Course syllabus

Course-PM

MPM052 Composite and nanocomposite materials lp1 HT19 (7.5 hp)

The course is offered by the Department of Industrial and Materials Science

Contact details

Course purpose

All three classes of composite materials are included in the course: polymeric matrix composites (PMC), as well as metallic and ceramic matrix composites (MMC and CMC), though the main focus is on PMC. Dominantly, conventional (that is using micro size reinforcement) composites are discussed. Nanocomposites (that is using nanosized reinforcement) are included in the course but to a lesser extent because the industry is mainly using conventional composites. Nevertheless, nanocomposites are making great research and growing engineering impacts, following science and development in the field of nanoparticles.

This is an advanced level course designed for MSc and PhD students as well as for professionals in the industry. The aims are three-fold to provide: (i) materials and basic mechanics understandings of composites and nanocomposites, (ii) theories and practical aspects of composites towards research and engineering, (iii) overall strategies, updates, impacts and challenges in the field of composites.

There are many applications and great expectations connected to composites, among others in the automotive, aerospace, civil engineering, and electronics industries.

Goals

After reading this course you should be able to: understand structure-properties relations particularly with respect to their mechanical performances; overview the field of composites, handle applications and judge the materials according to various criteria. Thus you should be able to:

  • apply/inform/describe methods, updates, impacts and challenges in the field of composites

  • synthesize/explain from constituents through structure through interactions through processing to properties to performance to applications

  • apply your so-far knowledge of physics, materials and mechanics, and new knowledge of types of fillers/fibres and matrices, and interactions between them, towards improved, high-quality materials and their performances. This is necessary toward cost/profile analysis in your future job.

  • apply specific knowledge acquired through studying course parts A-G to prepare your own application (problem-based learning, PBL).

  • implement micromechanics and macro-mechanics approaches and develop your own computer code based on MATLAB for calculating laminates

  • independently form issues, conclude/judge/compare; thus imparting more increased complexity in the analysis of composites.

    Course evaluation

    From 1 January 2012, the Student – och utbildningsavdelningen administrative unit at Chalmers is responsible for the support to course evaluation for the advanced level courses. Within the support, where among others the Educational Secretary (Johan Bankel, johan.bankel@chalmers.se) is included, procedures have been developed to elect student representatives to the course board. Also, dates for course board meetings will be set, and course questionnaires will be delivered.

    Lecturers are responsible for:

  • informing about course evaluation in the introduction of the course and in kurs-PM (course information), and to

    introducing student representatives

  • calling two course board meetings (1 & 2) - notes from meeting two will be published on the course homepage

  • presenting a view on the course at the course board meeting

  • improving the course before the course next run (say, before the next academic year)

  • adding items to the course questionnaire.

Content

The course consists of seven parts (A-G)

  • A Introduction

  • B Reinforcements & matrices

  • C Manufacturing

  • D Elastic & hygrothermal properties

  • E The interface region

  • F Performance

  • G Polymer nanocomposites

The frameworks of materials science and engineering, mechanics of heterogeneous materials, as well as manufacturing techniques are used in the course to study the chain: manufacturing-structure-performances in service. Particular attention is given to the near-fibre region (interphase) as the reinforcement-matrix interaction is of crucial importance for composites. Manufacturing is necessarily included as designing with composites is strictly related to manufacturing. Important performances: stiffness, strength, fracture, toughness, fatigue, creep, damping, and lightweight performance. Although the course is predominantly a materials course, some aspects of design are included. A project is included in the course, where project teams will be formed to advance an application of composites, first of all by applying course knowledge and widened with literature knowledge.

To summarize, this course goes some distance in building a complete knowledge of these important materials.

A recommended course helping you to read the present one is Polymer processing and properties (MTT090), although a fundamental course in polymeric materials is a possible alternative. 

Schedule

TimeEdit

Course literature

Compendium Composite and nanocomposite materials, Ed. 6, 2012 compiled in the Department of Materials and Manufacturing Technology, Chalmers. The compendium includes PMCs, CMCs and MMCs.

Tutorials

Tutorials timetable is included in the table above. Selected problems in composite materials will be solved. Some solutions are given in the compendium. All solutions will be posted on the course homepage after each tutorial.

Course design

    • Learning objectives and syllabus

Learning objectives:

  • Structure of the area of composites.
  • Handle applications and judge composites according to various criteria.
  • Apply/inform/describe methods, updates, impacts, and challenges in the field of composites.
  • Synthesize/explain from constituents through structure through interactions through processing to properties to performance to applications.
  • Apply knowledge of physics, materials and mechanics, and new knowledge of types of fillers/fibres and matrices, and interactions between them, towards improved, high-quality materials and their performances. This is necessary toward cost/profile analysis in your future job.
  • Apply knowledge acquired through studying course parts A-G to prepare your own application (problem-based learning, PBL).
  • Implement micromechanics and macro-mechanics approaches and develop your own computer code based on MATLAB for calculating laminates independently form issues.
  • Conclude/judge/compare the more increased complexity in the analysis of composites.

Link to the syllabus on Studieportalen.

Study plan

 

TIMETABLE

MPM052_2019 Timetable.png

Tutorial/consultation time with the examiner: every Monday 12-14 and anytime by mail to giadal@chalmer.se

 

Examination form

COMPULSORY ACTIVITIES

There are three compulsory activities in the course:

  • Mat-lab

  • project

  • examination

 

Mat-LAB

Lab Instruction Sheet for Laminate Theory will be handed out. The lab consists of two parts: computation (carried out in the computer room) and experiment (result handed out). In the preparation stage, you need to acquaint yourself with the laminate theory and train indicated typical calculations. Solutions to problems D12 needs to be handed to the lab instructors before the lab – in order to be admitted to the lab. During the lab, laminate equations will be implemented and solved using MATLAB, and the obtained result will be compared with an experimental result. For lab dates - see the timetable.

Approval of the lab: you will prepare a group report and submit it to the lab instructors Angelica avella@chalmers.se and Ezgi ezgic@chalmers.se. You need to actively take part in the lab work and in preparation of lab report. A group lab report needs to be approved.

PROJECT: WRITTEN REPORT AND PRESENTATION

Project-based learning (PBL) is included in the course in the form of a Project. It constitutes about 10% of the course. Points earned (max. 10 p) will be added to exam points. Why Project? Nowadays, through the professional career of engineers and scientists, working both in industry and academia as well as other fields, preparing reports and presentations for different target audiences is a significant part of one’s work routine. Thus, the project has two parts: (i) a written report and (ii) a presentation of the project.

The project will be carried out in teams of a maximum of five students.

You will deal with an application of nanocomposites and document your findings (the report).

In the end, you will prepare a team presentation which will be graded.

All members of the team will receive the same amount of points.

The project constitutes about 10% of the course. Points earned (max. 10 p) will be added to exam points.

Project topics: any applications of nanocomposites PMCs, (or combinations of PMCs and MMCs or CMCs) you are interested to find out more about (including all the part of the course A-G), compared to a current one. Guidelines and examples will be given in the introductory lessons.

Form a team, make your choice of project topic and register the application and team members with Giada (giadal@chalmers.se) by Friday, 13/9.

EXAMINATION

A written examination (in English) will take place at the end of the quarter, Johanneberg Campus. If the need arises, a re-sit (re-examination, omtenta) will take place in January, also Johanneberg Campus. Exam paper can include questions from parts A to G, each question carrying a given amount of points in proportion to the number of lecture hours. The maximum amount of points is 100: 90 p (max.) from the written examination + 10 p (max.) from the project. The following materials are allowed during the examination: approved type of calculator (Casio Fx82, Texas TI30, Sharp ELW531), standard mathematical tables, for example, Beta, dictionary.

Missed deadlines and revisions will be are handled by approval of the examiner.

TO PASS THE EXAM YOU NEED:

  • Pass the examination with min 40p (project points not included)

  • The project needs to gain at least 5 out of 10 points.

  • Lab report needs to be approved.

    The final grade is based on the overall result, meaning if passed the examination will be complemented by the project points. Preliminary grading is: 40-59 p for grade 3, 60-79 p for grade 4, and at least 80 p for grade 5.

    WELCOME TO THE COURSE AND GOOD LUCK!

Course summary:

Date Details Due