Programme Specification
MEng (Hons) Mechanical Engineering (Students undertaking Part D in 2018)
Academic Year: 2018/19
This specification provides a concise summary of the main features of the programme and the learning outcomes that a typical student might reasonably be expected to achieve and demonstrate if full advantage is taken of the learning opportunities that are provided.
This specification applies to delivery of the programme in the Academic Year indicated above. Prospective students reviewing this information for a later year of study should be aware that these details are subject to change as outlined in our .
This specification should be read in conjunction with:
- Reg. XX (Undergraduate Awards) (see
- Module Specifications
- Summary
- Aims
- Learning outcomes
- Structure
- Progression & weighting
Programme summary
Awarding body/institution | 天堂视频 |
Teaching institution (if different) | |
Owning school/department | Wolfson School of Mechanical, Electrical and Manufacturing Engineering |
Details of accreditation by a professional/statutory body | Institution of Engineering and Technology (IET) Institution of Mechanical Engineers (IMechE) |
Final award | MEng / MEng+DIS / MEng+DPS / MEng+DInts |
Programme title | Mechanical Engineering |
Programme code | WSUM03 |
Length of programme | The duration of the programme is either 8 semesters, or 10 semesters if the students undertake the additional period of study normally between Parts B and C for the award of the Diploma of Industrial Studies, the Diploma of International Studies or the Diploma of Professional Studies. |
UCAS code | H302, H303 |
Admissions criteria | MEng - MEng+DIS /DInts - |
Date at which the programme specification was published | Wed, 29 Aug 2018 11:02:13 BST |
1. Programme Aims
Aims:
- To prepare highly skilled graduates to pursue careers in Mechanical Engineering across a range of industries and activities including design, development, and analysis of complex systems
- To provide as high-quality learning experience across a complete range of core subjects in order to give students the necessary technical skills to understand mechanical systems and solve engineering problems
- To promote high-quality engineering practice by applying appropriate knowledge, skills, tools and techniques in the analysis, diagnosis and solution of industry-related problems.
- To develop engineers capable of designing systems and managing the development process in order to deliver solutions that meet the requirements of customers
- To impart an appreciation of the essential practical and commercial, ethical, business, sustainability and legal constraints of professional engineering
- To support personal and professional development and foster creativity, develop design capability and teach the communication skills necessary to put ideas into practice
2. Relevant subject benchmark statements and other external reference points used to inform programme outcomes:
- UK Quality Assurance Agency for Higher Education (QAA) – ‘Subject Benchmark Statement for Engineering’, (Feb.2015)
-
Engineering Council (UK). ‘UK-SPEC, UK Standard for Professional Engineering Competence’, 3rd Edition, Jan 2014
-
Engineering Council (UK). ‘The Accreditation of Higher Education Programmes’, 3rd Edition, May 2014
3. Programme Learning Outcomes
3.1 Knowledge and Understanding
On successful completion of this programme, students should be able to demonstrate knowledge and understanding of:
- The underpinning scientific, mathematical and engineering principles associated with mechanical engineering;
- The characteristics of engineering materials, equipment and processes and an awareness of basis mechanical workshop practices;
- Engineering principles, quantitative methods, mathematical and computer models;
- Relevant codes of practice and regulatory framework and operational practices for safe operation of engineering processes;
- Recognise the professional and ethic responsibilities of engineers;
- Principles of industrial design, engineering design and manufacturing design;
- Management techniques and an understanding of the commercial and economical context of the engineering business.
- Developing technologies in areas of specialization and understanding of concepts from areas peripheral to mechanical engineering, including a thorough appreciation of microprocessors and machine control software.
3.2 Skills and other attributes
a. Subject-specific cognitive skills:
On successful completion of this programme, students should be able to:
- Apply the principles of engineering science in developing solutions to practical mechanical engineering problems;
- Create new engineering components and processes through the synthesis of ideas from a range of sources using appropriate design principles, techniques and codes of practice;
- Integrate, evaluate and make use of information and data from a wide variety of sources including other engineering disciplines;
- Generate innovative designs by evaluating and responding to customer needs, including fitness for purpose and cost;
- Analyse complex mechanical systems, processes and components;
- Investigate and define engineering problems within the framework of economic, social, ethical and environmental issues and show the ability to assess risk;
- Investigate new and emerging technologies using fundamental knowledge and learn new theories, concepts and methods in an familiar situations.
b. Subject-specific practical skills:
On successful completion of this programme, students should be able to:
- Apply computer-based and mathematical methods to the modelling and analysis of engineering system, components and products;
- Define and solve practical engineering problems;
- Use laboratory and basis workshop equipment in an appropriate and safe manner;
- Generate ideas for new products and develop and evaluate a range of new solutions;
- Gather and interpret information and evaluate designs;
- Demonstrate the ability to manage the design process and apply appropriate techniques and codes of practice to the design of components and systems;
- Prepare mechanical engineering drawings, computer-graphics and technical reports and give technically competent oral presentations;
- Apply relevant codes of practice and industry standards;
- Demonstrate the ability to work with technical uncertainty;
- Demonstrate high levels of organizational and project management skills.
c. Key transferable skills:
On successful completion of this programme, students should be able to:
- Demonstrate a high level of numeracy;
- Search and retrieve information, ideas and data from a variety of sources;
- Adopt systematic approach to the solution of unfamiliar problems;
- Select and analyse appropriate evidence and data to solve problems;
- Solve problems applying engineering techniques and tools;
- Communicate effectively by means of technical reports, papers, graphical aids, interpersonal and presentational skills;
- Design and implement basic computer based information systems;
- Organise and manage time and resources effectively: develop work plans, take responsibility for their execution;
- Undertake most of the technical roles within a team and exercise leadership;
- Plan self-learning and improve performance, as the foundation for lifelong learning.
4. Programme structure
4.1 Part A - Introductory Modules
Code | Title | Weight | Semester | C/O |
MAA310 | Mathematics for Mechanical Engineering | 20 | 1+2 | C |
MMA101 | Statics and Dynamics | 20 | 1+2 | C |
MMA508 | Engineering Principles & Professional Skills | 20 | 1+2 | C |
MMA604 | Materials & Manufacturing Processes | 20 | 1+2 | C |
MMA800 | Thermodynamics and Fluid Mechanics | 20 | 1+2 | C |
MMA901 | Electronic Systems for Mechanical Processes | 10 | 1 | C |
MMA100 | Mechanics of Materials | 10 | 2 | C |
4.2 Part B - Degree Modules
Code | Title | Weight | Semester | C/O |
MMB300 | Engineering Computation | 10 | 1+2 | C |
MMB500 | Application of Engineering Design: Industry Based Project | 10 | 1+2 | C |
MAB110 | Mathematics for Mechanical Engineering | 10 | 1 | C |
MMB100 | Mechanics of Materials 2 | 10 | 1 | C |
MMB101 | Engineering Dynamics 2 | 10 | 1 | C |
MMB104 | Control Engineering | 10 | 1 | C |
MMB800 | Thermodynamics 2 | 10 | 1 | C |
ELB045 | Electrical Power & Machines | 10 | 2 | C |
MMB403 | Design of Machine Elements | 10 | 2 | C |
MMB404 | Computer Aided Design, Manufacture and Test (CADMAT) | 10 | 2 | C |
MMB801 | Heat Transfer | 10 | 2 | C |
MMB802 | Fluid Mechanics | 10 | 2 | C |
4.3 Part I – Optional Placement Year
Code | Title |
WSI010 | DIS Industrial Placement (non-credit bearing) |
WSI020 | DPS Industrial Placement (non-credit bearing) |
WSI035 | DIntS Industrial Placement (non-credit bearing) |
In order to be considered for the award of DIS or DPS students will need to complete a minimum of 45 weeks in an approved placement and meet the specified report submission for the award. In order to be considered for the award if DIntS students will need to complete 45 weeks approved overseas placement. This may be industrial or academic study or a combination of the two. Students should note that consideration of these awards is only on successful completion of their degree programme.
4.4 Part C - Degree Modules
Students MUST choose 20 credits of options (O) in Semester One and 30 credits in Semester Two.
TWO modules (20 credits) must be selected from Group A or Group B (both from the same group), OR ONE module from Group A or B and ONE module from Group C.
ONE module (10 credits) must be selected from each of Group D, E and F. Modules in Group D and E are paired with modules in Part D.
Code | Title | Weight | Semester | C/O |
MMD550 | Individual Project | 50 | 1+2 | C |
MMC200 | Engineering Management: Finance, Law and Quality | 10 | 1 | C |
MMC900 | Computer Control & Instrumentation | 10 | 1 | C |
MMC801 | Advanced Heat Transfer | 10 | 1 | OA |
MMC804 | Energy Systems Analysis | 10 | 1 | OA |
MMC901 | Laser Materials Processing | 10 | 1 | OA |
MMC104 | Robotics and Control | 10 | 1 | OB |
MMC107 | Contacts Mechanics: Tribology | 10 | 1 | OB |
MMC901 | Digital Image Processing | 10 | 1 | OB |
LAN*** | University Wide Language | 10 | 1 | OC |
MMC101 | Vibration and Noise | 10 | 2 | OD (1a) |
MMC105 | Kinematics of Machinery | 10 | 2 | OD (1b) |
MMC106 | Finite Element Analysis | 10 | 2 | OE (1c) |
MMC802 | Computation Fluid Dynamics | 10 | 2 | OE (1d) |
MPC012 | Polymer Engineering - Processing & Manufacture | 10 | 2 | OE (1e) |
MMC301 | Computer Aided Engineering | 10 | 2 | OF |
MMC803 | Ballistics and Rocket Propulsion | 10 | 2 | OF |
MPC014 | Materials in Service | 10 | 2 | OF |
MPC102 | Fracture and Failure | 10 | 2 | OF |
LAN*** | University Wide Language | 10 | 2 | OF |
4.5 Part D - Degree Modules
Students must choose 40 credits of optional modules (O) in Semester One and 40 credits in Semester Two.
ONE module (10 credits) must be from Group A. TWO modules (20 credits) must be from Group B. Modules in Group B are linked to modules in Part C.
ONE module (10 credits) must be from Group C.
Students cannot register for modules already studied in Part C.
Code | Title | Weight | Semester | C/O |
WSD403 | Engineering Design Management | 10 | 1 | C |
WSD503 | Project Engineering | 30 | 1+2 | C |
BSD523 | Enterprise Technology | 10 | 1 | OA |
WSD500 | Project Leadership | 10 | 1 | OA |
WSD217 | Teamwork and Leadership | 10 | 2 | OA |
WSD100 | StructualIntegrity | 10 | 1 | OB (2c) |
WSD102 | Non-Linear Dynamics | 10 | 1 | OB (2a) |
WSD105 | Dynamics of Engineering | 10 | 1 | OB (2b) |
WSD802 | Computational Fluid Dynamics 2 | 10 | 1 | OB (2d) |
MPD014 | Polymer Engineering 2: Properties | 10 | 1 | OB (2e) |
WSC602 | Sustainable Manufacturing | 10 | 1 | OC |
WSC606 | Additive Manufacturing for Product Development | 10 | 1 | OC |
WSD552 | Advanced Engineering Research | 20 | 1+2 | OC |
WSD900 | Mechatronics | 20 | 1+2 | OC |
LAN*** | University Wide Lanaguage (Level 3 and above) | 10 | 1 | OC |
WSC301 | Computer Aided Engineering | 10 | 2 | OD |
WSC800 | Internal Combustion Engines | 20 | 2 | OD |
WSC803 | Ballistics and Rocket Propulsion | 10 | 2 | OD |
WSC610 | Healthcare Engineering | 10 | 2 | OE |
WSC700 | Sports Engineering | 10 | 2 | OE |
WSD101 | Drive Train Dynamics | 10 | 2 | OE |
WSD902 | Laser & Optical Measurements | 20 | 2 | OE |
WSD407 | Sustainable Product Design | 10 | 2 | OF |
WSD606 | Additive Manufacturing and Reverse Engineering | 10 | 2 | OF |
LAN*** | University Wide Language (Level 3 and above) | 10 | 2 | OG |
All optional module choice is subject to availability, timetabling, student number restrictions and students having taken appropriate pre-requisite modules.
4.6 Mechanical Engineering M.Eng (Manufacturing Stream)
MEng Mechanical Engineering students who opted to follow the Manufacturing Stream in Part C, will select modules from Part D of the Product Design Engineering Programme.
4.7 Studies Overseas
Students may choose to study Semester 1 (only) during their Part D, at an approved Overseas Higher Education Institution. The mix of subjects of the learning programme must first be approved by the programme director for their course. An acceptable learning programme should, where possible, include a group project and studies at an advanced/masters level.
5. Criteria for Progression and Degree Award
5.1 Criteria for Progression and Degree Award
Progression from Part A to Part B, from Part B to Part C and from Part C to Part D will be subject to the provisions set out in Regulation XX and in addition candidates must accumulate 120 credits and achieve an overall average of 55% in each part.
5.1.2 For candidates who commenced study on the programme before September 2014 who fail to satisfy the progression requirements stated in paragraphs 5.1.1 above, the requirements are:
In order to progress from Part A to Part B, from Part B to Part C and from Part C to Part D and to be eligible for the award of an Honours degree, candidates must not only satisfy the minimum credit requirements set out in regulations XX but also:
i. In order to proceed from Part A to Part B, from Part B to Part C and from Part C to Part D, candidates must obtain at least 50% in modules with a minimum weight of 100 credits in each programme part and gain credit (40%) in all other modules.
ii. In order to be eligible for the award of an Honours degree, candidates must obtain a mark of 50% in Project Engineering module WSD503 in Part D.
5.2 Criteria for candidates who do not meet the requirements for progression or the award of a Degree.
Any candidate who fails to achieve the criteria for progression from Part A to Part B, Part B to Part C and from Part C to Part D shall have the opportunity to repeat Module Assessments in accordance with the provisions of Regulation XX. Alternatively, the candidate may elect to enter the B.Eng degree programme in Mechanical Engineering, before commencing Part C, provided that the candidate has satisfied the criteria for progression for that programme at the appropriate point.
In exceptional circumstances, any candidate who, having successfully completed Part C, is unable to commence or complete Part D or fails to achieve the criteria necessary for the award of the degree of M.Eng may, at the discretion of the Programme Board, be awarded the degree of B.Eng in Mechanical Engineering with a classification corresponding to the candidate’s achievements in the Part B and Part C assessments and determined on the basis of the weightings given for the B.Eng programme.
6. Relative Weighting of Parts of the Programme for the Purposes of Final Degree Classification
Candidates’ final degree classification will be determined on the basis of their performance in degree level modules assessments in Parts B, C and D in accordance with the scheme set out in Regulation XX. The average percentage marks will be combined in the ratio Part B - 20, Part C - 40, Part D – 40 to determine the overall average percentage mark for the programme (the programme mark).