Fundamentals of Mechanics and Materials

Module title	Fundamentals of Mechanics and Materials
Module code	INT1116
Academic year	2025/6
Credits	15
Module staff	Andrew Mackenzie Robertson (Convenor)

Duration: Term	1	2	3
Duration: Weeks		11

Number students taking module (anticipated)	35

Module description

This module follows on from the Core Engineering module and introduces further concepts of Mechanics and Materials in preparation for year 2 of your degree. In this module we focus on classical mechanics, including fluid statics and dynamics, and materials, including two sub-disciplines, material science and material engineering.

You will work through new topics each week with the aid of extensive learning materials, lectures, tutorials and experimental activities. You will undertake numerous elements of online continuous assessment throughout the module which will allow you to evaluate your understanding of the material and diagnose areas that require further attention. Continuous assessments provide ongoing feedback and support you to actively manage your learning.

Module aims - intentions of the module

This module aims to equip you with fundamental knowledge and skills in Mechanics and Materials. It also consolidates a common knowledge base and begins the development of a learning methodology appropriate to a professional engineer. Through both continuous assessment and the end of year exams, the module encourages you to actively manage your own learning and seeks to develop your ability to communicate your understanding of engineering theory and concepts in a professional manner.

Programmes that are accredited by the Engineering Council are required to meet Accreditation of Higher Education Programmes (AHEP4) Learning Outcomes.

The following Engineering Council AHEP4 Learning Outcomes are covered on this module (shown in brackets):

Intended Learning Outcomes (ILOs)

ILO: Module-specific skills

On successfully completing the module you will be able to...

1. ILO 19 & 37 - Apply a comprehensive knowledge of mathematics and engineering principles to the solution of complex problems (B1, C1, M1)
2. ILO 20 & 38 - Formulate and analyse complex problems to reach substantiated conclusions (B2, C2, M2)
3. ILO 3, 21 & 39 - Select and apply appropriate computational and analytical techniques to model complex problems (B3, C3, M3)

ILO: Discipline-specific skills

On successfully completing the module you will be able to...

4. ILO 22 & 40 - Select and critically evaluate technical literature and other sources of information to solve complex problems (B2, C2, M2)
5. ILO 30 & 48 - Use practical laboratory and workshop skills to investigate complex problems (B12, C12, M12)
6. ILO 13, 31 & 49 - Select and apply appropriate materials, equipment, engineering technologies and processes, recognising their limitations (M13)

ILO: Personal and key skills

On successfully completing the module you will be able to...

7. ILO 17 - Communicate effectively on complex engineering matters with technical and non-technical audiences

Syllabus plan

Hydrostatics

Pressure and head

Forces on submerged bodies and buoyancy

Introduction to Dynamics

Straight line and curvilinear motion

Force, mass and acceleration

Momentum and energy methods

Hydrodynamics

Fluid Flow and Types

Flow Continuity and Momentum Equations

Energy Equation

Applications of Energy Equation

Measurement Techniques

Dimensional analysis

Material Failure

Failure types

Stress intensity factor

Role of cracks

Fracture toughness

Application of fracture toughness in engineering design

Creep and stress relaxation

Fatigue

Modern Materials and Manufacturing Methods

Learning activities and teaching methods (given in hours of study time)

Scheduled Learning and Teaching Activities	Guided independent study	Placement / study abroad
65	85

Details of learning activities and teaching methods

Category	Hours of study time	Description
Scheduled Learning and Teaching activities	31	Mechanics lessons
Scheduled Learning and Teaching activities	30	Materials lessons
Scheduled Learning and Teaching activities	4	Laboratory sessions to develop practical skills and awareness of practical application of the subject material.
Guided independent study	85	Directed reading, assigned problems and web-based activities on ELE will develop learning at a pace appropriate for the individual student.

Formative assessment

Form of assessment	Size of the assessment (eg length / duration)	ILOs assessed	Feedback method
Question sets in tutorial sessions	Various	1-6	Verbal in tutorial

Summative assessment (% of credit)

Coursework	Written exams	Practical exams
40	60

Details of summative assessment

Form of assessment	% of credit	Size of the assessment (eg length / duration)	ILOs assessed	Feedback method
Mechanics Exam	30	2 hours	1-2	Cohort level feedback. Individual students can request feedback after exam
Materials Exam	30	2 hours	1-2, 6	Cohort level feedback. Individual students can request feedback after exam
Coursework Mechanics continuous assessment worksheets	10	8 hours (typically 2 worksheets)	1-2	Online assessment with immediate feedback
Coursework Materials continuous assessment worksheets	10	8 hours (typically 2 worksheets)	1-2, 6	Online assessment with immediate feedback
Coursework Truss analysis Lab Report	10	8 hours	4-5	Marked coursework returned with feedback
Coursework Fluid dynamics experiment and lab report	10	8 hours	3, 5-7	Marked coursework returned with feedback

Details of re-assessment (where required by referral or deferral)

Original form of assessment	Form of re-assessment	ILOs re-assessed	Timescale for re-assessment
Coursework	Coursework (see details of summative assessment)	same as above	Next assessment period
N/A	Exam (referral)	All	Next assessment period

Re-assessment notes

Deferral – if you miss an assessment for reasons judged legitimate by the Mitigation Committee, the applicable assessment will normally be deferred. See ‘Details of reassessment’ for the form that assessment usually takes. When deferral occurs there is ordinarily no change to the overall weighting of that assessment.

Referral – if you have failed the module overall (i.e. a final overall module mark of less than 40%) you will be required to take a referral exam. Only your performance in this exam will count towards your final module grade. A grade of 40% will be awarded if the examination is passed.

Indicative learning resources - Basic reading

Basic reading:

Author	Title	Edition	Publisher	Year	ISBN
Callister, WD	Materials Science and Engineering: an introduction	8th	John Wiley & Sons	2007	978-0470505861
Ashby & Jones	Engineering Materials 1 : an introduction to their properties, applications and design	Electronic	Elsevier	2012	0750663812
Bedford A & Fowler W	Engineering Mechanics - Statics & Dynamics Principles		Prentice-Hall	2003	9780130082091
Callister, WD	Engineering Mechanics Statics		Pearson	2017	978-1-292-08923-2
Callister, WD	Engineering Mechanics Dynamics		Pearson	2017	978-1-292-08923-2
Nelson, E W et al	Schaum's outlines Engineering Mechanics Statics		Mc Graw Hill	2010	978-0071632379
Nelson, E W et al	Schaum's outlines Engineering Mechanics Dynamics		MC Graw Hill	2011	978-0071632379

Web-based and electronic resources:

ELE – https://ele.exeter.ac.uk

Indicative learning resources - Web based and electronic resources

Web-based and electronic resources:

ELE – https://vle.exeter.ac.uk/course/view.php?id=13164

Key words search

Shear force and bending moments; fluid statics and dynamics; torsion; materials; stress; strain; elasticity; plastic material; material; failure; construction materials; steel; reinforced concrete

Credit value	15
Module ECTS	7.5
Module pre-requisites	INT1115
Module co-requisites	None
NQF level (module)	4
Available as distance learning?	Yes
Origin date	06/07/2021
Last revision date	05/06/2025