Postgraduate Programme and Module Handbook 2020-2021 (archived)
Module ENGI44B10: Non-Linear Solid Mechanics 4
Department: Engineering
ENGI44B10:
Non-Linear Solid Mechanics 4
Type |
Tied |
Level |
4 |
Credits |
10 |
Availability |
Available in 2020/21 |
Module Cap |
None. |
Prerequisites
- <If other modules, please enter module code using 'Right Click, Insert module_code' or enter module title>
Corequisites
- As specified in programme regulations.
Excluded Combination of Modules
- As specified in programme regulations.
Aims
- This module is designed solely for students studying Department of Engineering degree programmes.
- To provide an overview of non-linear solid mechanics problems.
- To develop advanced knowledge and understanding of problems involved material and geometric non-linearity and contact and friction.
- This module will allow graduates to develop skills in solving non-linear problems using numerical and analytical techniques.
Content
- Fundamentals of large deformation mechanics and plasticity theory.
- Integration of elasto-plastic constitutive models.
- Non-linear finite element solution methods.
- Analytical solutions to contact problems.
- Numerical treatment of contact problems.
- Fundamentals of frictional and lubrication.
Learning Outcomes
- An appreciation of the limitations on linear finite-element analysis and an understanding of the consequences of including geometric and material non-linearity.
- An understanding of the fundamental components of finite deformation mechanics and elasto-plasticity.
- An understanding of the fundamental concepts of contact analysis and the critical ability to select an appropriate numerical tool to tackle a specific contact problem.
- An appreciation of the techniques used in, and the structure of, non-linear finite-element analysis software.
- An awareness of current technology, analysis methods and industrial practises along with the ability to apply those methods in novel situations.
- An in-depth knowledge and understanding of specialised and advanced technical and professional skills, an ability to perform critical assessment and review and an ability to communicate the results of their own work effectively.
- Capacity for independent self-learning within the bounds of professional practice.
- Highly specialised numerical skills appropriate to an engineer.
- Mathematics relevant to the application of advanced engineering concepts.
Modes of Teaching, Learning and Assessment and how these contribute to
the learning outcomes of the module
- The module content is delivered in lectures and is reinforced by problem sheets, worked examples and short MATLAB scripts, equipping students with the required problem solving capability.
- Students are able to make use of staff 'Tutorial Hours' to discuss any aspect of the module with teaching staff on a one-to-one basis. These are sign up sessions available for up to one hour per week per lecture course.
- A single examination covers all of the lecture material. Written timed examinations are appropriate because of the wide range of analytical, in-depth material covered in this module and allow students to demonstrate the ability to solve advanced problems independently.
Teaching Methods and Learning Hours
Activity |
Number |
Frequency |
Duration |
Total/Hours |
|
Lectures |
20 |
Typically 1 per week |
1 Hour |
20 |
|
Tutorial Hours |
As required |
Weekly sign-up sessions |
Up to 1 Hour |
10 |
|
Preparation and Reading |
|
|
|
70 |
|
Total |
|
|
|
100 |
|
Summative Assessment
Component: Examination |
Component Weighting: 100% |
Element |
Length / duration |
Element Weighting |
Resit Opportunity |
Written Examination |
2 hours |
100% |
|
N/A
■ Attendance at all activities marked with this symbol will be monitored. Students who fail to attend these activities, or to complete the summative or formative assessment specified above, will be subject to the procedures defined in the University's General Regulation V, and may be required to leave the University