ENCH394-21S2 (C) Semester Two 2021

Process Engineering Design 2

15 points

Details:
Start Date: Monday, 19 July 2021
End Date: Sunday, 14 November 2021
Withdrawal Dates
Last Day to withdraw from this course:
  • Without financial penalty (full fee refund): Sunday, 1 August 2021
  • Without academic penalty (including no fee refund): Friday, 1 October 2021

Description

This course introduces students to key concepts of process design, including the detailed design of unit operations. The course builds on the topics covered in the 1st Professional year and begins to explores how unit operations can interact to shift the overall optimal operating conditions away from, say, the conditions that optimise a reactor alone. The course also extends the process safety concepts introduced in ENCH295 to cover more quantitative analysis techniques and provides an introduction to materials engineering for chemical engineers.

This course provides an introduction to process design. The course introduces the Douglas hierarchical design philosophy and the use of process simulators to aid in process design. The course builds on the material taught throughout the 2nd year, especially the concepts of material and energy balances. Here these concepts are extended to the design of more complex processes. The design of specific unit operations is introduced by providing a detailed introduction to heat exchanger design. The course also builds on the process safety material taught in ENCH295 to look at consequence modelling and techniques for risk reduction in process safety. An introduction to engineering materials for chemical engineers is also provided to guide students to select proper materials for their process design and future applications.

Course Content
• Introduction to Process Design (Daniel Holland, 4 lectures, 1 assignment)
• Process Safety (consequence modelling, risk reduction and legal framework) (Rachael Wood, 9 lectures, 1 test)
• Heat Exchanger Design (Heon Park, 6 lectures, 1 assignment)
• UNISIM Software Package Training (Daniel Holland, 3 computer lab tutorials, 1 assignment)
• Introduction to Engineering Materials (Heon Park, 15 lectures, 1 computer lab tutorial, 2 quizzes, 1 exam

Learning Outcomes

  • Knowledge outcomes
  • Understand and be capable of applying energy and material balance analysis in process engineering.
  • Rapidly analyse the economics of potential processes for the production of chemicals.
  • Optimise processes using process modelling software.
  • Design heat exchangers for process applications.
  • Evaluate safety of proposed processes.
  • Design systems to reduce the risk in industrial processes.
  • Understand how microstructure influences material properties.
  • Classify materials based on measured properties.
  • Identify suitable materials for process applications.

    Transferable skills
  • Team working and interpersonal relation.
  • Time management.
  • Handling stress during treating with real world problems.
  • Communication of complex idea to peers.
  • Simple economic analysis.
  • Approaching problems rationally.

Prerequisites

Timetable Note

35 Lectures and 3 computer labs during normal lecture time
CONTRIBUTION TO ACCREDITATION REQUIREMENTS
This course contributes to the following Institute of Professional Engineers New Zealand (IPENZ) graduate profiles
2. Formulate and solve models that predict the behaviour of part or all of complex engineering systems, using first principles of the fundamental engineering sciences and mathematics;
3. Synthesise and demonstrate the efficacy of solutions to part or all of complex engineering problems;
4. Recognise when further information is needed and be able to find it by identifying, evaluating and drawing conclusions from all pertinent sources of information, and by designing and carrying out experiments;
5. Understand the accepted methods of dealing with uncertainty (such as safety factors) and the limitations of the applicability of methods of design and analysis and identify, evaluate and manage the physical risks in complex engineering problems;
6. Function effectively in a team by working co-operatively with the capacity to become a leader or manager;
7. Communicate effectively, comprehending and writing effective reports and design documentation, summarising information, making effective oral presentations and giving and receiving clear oral instructions;
8. Understand the role of engineers and their responsibility to society by demonstrating an understanding of the general responsibilities of a professional engineer;
10. Demonstrate competence in the practical art of engineering in their area of specialisation by showing in design an understanding of the practical methods for the construction and maintenance of engineering products, and using modern calculation and design tools competently for complex engineering problems.

This course contributes to the following Institute of Chemical Engineers, UK (IChemE)
Chemical engineering learning outcomes
Core Chemical Engineering: “Systems” (3)
Design (4)
Social, environmental and economic context MEng (3)
Development and applications of skills – increased skills (both subject-specific skills and transferable skills), normally acquired through enhanced and extended project work;

Students questions by e-mail will be replied in two working days.

Course Coordinator

Heon Park

Lecturers

Daniel Holland and Rachael Wood

CONTRIBUTION TO ACCREDITATION REQUIREMENTS
This course contributes to the following Institute of Professional Engineers New Zealand (IPENZ) graduate profiles
2. Formulate and solve models that predict the behaviour of part or all of complex engineering systems, using first principles of the fundamental engineering sciences and mathematics;
3. Synthesise and demonstrate the efficacy of solutions to part or all of complex engineering problems;
4. Recognise when further information is needed and be able to find it by identifying, evaluating and drawing conclusions from all pertinent sources of information, and by designing and carrying out experiments;
5. Understand the accepted methods of dealing with uncertainty (such as safety factors) and the limitations of the applicability of methods of design and analysis and identify, evaluate and manage the physical risks in complex engineering problems;
6. Function effectively in a team by working co-operatively with the capacity to become a leader or manager;
7. Communicate effectively, comprehending and writing effective reports and design documentation, summarising information, making effective oral presentations and giving and receiving clear oral instructions;
8. Understand the role of engineers and their responsibility to society by demonstrating an understanding of the general responsibilities of a professional engineer;
10. Demonstrate competence in the practical art of engineering in their area of specialisation by showing in design an understanding of the practical methods for the construction and maintenance of engineering products, and using modern calculation and design tools competently for complex engineering problems.

This course contributes to the following Institute of Chemical Engineers, UK (IChemE)
Chemical engineering learning outcomes
Core Chemical Engineering: “Systems” (3)
Design (4)
Social, environmental and economic context MEng (3)
Development and applications of skills – increased skills (both subject-specific skills and transferable skills), normally acquired through enhanced and extended project work;

Assessment

Course Policies on Collaboration and Cheating:
Solving problems in small teams and collaborative learning when working on assignments is encouraged.  However direct copying will result in reduced or zero marks for all students involved.  The assignments are mainly a tool to prepare you for the exams. We advise you to try them individually before collaborating in groups.

Laboratories:
There are computer-based labs and tutorials will be provided. Assessments will be given with problems which need to utilise the computer software.

Wrong units or missing units in answers unless these are dimensionless:
Zero point will be given to the problem

Marked assignments will be released before study break for exam

Textbooks / Resources

Recommended Reading

Douglas, James M; Conceptual design of chemical processes ;

Felder, Richard M. , Rousseau, Ronald W; Elementary principles of chemical processes ; 3rd;

G.T. Murray; Handbook of materials selection for engineering applications ;

Himmelblau, David Mautner; Basic principles and calculations in chemical engineering ; 5th;

M.F. Ashby; Materials selection in mechanical design ; 3rd;

Basic principles and calculations in chemical engineering by D.M. Himmelblau, 5th ed.
Conceptual design of chemical processes by J.M. Douglas
Elementary principles of chemical processes by R.M. Felder, R.W. Rousseau, 3rd ed.
Handbook of materials selection for engineering applications by G.T. Murray
Materials selection in mechanical design by M.F. Ashby 3rd ed.

Notes

Concerns
Students may obtain the general policies of the University from the website. For example:

Special considerations: http://www.canterbury.ac.nz/study/special-consideration/  

Academic Appeals of Assessments: Students with concerns about course teaching, assessment processes, or grades should speak first with the relevant lecturer or the course coordinator. If the matter cannot be resolved, then the student can meet the 3rd year Director. If the matter still cannot be resolved, the student can discuss the matter with the Head of Department and thereafter follow the procedures outlined in the University procedures http://www.canterbury.ac.nz/media/documents/postgraduate-/Academic-Appeals-Grievances-Principles-Procedures.pdf  and regulations https://www.canterbury.ac.nz/regulations/general-regulations/academic-appeals-and-grievances/

Reconsideration of grades: If you are concerned that your final grade may be incorrect, it is suggested (for CAPE) that you make an informal query to the course coordinator, but you may follow the official procedures: http://www.canterbury.ac.nz/study/examinations/result-dates-and-appeals/

Disabilities: http://www.canterbury.ac.nz/disability/

Relation to Other Courses
This course builds on the concepts introduced throughout the 2nd Year. It serves as preparation for final-year design, ENCH494.

Course Requirements:
Submission of all assignments, test, and exam is mandatory to pass this course.

Students Contributions:
Students are expected to study on this course at least 10 hours per each week. Lectures provide only the skeleton of the materials to be learned. Once each lecture is taught, students should study and review by themselves to achieve learning outcomes by utilising all methods and resources. Students are also expected to source materials for their study.

Additional Course Outline Information

Academic integrity

Course Policies on Collaboration and Cheating
Solving problems in small teams and collaborative learning when working on assignments is encouraged.  However, partial or full,  direct copying sources from peer or literature will result in zero mark for the assignment. Students, who provided or shared their findings (raw data, solutions, etc.), will fail this course.
The assignments are mainly a tool to prepare students for more complex problems. We advise you to try them individually before collaborating in groups.

General Policies of the Department
Students may obtain the general policies of the University on matters such as special consideration applications, appeal procedures, reconsideration of grades and special provision for students with disabilities from the University Calendar

Assessment and grading system

Assignments, Test, and Exam
• Process design assignment (due 11 August 2021) 20%
• Safety test (19 August 2021) 20%
• Heat exchanger design assignment (due 20 September 2021) 15%
• Process simulation assignment (due 29 September 2021)  15%
• Materials Quiz (due 4 October 2021) 2.5%
• Materials Quiz (due 15 October 2021) 2.5%
• Exam (Materials) 25%

Grade
All assessment marks might be scaled to ensure that a reasonable range of grades is obtained when the University Grading Scale (https://www.canterbury.ac.nz/study/grading-scale/) is applied.
Students should not rely on their raw marks to estimate the final grade.
At least 40% of the total mark of the exam and a lowest grade of C- are required to pass this course.

Attendance

Students' attendance is not mandatory but highly encouraged.
Lectures will be video-recorded, and the videos will be available up to two weeks from the lecture time. However, the technical quality of the videos will be not guaranteed. Thus, students are highly suggested to attend all the lectures.
A hard copy or electronic version of lecture notes or slides may not be released prior to each lecture, and thus students should try to take their own notes during or/and after each lecture.

Late submission of work

Late submissions will lose 10% grade per day overdue

Requests for extensions

To be submitted to the lecturer or course coordinator, or see Department policy on Special Consideration

Resubmissions

To be submitted to the lecturer course coordinator

Where to submit and collect work

CAPE reception, 4th Floor Link building, or to LEARN (as directed)

Indicative Fees

Domestic fee $986.00

International fee $5,500.00

* All fees are inclusive of NZ GST or any equivalent overseas tax, and do not include any programme level discount or additional course-related expenses.

For further information see Chemical and Process Engineering .

All ENCH394 Occurrences

  • ENCH394-21S2 (C) Semester Two 2021
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