Minerals, Materials and Recycling (CHEN90010)

Graduate courseworkPoints: 12.5On Campus (Parkville)

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Overview

Availability
Semester 2
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AIMS

The importance of the minerals industry to the Australian economy. Liberation, size reduction, size separation and concentration separations in minerals processing. Extractive metallurgy, including hydrometallurgy and pyrometallurgy. Aspects of physico-chemical principles of mineral separation processes to produce metals and ceramic products from ores as well as recycled materials and consumer products. The influence of interatomic bonding and material atomic structure on material behaviour. Phase diagrams and equilibria as well as material mechanical, electrical and magnetic properties will be covered. The process of developing material selection criteria and selecting materials for particular applications will be presented. The systems approach to recycling of products, process sustainability and environmental considerations.

 

INDICATIVE CONTENT

Understand: why recycling makes sense; mineral processing separation concepts; processing-structure-property relationships; atomic bonding and atomic scale structure in materials; thermodynamic basis for phase equilibria; influence of material properties on recyclability; influence of recycling on material purity and properties.

Know how to design mineral separation processes; use phase diagrams; derive a number of material properties based upon atomic bonding and atomic scale structure.

Be familiar with: similarities and differences in mineral processing and recycling; equipment used in size reduction and separation and concentration separations; extractive metallurgy; typical minerals processing and metals production processes; typical properties of metals, polymers, ceramics and semiconductors; influence of materials on society; influence of microstructure on material properties; mechanical, electrical, magnetic, optical and thermal properties of materials; typical material processing; be able to select materials for particular applications.

Intended learning outcomes

INTENDED LEARNING OUTCOMES (ILO)


On completion of this subject the student is expected to:




  • Understand the complex interaction of processes within the material cycle i.e. starting with primary material production from minerals, material production and properties, consumer products and ending with recycled material, waste and environmental issues. This will be based on material science principles, thermodynamics, system engineering and optimization
  • The students will understand the relationships between materials composition, processing, microstructure and properties
  • The students will be able to select materials for particular engineering design applications

Generic skills

  • Capacity for independent thought
  • Awareness of advanced technologies in the discipline
  • Ability to apply knowledge of basic science and engineering fundamentals
  • Ability to undertake problem identification, formulation and solution
  • Ability to utilise a systems approach to design and operational performance

Last updated: 3 November 2022

Eligibility and requirements

Prerequisites

Admission into MC-ENG Master of Engineering (Chemical) or MC-ENG Master of Engineering (Chemical with Business) or MC-ENG Master of Engineering (Biochemical)

 

OR

 

 

All other MC-ENG Master of Engineering students may seek approval from their Course Coordinator and the Subject Coordinator to take this subject

 

Corequisites

None

Non-allowed subjects

CHEN40011 Minerals, Materials and Recycling

Code Name Teaching period Credit Points
CHEN90035 Advanced Topics in Chemical Engineering
Summer Term (On Campus - Parkville)
 12.5

Inherent requirements (core participation requirements)

The University of Melbourne is committed to providing students with reasonable adjustments to assessment and participation under the Disability Standards for Education (2005), and the Assessment and Results Policy (MPF1326). Students are expected to meet the core participation requirements for their course. These can be viewed under Entry and Participation Requirements for the course outlines in the Handbook.

Further details on how to seek academic adjustments can be found on the Student Equity and Disability Support website: http://services.unimelb.edu.au/student-equity/home

Last updated: 3 November 2022

Assessment

Additional details

  • Continuous assessment comprising regular assignments, requiring approximately 35 - 40 hours of work in total (30%)
  • One written 3-hour end-of-semester examination (70%).

Intended Learning Outcomes (ILOs) 1 - 3 are addressed in the examination and the regular assignments.

Last updated: 3 November 2022

Dates & times

  • Semester 2
    Principal coordinatorGeorge Franks
    Mode of deliveryOn Campus (Parkville)
    Contact hours2 x 2 hour lectures per week
    Total time commitment200 hours
    Teaching period24 July 2017 to 22 October 2017
    Last self-enrol date 4 August 2017
    Census date31 August 2017
    Last date to withdraw without fail22 September 2017
    Assessment period ends17 November 2017

    Semester 2 contact information

    Prof George Franks

    Email: gvfranks@unimelb.edu.au

Time commitment details

Estimated 200 hours

Last updated: 3 November 2022

Further information

  • Texts

    Prescribed texts

    None

  • Subject notes

    LEARNING AND TEACHING METHODS

    Lectures, homework assignments, worked examples case studies and guest lectures.

     

    INDICATIVE KEY LEARNING RESOURCES

    Comprehensive Lecture Notes are provided on LMS for the Students. Materials for the lecture notes are taken from the following list of sources which is provided to the students.

    MINERALS

    • Introduction to Mineral Processing, Kelly, E. G., and Spottiswood, D. J., 1995.Australian Mineral Foundation, (K&S)
    • Mineral Processing Technology, 6th Edition, Wills, B. A., 1997. Butterworth Heinemann, (Wills)

    METALS PRODUCTION

    • Principles of Extractive Metallurgy, F. Habashi, Gordon and Breach, 2nd ed., Vols 1-3, 1980. (Habashi).
    • Process Principles in Minerals & Materials Production, P. Hayes, Hayes Publishing, Brisbane, 1993. (Hayes).
    • Extraction Metallurgy, 3rd ed., J. D. Gilchrist, Pergamon Press, 1989. (Gilchrist)
    • Extractive Metallurgy of Copper, W. G. Davenport, M. King, M. Schlesinger, A. K. Biswas, 4th ed., Pergamon, 2002. (DKSB)


    MATERIALS

    • Materials Science and Engineering an Introduction, Callister, W. D. Jr.
    • Sixth Edition, John Wiley and Sons, 2003. (Call)
    • The Principals of Engineering Materials, Barrett, C. R., Nix, W. D., and Tetelman, A.S., Prentice Hall, 1973. (BNT).
    • Introduction to Engineering Materials, Second Edition, John, V. B., Macmillan Press, 1983. (John).
    • Principles of Materials Science and Engineering, 3rd edition, Smith, W. F., McGraw Hill, NY, 1996. (Smith)
    • Materials Selection in Mechanical Design, Ashby, M. F., Permagon Press 1992 and 1999. (Ashby).
    • Engineering Materials 1, 3rd edition, and Engineering Materials 2, Ashby, M. F. and Jones , D. R. H., Elsevier, 2005., Butterworth-Heinemann, (A&J)
    • MIT OpenCourseWare, Materials Science and Engineering Department, http://ocw.mit.edu/OcwWeb/index.htm (MIT)
    • Elements of Materials Science and Engineering, 3rd Edition, Van Vlack, L. H., 1975., Addison-Wesley, Reading, MA, (Van Vlack)
    • Introduction to Ceramics, 2nd Edition, Kingery, W. D., Bowen, H. K., Uhlmann, D. R., 1976. John Wiley and Sons, NY, (KBU)
    • Materials Science for Engineers, 5th edition, Anderson, J. C., Leaver, K. D., Leevers, P., Rawlings, R. D., 2003., Nelson Thornes, Ltd. London, (ALLR)
    • Coulson and Richardson’s Chemical Engineering, Volume 6, Third Edition, R. K. Sinnot, R. K., 1999, Butterworth-Heinemann, (C&R).
    • Introduction to Dislocations, 2nd edition, D. Hull, Pergamon Press, Oxford, 1975, (Hull)
    • Materials Science and Engineering, G. F. Carter and D. E. Paul, 1991. ASM International, (C&P)
    • Physical Chemistry, 7th Edition, P. Atkins and J. de Paula, Oxford Univ. press, 2002. (Atkins)

     

    RECYCLING

    • The Metrics of Material and Metal Ecology, Reuter, M. A., Heiskanen, K., Boin, U., van Schaik, A., Verhoef, E. yang, Y., Georgalli, G., Elsevier, 2005. (Reuter)

     

    CAREERS / INDUSTRY LINKS

    The recycling component of the subject, (lectures and a case study) is taught by an engineer from industry. There are also typically 2 or 3 other guest lecturers (1 to 2 hours) from industry as well.

  • Related Handbook entries

    This subject contributes to the following:

    TypeName
    CourseDoctor of Philosophy - Engineering
    CourseMaster of Philosophy - Engineering
    CoursePh.D.- Engineering
    Specialisation (formal)Chemical with Business
    Specialisation (formal)Chemical
    Informal specialisationMaster of Engineering (Chemical)
    Informal specialisationMaster of Engineering (Biochemical)
    Specialisation (formal)Biochemical
    Informal specialisationMaster of Engineering (Chemical with Business)
  • Available through the Community Access Program

    About the Community Access Program (CAP)

    This subject is available through the Community Access Program (also called Single Subject Studies) which allows you to enrol in single subjects offered by the University of Melbourne, without the commitment required to complete a whole degree.

    Please note Single Subject Studies via Community Access Program is not available to student visa holders or applicants

    Entry requirements including prerequisites may apply. Please refer to the CAP applications page for further information.

    Additional information for this subject

    Subject coordinator approval required

Last updated: 3 November 2022