGraw-Hill
International.
Lecturer’s notes, and Software Packages user manuals,
information from internet.
Critical Thinking and Problem Solving Skills (CT1, CT2)
Team Work Skills (TS1, TS2)
Life Long Learning and Information Management (LL1)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK3154
Title
Process Control
Pre-requisite
KKEK 3152
Student Learning Time (SLT)
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
The course will initially cover the dynamic responses of processes
using transfer function approach. It is followed by the
formulation of the closed loop control block diagram and study of
the responses and stability of these closed loop systems using
conventional controllers. Design of control systems through
frequency based techniques will also be taught along with the
Bode stability criteria methods and tuning of controllers. The
design of cascade control systems will also be covered at the end
of the course.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
Soft Skills
Analyse responses of systems with different orders.
Analyse closed loop block diagrams.
Design controllers for closed loop systems.
Tune controllers that has been designed using various
methods such as Bode stability criteria and dynamic error
criteria
Analyse the stability of closed loop systems that has been
designed.
Design the overall closed loop system and cascade systems
for chemical processes.
Coughanowr, Process Systems, analysis and Control,
McGraw-Hill, 1991.
Stephanopoulos, Chemical Process Control, Prentice-Hall,
1984.
D.Seborg et.al., Process Dynamics and Control, Wiley , 2004.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3, CT4,
CT5)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK3155
Title
Particle Technology
Pre-requisite
Student Learning Time (SLT)
None
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
Synopsis
Assessment
References
Soft Skills
Characterise particle solids.
Design unit operations which involve particulate systems.
Manipulate related equations for different conditions (i.e.,
constant pressure, etc.).
Apply the correct equations in designing equipment
involving particulate systems.
Evaluate the suitability of the solution obtained in
theoretical calculation.
Introduction of particle technology and solids handling issues. In
this course students will be involved in equipment design on unit
operations related to solids. In addition, the subject of solid-solid
mixing and powder storage are also covered.
40 % Continuous Assessments
60 % Final Examination
1.
2.
Principles of Powder Technology, Martin Rhodes (1993).
Introduction to Particle Technology, Martin Rhodes (1998).
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK3156
Title
Plant Engineering
Pre-requisite
Student Learning Time (SLT)
None
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
6.
7.
Synopsis
Assessment
References
Process plants are complex facilities consisting of equipment,
piping systems, instruments, electrical systems, electronics and
control systems. The design and engineering of process plants
require not only fundamental core chemical engineering but also
multidisciplinary knowhow. Plant layout principles and system
design of air, water, steam, industrial gases supply constitute a
major part of the design and engineering effort in order to design
a safe and dependable processing facility in a cost effective
manner. This course provides the basic knowledge and skills and
covers the fundamental principles and concepts used in plant
design highlights concepts such as electrical distribution system
requirements, fire fighting and centralized refrigeration system
design, plant maintenance and commissioning planning,
ventilation and other common facilities, principles for designing
shut down and start-up procedures, and quality control and
monitoring requirements.
40 % Continuous Assessments
60 % Final Examination
1.
2.
Soft Skills
Synthesise a layout plan for a given process plant with all the
major components.
Produce flow diagram for air, water, steam, central
refrigeration and industrial gases system with appropriate
components for any given process plant.
Select appropriate electrical and fire fighting requirement.
Produce commissioning procedures for any given equipment
or combination of equipments using systematic and safe
approaches.
Select main maintenance required for a given unit operation.
Generate start-up and shut down procedures for a given
equipments or system.
Select main controlling and monitoring requirements for a
given product or utility line.
Robert C. Rosaler., Standard Handbook of Plant
Engineering., McGraw-Hill, 1983.
J.L.A. Koolen, Design of simple and Robust process plants,
Wiley, 2001.
Communication skills (CS1, CS2, CS3)
Critical thinking and problem solving skills (CT1, CT2, CT3)
Team work skills (TS1, TS2)
Life long learning and Information management (LL1, LL2)
Professional ethics and moral (EM1)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK3157
Title
Process Synthesis
Pre-requisite
Student Learning Time (SLT)
KKEK 2154, KKEK 2220, and KKEK 2158
105 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
Synopsis
Assessment
References
This course enables students to learn the key steps in carrying
out a process design, creation and synthesis with emphasis on
environmental issues and safety considerations. Students will be
exposed to basic principles of sequencing and optimizing of
separation columns, determine minimum energy requirement for
heat exchanger network and reduce power requirements.
Students will also be exposed to handling flowsheet
controllability and plantwide control structure.
40 % Continuous Assessments
60 % Final Examination
1.
2.
Soft Skills
Design a train of separation units
Design a heat exchanger network (HEN) for a chemical
process such that the maximum energy is recovered or the
minimum number of exchangers is used
Suggest reasonable process control configurations using
qualitative methods
Formulate linear optimization problems
Solve linear optimization problems using linear programming
Seider, W. D., Seader, J. D. and Lewin, D. R. Product and
Process Design Principles: Synthesis, Analysis and Evaluation,
Wiley (2004).
George Stephanopoulos Chemical Process Control: an
Introduction to Theory and Practice (Prentice Hall
International Series in the Physical and Chemical Engineering
Sciences), Prentice Hall PTR.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Team work skills (TS1)
Life long learning and Information management (LL1)
Professional ethics and moral (EM1)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK3159
Title
Separation Processes II
Pre-requisite
KKEK 1222
Student Learning Time (SLT)
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
6.
7.
Synopsis
Assessment
References
Quantitative and qualitative analysis of separation processes
involving simultaneous heat and energy balances, i.e.
humidification/dehumidification, drying, evaporation,
crystallization. Design calculations of the processes.
Classification of membranes and membrane processes.
Membrane resistances and diffusivities.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
Soft Skills
Perform simultaneous mass and energy balances of
processes.
Explain the theoretical basis of processes involving
humidification/dehumidification, drying, evaporation,
crystallisation and membrane separation.
Perform calculations for the processes mentioned in (2).
Give suggestions to equipment choices.
Select an appropriate membrane for a particular process.
Explain the principles of operation of different membrane
types.
Geankoplis, C.J.,Transport Process and Unit Operations, 4th
Edn, 2003, Prentice-Hall.
Treybal, R.E., ‘Mass Transfer Operations”, 3rd edn, 1980,
McGraw Hill.
Seader, J.D. and Henley, E.J.,Separation Process Principles,
1998, John Wiley & Sons
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK3161
Title
Process Safety
Pre-requisite
Student Learning Time (SLT)
None
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
Methods to identify hazards in workplace by application of JSA,
HAZOP and Fault Tree Analysis will be explained. Analytical
methods to estimate reliability of equipment are described. This
course also includes explanation of methods for accident
investigation and to look on deficiencies in Process Safety
Management System.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
5.
Soft Skills
Identify hazards at workplace
Calculate the amount of toxic release due to vessel failure.
Conduct HAZOP study and Fault Tree Analysis from the PID
diagram.
Carry out a reliability study on the equipment.
Estimate damage and risk due to explosion.
Conduct accident investigation for the determination of
deficiencies in Process Safety Management System
Phillion, B. S.: Reliability, Quality and Safety for Engineers,
CRC Press, 2004.
Braver, R.L.: Safety and Health for Engineers, WileyInterscience, 2nd Edition, 2005.
Daniel, Crowl and Joseph: Chemical Process Safety:
Fundamentals with Applications, Prentice-Hall, 2001.
Wells, G.: Hazard Identification and risk Assessment, IChemE,
1997.
Act 514: Occupational Health and Safety, 2008.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Team work skills (TS1)
Lifelong learning and Information management (LL1)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK3171
Title
Lab and Communication II
Pre-requisite
Student Learning Time (SLT)
KKEK 2171
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
Soft Skills
Conduct experimental work in heat transfer, reaction
kinetics, separation process, fluid mechanic and process
control.
Use and demonstrate analysis of technical data.
Work 2-3 persons per group in doing experiment.
Communicate the analysis and results individually in
technical report and oral presentations.
Mass and energy transfer operation: Heat exchanger, film and
drop wise condensation, climbing film evaporator and single
effect evaporator. Chemical Engineering Reaction: Residence
time distribution, kinetic of homogeneous and heterogeneous
reaction. Separation process: Binary distillation, bubble cap
distillation, extraction. Process control: Flow, level and
temperature control.
100 % Continuous Assessments
Lab Manual
Communication skills (CS1, CS2, CS3)
Critical thinking and problem solving skills (CT1, CT2, CT3)
Team work skills (TS1)
Life- long learning and Information management (LL1, LL2)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK3192
Title
Industrial Training
Pre-requisite
Student Learning Time (SLT)
None
200 hours
Credit
5
Learning Outcomes
1.
2.
3.
Synopsis
Assessment
References
Soft Skills
Apply engineering knowledge in practice.
Communicate effectively.
Practice good work ethics and safety
Learning multiple and integrated aspects that are related to
chemical engineering field.
100 % Continuous Assessments
None
Communication skills (CS1, CS2, CS3)
Critical thinking and problem solving skills (CT1, CT2, CT3)
Team work skills (TS1, TS2)
Life long learning and Information management (LL1, LL2)
Professional ethics and moral (EM1, EM2)
Leadership skills (LS2)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK3221
Title
Reaction Engineering II
Pre-requisite
Student Learning Time (SLT)
KKEK 2220
84 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
This course introduces the properties, characterization and
manufacturing of catalyst ensued by the catalytic reactions and
its criteria. All possible mechanisms for the catalytic reactions
based on reaction control, adsorption control and diffusion
control will be covered. The course covers also the effects of
external mass transfer as well as the internal mass transfer on
concentration and temperature profiles inside the pellet and its
relation to the effectiveness factor and Thiele Modulus. The
above principles are applicable for the design of slurry and plug
flow reactors.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
Soft Skills
List types of catalyst and methods of characterization it
based on adsorption and mercury intrusion.
Determine reaction rate equation based on reaction control,
adsorption control and diffusion control for single site and
dual sites.
Demonstrate effects of external mass transfer on
concentration and temperature gradients between the bulk
phase and the catalyst surface.
Analyze effects of internal mass transfer on concentration
and temperature gradients inside catalyst pellet and the use
of several criteria to evaluate the mechanism that control
the reaction.
Design slurry and plug flow reactors.
Assess effective teamwork practices.
S.H. Fogler, Element of Chemical Reaction Eng. Prentic Hall,
1995.
O. Levenspiel, Chemical Reaction Engineering, John Wiley,
1972.
J. M. Smith Chemical Engineering Kinetics. McGRAW-HILL,
1981,
Schmid, L. D. 1998. The Engineering of Chemical
Reaction. Oxford University press.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK3282
Title
Design Exercise
Pre-requisite
Student Learning Time (SLT)
KKEK 2154, KKEK 2220, and KKEK 2158
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
The students are assigned to perform mass and energy balances
and also design important unit operations (heat exchanger,
reactor, distillation column, storage tank and piping systems) in a
chemical process plant. The tasks are performed manually and
also using simulation softwares such as AspenPlus and HYSIS. In
addition, the students are required to produce proper PFD
drawing of the chemical plant using AutoCAD. The tasks are
performed in groups. The students are also required to write
technical reports and give oral presentation.
100 % Continuous Assessments
1.
2.
3.
4.
5.
Soft Skills
Collect the engineering and scientific data required for
formulating and solving the fundamental design equations of
important unit operations.
Design major equipment in a chemical processing plant
manually and also using simulation softwares.
Work in a team on solving an open-ended design project.
Write professional technical reports consisting of concise,
well structured and clear language
Perform a professional oral presentation with appropriate
visual aids.
Use commercial software to produce chemical engineering
drawings such as PFD drawing.
Patents and open literature publications including internet
resources.
Turton, Bailie, Whiting and Shaewitz, Analysis, Synthesis, and
Design of Chemical Processes, 2nd Edition, Prentice Hall,
2003.
Coulson, Richardson and Sinnott, Chemical Engineering Vol.
6. Pergamon Press, 1999.
McCabe, Smith, and Harriott, Unit Operations of Chemical
Engineering, 6th Edition, McGraw Hill, 2001.
AutoCAD software manual.
Communication skills (CS1, Cs2, CS3, CS4)
Critical thinking and problem solving skills (CT1, CT2, CT3, CT4)
Team work skills (TS1, TS2, TS3)
Life long learning and Information management (LL1, LL2)
Enterpreneuraial skills (KK1)
Leadership skills (LS1)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4163
Title
Environmental Management
Pre-requisite
Student Learning Time (SLT)
None
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
Synopsis
Assessment
References
General perspective of pollution. Environmental ecosystems.
Transport and transformation of pollutants. Industrial activities
and the environment. Residuals management. Improved
manufacturing operations. Environmental legislation. Pollution
prevention concepts and toolbox. Towards a sustainable society.
40 % Continuous Assessments
60 % Final Examination
1.
2.
Soft Skills
Relate the concept of pollution and its relationship to the
environmental ecosystems.
Determine the contribution of industrial processes to
pollution.
Illustrate the concept of pollution prevention.
Propose potential actions to prevent pollution.
Examine the role of a responsible and ethical member of
society for the development of a sustainable environment.
Bishop, P.L. Pollution Prevention, McGraw-Hill, Singapore
2000.
Davis M.L. and Masten S.J. Principles of Environmental
Engineering & Science, McGraw-Hill Int. edition, Singapore,
2004.
Communication skills (CS1, CS2, CS3, CS4)
Critical thinking and problem solving skills (CT1, CT2, CT3, CT4)
Team work skills (TS1, TS2, TS3)
Life long learning and information management (LL1, LL2)
Entrepreneurial Skill (KK1)
Professional ethics and moral (EM1, EM2)
Leadership skills (LS1, LS2)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4165
Title
Project Management
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
Synopsis
Assessment
References
Soft Skills
Identify project components.
Create time table and resource allocation for a project.
Evaluate projects using Work Breakdown Structure.
Solve problem collectively.
Determine critical paths.
Forming vision, mission, target, objective and project scope.
Planning and develop WBS. Project cost estimation. Resource
allocation and scheduling. Handling conflict and changes.
Project risk management. Quality management and control of a
project
40 % Continuous Assessments
60 % Final Examination
Larson, E.W. and Gray C. F,Project Management-The managerial
Process, McGraw Hill, 2011
Critical thinking and problem solving skills (CT1, CT2, CT3)
Team work skills (TS1)
Leadership skills (LS1, LS2)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4167
Title
Process Economics and Engineering
Pre-requisite
Student Learning Time (SLT)
None
120 hours
Credit
3
Learning Outcomes
1.
2.
3.
4.
5.
Synopsis
Assessment
References
Basic elements on economics which need to be considered in
dealing with current project issues such as supply and demand,
depreciation, inflation, financial resources and taxes are
introduced. Students are then exposed to conduct financial
analysis and economic feasibility study before making decision on
any engineering projects.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
Soft Skills
Gather the information needed to conduct economic
assessment on an engineering project.
Estimate the operational and capital cost of a chemical plant.
Determine the economic feasibility of a project.
Conduct economic optimization exercise for existing
alternatives.
Explain facts on basic economics related to daily issues.
Peters & Timmerhaus, Plant Design & Economics for
Chemical Engineers, 5th ed, McGraw Hill, 2002.
Degarmo, Sullivan, Bontadelli and Wicks, Engineering
Economy, 10th Edition, Prentice Hall, 1997.
Fabryky, Thuesen and Verma. Economic Decision Analysis,
3rd Edition, Prentice Hall, 1998.
Hartman, J.C. Engineering Economy and the Decision Making
Process, Prentice Hall, 2006.
Communication skills (CS1)
Critical thinking and problem solving skills (CT1, CT2, CT3)
Team work skills (TS1)
Lifelong learning and information management (LL1)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code KKEK4281
Title Design Project
Pre-requisite KKEK 3153, KKEK 3154, KKEK 3156, KKEK 3157, KKEK 3221, KKEK 3282
Student Learning Time (SLT) 240 hours
Credit 6
Learning Outcomes 1.
2.
3.
4.
5.
Design a chemical plant and its major equipment such as reacting unit,
separation system and heat transfer equipment
Conduct a technical and economic feasibility study before establishing
a chemical plant.
Evaluate fixed and operating costs involved.
Predict the operation of a chemical plant.
Apply team work and good communication skills
Synopsis One or more project proposals to produce chemicals will be prepared by the
design project coordinator. Students work in groups of four or five, with each
group supervised by an academic staff. In the first semester, each group has
to examine flow sheets based on technical, economic, environmental
considerations, and complete the mass and energy balances. In the second
semester, each student has to design a major equipment or system such as a
chemical reactor or a vacuum generating system complete with the
engineering drawings, safety features and ccontrol systems.
Assessment 100 % Continuous Assessments
References 1.
2.
3.
4.
5.
6.
7.
8.
9.
Kirk-Othmer, “Kirk-Othmer Encyclopedia of Chemical Technology”,
Vols. 1 to 27, 4th ed., Wiley-Interscience, 1998.
R. Turton, R. C. Bailie, W. B. Whiting & J. A. Shaeiwitz, “Analysis,
Synthesis, and Design of Chemical Processes”, 2nd ed., Prentice-Hall,
2002.
R. K. Sinnott, “Chemical Engineering Design”, Vol.6, 4th ed.,
Butterworth-Heinemann, 2005.
W. D. Seider, J. D. Seader & D. R. Lewin, “Product and Process Design
Principles: Synthesis, Analysis, and Evaluation”, 2nd ed., Wiley, 2003
M. S. Peters, K. D. Timmerhaus, R. E. West & M. Peters, “Plant Design
and Economics for Chemical Engineers”, 5th ed., McGraw-Hill, 2002.
G. Towler & R. K. Sinnott, “Chemical Engineering Design: Principles,
Practice and Economics of Plant and Process Design”, ButterworthHeinemann, 2007.
R. M. Smith, “Chemical Process: Design and Integration”, 2nd ed.,
Wiley, 2005.
ASPEN Software Manual.
HYSIS Software Manual.
Soft Skills Communication skills (CS1, CS2, CS3)
Critical thinking and problem solving skills (CT1, CT2, CT3)
Team work skills (TS1,TS2)
Lifelong learning and information management (LL1, LL2)
Professional ethics and moral (EM1, EM2)
Leadership skills (LS1, LS2)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4283
Title
Research Project
Pre-requisite
KKEK 3171
Student Learning Time (SLT)
160 hours
Credit
4
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
Soft Skills
Carry out literature review on research topics related to
chemical engineering.
Establish a methodology to carry out experimental or
theoretical research.
Analyse experimental and theoretical data.
Write a scientific report.
Write a scientific article.
Communicate research findings by means of poster
presentation.
This course provides a comprehensive training to students in
conducting a research project, which includes performing a
critical literature review, formulating research questions,
establishing research methodology, writing and defending
research proposal, conducting experimental works, analyzing
experimental results, and presenting research outcome via
poster.
100 % Continuous Assessments
Research journals, patents, information on the internet and
reference books
Communication skills (CS1, CS2, CS3, CS4, CS5, CS6)
Critical thinking and problem solving skills (CT1, CT2, CT3, CT4)
Team work skills (TS1)
Lifelong learning and information management (LL1, LL2, LL3)
Entrepreneurial Skills (KK1)
Professional ethics and moral (EM1)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4301
Title
Air & Noise Pollution
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
6.
7.
Synopsis
Assessment
References
Historical perspective of air pollution. Types, sources and
effects/impacts of air pollutants. Monitoring and measurement
of air pollutants. Air meteorology and dispersion of air pollutants.
General air pollution control strategy. Types, sources and effects
of noise. Control of noise pollution.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
Soft Skills
Examine the issues which give rise to the air pollution
problems.
Describe the types, sources and effects of air pollutants.
Identify monitoring techniques and equipment for important
air pollutants.
Perform calculations for dispersion of air pollutants.
Propose appropriate control strategy for particulate and
gaseous air pollutants.
Identify types, sources and effects of noise pollution.
Suggest appropriate control strategy for noise pollution.
Boubel, R.W., Fox, D.L., Turner, D.B. and Stern,
A.C.,Fundamentals of Air Pollution, 3rd edition, 1994.
Academic Press, USA
De Nevers N., ‘Air Pollution Control Engineering’, 2ed. 2000.
McGraw-Hill, Singapore.
Davis, M.L. and Masten S.J.,Principles of Environmental
Engineering and Science, International Edition, 2004.
McGraw-Hill, Singapore
Communication skills (CS1, CS2, CS3, CS4)
Critical thinking and problem solving skills (CT1, CT2, CT3)
Team work skills (TS1, TS2)
Life long learning and information management (LL1, LL2)
Entrepreneurial skills (KK1)
Professional ethics and moral (EM1, EM2)
Leadership skills (LS1, LS2)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4304
Title
Process Integration
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
This course is focussed on the maximum energy recovery (MER)
from process streams (heat integration) using pinch technology.
The course contents include setting energy target, generating
composite curves and grand composite curves, problem table
algorithms and heat exchanger network with maximum energy
recovery (MER). In addition, the minimum number of the heat
exchanger units is determined using energy relaxation.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
Soft Skills
Explain the process integration pinch methods.
Build a problem table from flow sheet data.
Calculate pinch temperature and target minimum utilities
using problem table analysis and composite curve.
Plot Composite curve and Grant Composite curve.
Design heat exchanger networks for maximum energy
recovery including split streams.
Reduce the number of heat-exchanger unit using energy
relaxation.
Smith R.,1995,Chemical Process Design, McGraw Hill.
Shenoy U V, 1995, ‘Heat Exchanger Network Synthesis:
Process Optimisation by Energy and Resource Analysis’ Gulf
Professional Publishing.
User Guide on Process Integration for the Efficient Use of
Energy, IChemE (1982).
Article: Dunn R F, El-Hawagi M M, 2003,Process Integration
Technology Review: Background and applications in the
chemical process industry Journal of Chemical Technology &
Biotechnology 78 (9),
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3, CT4,
CT5)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4305
Title
Advanced Process Control
Pre-requisite
Student Learning Time (SLT)
KKEK 3154
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
The course will teach the theory and applications of various
advanced control strategies such as Adaptive control, Feed
forward control, Nonlinear control, Neural networks methods
and Fuzzy logic control for various chemical process systems.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
Soft Skills
Identify various advanced process control techniques.
Apply appropriate advanced process control techniques for
different types of chemical process and unit operations.
Apply artificial intelligence techniques for nonlinear system.
Evaluate the performance of these controllers in chemical
process systems.
Coughanowr and S. LeBlanc, Process Systems, analysis and
Control, McGraw-Hill, 3rd edition, 2008.
Stephanopoulos, Chemical Process Control, Prentice-Hall ,
1984.
D.Seborg et.al., Process Dynamics and Control, Wiley , 2nd
ed., 2007.
W. Bequette, process control : Modelling, design and
simulation, prentice-Hall, 2007.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3, CT4,
CT5)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4311
Title
Biochemical Engineering
Pre-requisite
KKEK 3151 Biochemistry
Student Learning Time (SLT)
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
This course introduces the fundamental principle of Biochemical
Engineering. The enzyme kinetics and the factors influencing of
the enzyme activities are emphasized and so are the immobilized
enzymes and the methods of immobilization. The course also
covers the growth kinetics and modelling of the growth system,
various operation modes of bioreactors, types of conventional
and novel bioreactors. Different methods of sterilization, kinetics
of thermal deactivation and design of heat sterilization cycle are
also included. A brief coverage on the dimensional analysis as
principle for scaling up is given before the course is extended to
the selection of suitable downstream processes and the
characterization of the fermentation products.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
5.
Soft Skills
Employ calculations for enzymatic reactions in biochemical
systems.
Employ calculations in bio-processing by applying the
chemical engineering approaches in nomenclature and
mathematical analysis.
Analyze growth kinetics based on structured models.
Discuss the importance of agitation and aeration to achieve
adequate mixing for the design of bioreactors.
Discuss different sterilization methods and their suitability in
bioprocesses.
Analyze bio-products and to select the suitable technique for
bio-separation.
J.M. Lee Biochemical Engineering, Prentice Hall, 1992.
M.L. Shuler and F. Kargi, Bioprocess Engineering: Basic
Concepts, Prentice Hall, 1992.
J. Bailey and D. Ollis, Biochemical Engineering
Fundamentals, 1986, McGraw Hill.
N. Blakebrough, Biochemical and Biological Engineering
Science, 1967, Academic Press.
M. J. Asenjo, J. Merchuk and M. Dekker, Bioreactor System
Design, 1995.
Communication skills (CS1, CS2, CS3)
Critical thinking and problem solving skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4316
Title
Solid Waste Management
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
6.
7.
Synopsis
Assessment
References
Soft Skills
Identify all the components of solid waste management.
Estimate quantity of generation and thermal, chemical, physical and
biological characteristics of a mixed municipal waste.
Demonstrate the ability to identify optimum process, methods
and/or systems for pre-treatment, storage, collection,
transportation and transferring solid waste for a given conditions
and location.
Choose the most appropriate resource recovery method for a given
case study.
Demonstrate the understanding on science, design, technology,
operation and environmental issues for incineration and land filling
processes.
Demonstrate the ability to analyze current issues on municipal solid
waste in Malaysia critically.
Evaluate business opportunities which are based on solid waste.
This course covers the essential principles entailed in the management
of societys waste. During the course, the source, composition,
properties and classifications of solid waste will be discussed along with
the evolution of solid waste management both in local and global
context. The principles related to evaluate equipment and facilities
options, make operational choices and to develop management systems
would also be taught. This covers equipment and facilities for pretreatment, waste storage, transport and transfer of solid waste.
Advanced principles related to the separation, processing, incineration,
landfilling and transformation technologies of solid waste through RDF,
biogas and compost generation would also be covered. Other advance
concepts such as waste minimization and zero emission will also be
discussed in the context of current waste issues.
40 % Continuous Assessments
60 % Final Examination
1.
George Tchobanoglous, Hilary Theisen and Samuel Vigil,
‘Integrated Solid Waste Management Engineering Principles and
Management Issues’ 1993, McGraw-Hill
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Communication skills (CS1, CS2, CS3, CS4, CS5)
Critical thinking and problem solving skills (CT1, CT2, CT3, CT4)
Team work skills (TS1, TS2, TS3)
Life long learning and information management (LL1, LL2)
Entrepreneurial Skill (KK1, KK2)
Professional ethics and moral (EM1, EM2)
Leadership skills (LS2, LS3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4318
Title
Waste water Treatment
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
Water quality, analysis and management. Treatment systems for
water, wastewater and sludge
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
5.
6.
Soft Skills
Explain what is meant by pollution of the aquatic
environment.
Explain the causes of pollution of the aquatic environment.
Perform calculations to obtain pollution indices.
Explain the principles of operation of the various water,
wastewater and sludge treatment systems.
Perform design calculations for sedimentation, flotation,
activated sludge system, trickling filter system and rotating
biological contactor.
Select an appropriate treatment system for water,
wastewater or sludge for given characteristics of the
pollutants.
Sundstrom, D.W. and Klei, H.E. (1979). Wastewater
Treatment, Prentice Hall, Inc., New Jersey.
Barnes, D., Bliss, P.J., Gould, B.W., and Valentine, H.R.
(1981). Water and Wastewater Engineering System, Pitman
Inter., Bath.
Benefield, L.D. and Randall, C.W. (1980) Biological Process
Design for Wastewater Treatment, Prentice-Hall, Englewood
Cliffs, New Jersey.
Metcalf and Eddy, Inc. revised by Tchobanoglous, G. (1979).
Wastewater Engineering treatment Disposal Reuse,
McGraw-Hill, New Delhi.
Clarke, J.W., Warren, Jr. V. and Hammer, M.J. (1977). Water
Supply and Pollution Control, 3rd Edition. Harper & Row,
New York.
El- Halwagi, M.M. (2003) .Pollution Prevention Through
Process Integration, Academic Press.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4322
Title
Adsorption in Porous Solids
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
This course give introduction to adsorption and different types of
pores, different types of isotherm curves and the mechanism
involved. Determination of micropore volume. Determination of
mesopore volume and meso pore volume distribution
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
Soft Skills
List the different types of isotherm and explain the shape of
the curves and the mechanism involved.
Describe the micro, meso and macropores.
Interpret the volume of the pores based on several
equations.
Evaluate effective teamwork practices.
Gregg S. J. and K. S. W. Sing Adsorption, surface area and
porosity, Academic Press New York 1982.
Jaroniec, M, Physical adsorption on heterogeneous solid.
Amsterdam. Elsevier 1988.
Duong D. Do. Adsorption analysis: Equilibria and kinetics.
London Imperial College press 1998.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4325
Title
Petroleum Engineering
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
6.
Synopsis
Assessment
References
Introduction to exploration and production (E&P) activities.
Phase rules and equilibrium concept. Flow regime. Petroleum
fluids.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
Soft Skills
Identify the exploration and production activities in
Malaysia.
Describe sedimentation process and the formation of
hydrocarbon from organic matter.
Describe classification of well, drilling rigs and drilling bottom
hole assembly.
Determine mud program to ensure safety drilling operation.
Determine different types of flow regime in the reservoir
Describe different types of reservoir fluids.
B. C. Craft & M. Hawkins, Applied Petroleum Reservoir
Engineering, 2nd ed., Prentice Hall PTR, 2001.
W. D. McCain, The Properties of Petroleum Fluids, 2nd ed.,
Pen Well, 2000.
R. Stoneley, An Introduction to Petroleum Exploration for
Non-Geologist, 2nd ed., Prentice Hall, 2005
C.H. Whitman & M.R. Brule, Phase Behavior, Monograph
Volume 20, SPE, 2000.
Critical Thinking and Problem Solving Skills (CT1, CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4327
Title
Advanced Process Safety and Loss Prevention
Pre-requisite
Student Learning Time (SLT)
None
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
6.
7.
Synopsis
Assessment
References
Safety and health management. Laws on safety and health: codes
and standards in loss prevention. Safety audit. Release mitigation
approaches. Pasquill-Gifford Model. Safe chemical handling.
Relief sizing. Design in preventing fire and explosion. Fire and
explosion hazards. Hazard to environment and its law –
assessment on environment and CIMAH regulations, Preventing
mechanical failures, Impact on economy from safety, health and
environmental aspects.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
5.
Soft Skills
Lay out good safety management system at workplace.
Conduct effective safety audit in an organisation.
Identify the appropriate valves to be used and location of
valves.
Decide on appropriate release mitigation techniques.
Apply Pasquill-Gifford Model to toxic release.
Determine ways of preventing mechanical failures.
Estimate impact on economy due to accidents.
Daniel, C. and Joseph, F.L.: Chemical Process Safety:
Fundamentals with Applications, Prentice-Hall, 2002.
Wentz, C.A.: Safety, Health and Environment Protection.
McGraw-Hill, 1999.
Safety and Loss Prevention Bulletin / Journal, 2007
Safety and Health Act – 514, 2008.
Phillon, B.S. Reliability, Quality and Safety for Engineers, CRC
Press, 2004.
Communication skills (CS1)
Critical thinking and problem solving skill (CT1, CT2, CT3)
Team work skills (TS1)
Life-long learning and information management (LL1)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4329
Title
Finite Element Method for Chemical Engineers
Pre-requisite
Student Learning Time (SLT)
KKEK2142, KKEK2156, KKEK3152, KXEX2245, KXEX3244
82 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
This course introduces the necessary background, i.e. Lagrange
interpolating polynomials as basis functions for expanding
quantities and coordinates, derivatives and integrals of quantities
so expanded, and tessellation of the computational domain.
Pertinent vector calculus, chemical engineering related governing
equations together with the initial and boundary conditions will
also be reviewed. FEM is treated as a variant of the method of
weighted residuals. The Galerkin weak form is the core of the
FEM, from which the elemental and global matrices arise. The
often non-linear set of equations is solved mainly with the
Newton-Raphson method. The details of the programming and
critical analysis of the results will be elaborated. Methods to
handle more advanced problems involving time dependence and
deformable domains conclude the course.
100 % Continuous Assessments
1.
2.
3.
Soft Skills
Explain the basic ideas and terminologies of FEM.
Transcribe governing equations (linear and non-linear) and
the initial value and boundary conditions into FEM
formulation.
Write computer programmes to solve single or multiple
variable problems in one or two dimensions.
Critically analyse the numerical results.
S.C. Chapra & R.P. Canale.Numerical Methods for Engineers,
McGraw-Hill. 6th Edition, 2010.
Reddy, J. N.,An Introduction to the Finite Element Method,
McGraw-Hill, 2nd. ed., 1993.
Burnett, D. S.,Finite Element Analysis: From Concepts to
Applications, Addison-Wesley Pub., 1987.
Critical thinking and ability to solve problems (CT1, CT2)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4330
Title
Advanced Fluidization Engineering
Pre-requisite
KKEK 3155 Particulate Technology
KKEK 3221 Reaction Engineering II
Student Learning Time (SLT)
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
Synopsis
Assessment
References
In the introductory part, this course briefly reviews the
fluidization phenomenon i.e. minimum, bubbling, slugging,
turbulent fluidizations etc. and the classification of Geldart
particles along with their behaviour. Distributor design and its
types will be covered in detail. The core of this course circulates
around bubbling fluidized bed reactor which includes bed
properties, effect of T & P along with flow models i.e. two phase
flow model, K-L model, entrainment and elutriation etc. The solid
movement (horizontal and vertical motions) that cause mixing,
segregation and different staging will also be covered. As the gas
solid reactions contribute a major role in the chemical industry
hence at different particle size ranges (fine, intermediate and
large etc.) these catalytic gas conversion models will be
elaborated. The designing of non-catalytic gas solid reactors
including uniform reaction model and shrinking core model will
conclude the course
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
5.
6.
Soft Skills
Design fluidized bed reactor distributor.
Estimate the bed properties using flow models e.g. two
phase flow and K-L model in bubbling fluidized bed.
Apply different reactor models for gas conversion in catalytic
reaction using different particle size ranges.
Design non-catalytic gas solid reactors involving models i.e.
uniform reaction model, shrinking core model etc.
Wen C. Y., Handbook of fluidization and fluid particle system
Taylor & Francis, 2003.
Gibilaro, L. G., "Fluidization Dynamics" Butterworth
Heinemann, 2001.
Kunii, D. and Levenspiel, O., "Fluidization Engineering",
Butterworth-Heinemann, 2nd ed., 1992.
Davidson, J. F., Clift, R. and Harrison, D., "Fluidization"
Academic Press, New York, 1985.
Howard, J. R., "Fluidized Bed Technology", Adam Hilger,
Bristol and New York, 1989.
Geldart, D., "Gas Fluidization Technology", John Wiley &
Sons, New York, 1986.
Critical thinking and problem solving skills (CT1 , CT2, CT3)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4331
Title
Industrial Emergency and Crisis Management
Pre-requisite
Student Learning Time (SLT)
Process Safety KKEK3161
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
Synopsis
Assessment
References
Industrial Emergency and Crisis Management
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
5.
Soft Skills
Select appropriate technical measures to prevent industrial
crisis
Estimate extent of industrial crisis scenarios by simulation
Develop an Emergency Response Plan (ERP) for chemical
process plants.
Introduction to Emergency Management, Third Edition,
Homeland Security Series, 2007.
Managing Crises Before They Happen: What Every Executive
Needs to Know About Crisis Management. Ian Mitroffand &
GusAnagnos, AMOCOM, New York, 2000.
Emergency Planning for Industrial Hazard, Gow & Kay,
Elsevier Applied Science, 2005
Emergency Response Planning, P. A. Erickson, Elsevier
Butterworth-Heinemann, Second Edition, 2006.
Principles of Emergency Managment and Emergency
Operations Centers, M.J. Fagel, CRC Press, Taylor & Francis
Group, 2011
Critical thinking and problem solving skills (CT, CT2, CT3)
Team Work Skills (TS1)
Life long learning and information management (LL1)
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4332
Title
Biofuel Process Technology
Pre-requisite
Student Learning Time (SLT)
KKEK1222, KKEK2220, and KKEK3159
80 hours
Credit
2
Learning Outcomes
1.
2.
3.
4.
5.
Synopsis
Assessment
References
The course introduce prior and current biofuel process
technology and discuss biofuels (biodiesel, bioethanol, biogases
and bio coal) as alternative fuels to replace fossil fuels in the
world market. The course will also cover biomass characteristics,
production processes, physical and chemical characteristics of
biofuels, process equipment, control system, instrumentation
and performance analysis of mechanical engines.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
Soft Skills
Identify biomass to produce biofuels and reliability of carbon
sources.
Describe biofuel processes and the formation of
hydrocarbons from biomass.
Describe chemical and biochemical processes for biofuel
production and classification of equipment for biofuel
production
Identify physical and chemical characteristics of biofuel.
Recognize appropriate process control and instrumentation
of biofuel production.
Dominik Rutz, Rainer Janssen (2001), Biofuel Technology
Handbook, WIP Renewable Energies. Munich, Germany
Caye Drapcho, John Nghiem, Terry Walker (2008), Biofuels
Engineering Process Technology , McGral-Hill.
Alain Vert, Nasib Qureshi, Hideaki Yukawa, Hans P. Blaschek
(2010), Biomass to Biofuels: Strategies for Global Industries,
John Wiley & Sons, United Kingdom.
Communication Skills
Critical thinking and problemn solving skills
Team work skills
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4333
Title
Membrane Technology and Processes
Pre-requisite
Student Learning Time (SLT)
Credit
Learning Outcomes
None
80 hours
2
1.
2.
3.
4.
Synopsis
Assessment
References
Expose students to the importance of membranes and
membrane separation processes in industrial applications. The
nature, principles and transport properties of each membrane
processes are demonstrated with the emphasis given on the
driving forces, thermodynamics and model transport through
porous and non-porous membranes. The course material is
innovative and gives the students a good advanced knowledge of
membrane technology as a separation and reaction tools in the
field of chemical engineering.
40 % Continuous Assessments
60 % Final Examination
1.
2.
3.
4.
Soft Skills
Describe the fundamental and principles of membrane
separation processes, membrane preparation,
characterization techniques and surface modification.
Identify various conventional and emerging membrane
separation
Determine mass transport properties in membrane
processes such as reverse osmosis and gas permeation
Solve engineering problems involving design of membranes
and membrane modules for specific applications.
Baker, R.; Membrane Technology and Applications, 3rd
Edition, Wiley, 2012.
Li, N.N., Fane, A.G., Ho, W.S.W. and Matsuura, T.; Advanced
Membrane Technology and Applications, Wiley-AIChE, 2008.
Drioli, E., Criscuoli, A. and Curcio, E.; Membrane Contactors:
Fundamentals, Applications and Potentialities, Elsevier,
2006.
Ramakrishna, S., Ma, Zuwei. and Matsuura, T.; Polymer
Membranes in Biotechnology, Imperial College Press, 2011
Critical thinking and problemn solving skills
Course Pro-forma
Bachelor of Engineering (Chemical)
Code
KKEK4334
Title
Application of Molecular Techniques in Activated Sludge
Processes
Pre-requisite
Student Learning Time (SLT)
Credit
Learning Outcomes
KKEK3151 Biochemistry
80 hours
2
1.
2.
3.
4.
Synopsis
Assessment
References
The course starts with an introduction to activated sludge
processes, with emphasis on the working principles and the
microorganisms involved. Then, the working principles of
molecular techniques are introduced to relate the application of
these techniques in monitoring the microbial structure in
wastewater treatment systems to the process performance.
Problems with traditional methods, and pros and cons of
molecular methods are highlighted. There are also laboratory
classes to provide students with basic practical skills in using
molecular techniques.
50 % Continuous Assessments
50 % Final Examination
1.
2.
3.
4.
Soft Skills
Describe important terms and concepts in activated sludge
processes and molecular biology.
Explain the microbiology in activated sludge plants and the
working principles of molecular techniques.
Relate the microbial community structure to the process
performance.
Perform basic molecular techniques for identification of
microorganisms.
Robert Seviour and Per H. Nielsen (editors). (2010) Microbial
Ecology of Activated Sludge. IWA Publishing.
Scragg A. (2005) Environmental Biotechnology. Oxford
University Press. 2nd edition.
Rittmann B.E.and McCarty P.L. (2001) Environmental
Biotechnology: Principles and Applications. McGraw Hill.
Selected journal articles.
Critical thinking and problemn solving skills