• Home
• Study
• Study Information
• Programmes
• Programme Information

Programme Specification for the 2025/6 academic year

BEng (Hons) Chemical Engineering

1. Programme Details

Programme name	BEng (Hons) Chemical Engineering	Programme code	UFN3ECSECS26
Study mode(s)		Academic year	2025/6
Campus(es)	Streatham (Exeter)	NQF Level of the Final Award	6 (Honours)

2. Description of the Programme

• One of the most multi-disciplinary areas of Engineering, Chemical Engineering is based on the processes of converting raw materials into useful products in a sustainable way.
• You will gain knowledge across all areas of Engineering and underpinning sciences to help you design these conversion processes to make them safe and effective, from bench-top to industrial scale.
• With sustainability in mind, you will learn from experts about clean energy generation and storage, waste reduction and water treatment, and smart coatings and nanotechnology.
• With our emphasis on project-based learning, you will develop a range of transferable skills to complement your core technical skills by taking part in exciting, hands-on group and individual projects.
• Your future career starts here, where you will gain the necessary technical and practical knowledge to work in a wide range of current and future industries, from food, drink and other consumer goods, through healthcare, towards clean energy.

3. Educational Aims of the Programme

This program aims to provide students with a comprehensive knowledge and understanding of general engineering and foundational sciences. It encourages critical thinking and develops key problem-solving skills using a systems approach and appropriate tools. Additionally, it fosters an appreciation for social, environmental, legal, ethical, safety, economic, and commercial issues. This broad sector approach equips students with the practical and professional skills necessary to assume key leadership roles within multidisciplinary teams, enabling them to address present and future challenges after graduation.

Students will gain a strong foundation in Chemical Engineering principles through lectures, with opportunities for practice and consolidation in tutorials and workshops. These sessions will cover fundamental concepts and principles, industrially relevant processes at different scales, and modelling and quantitative approaches. Industrially relevant examples of process and product technology will be provided, always with safety and sustainability in the forefront.

Hands-on practical sessions with small-scale equipment will enable students to understand theoretical concepts in practice. Through problem-based learning, students will learn how to apply Chemical Engineering knowledge in real-world scenarios. This will enable them to design complex processes involving multiple steps, equipment sizing, control and performance, and safety and loss prevention, all while dealing with strict technical and business requirements, often limited or uncertain.

Taught sessions are developed with accessibility in mind, embracing the ethos that everyone has different ways of learning and participating. This approach ensures that students of all talents can engage effectively and achieve strong academic outcomes.

4. Programme Structure

The BEng Chemical Engineering is a 3-year full-time programme of study at Regulated Qualifications Framework (RQF) level 6 (as confirmed against the FHEQ). This programme is divided into three stages. Each stage is normally equivalent to an academic year.

Interim / Exit Awards

With the requisite number of credits, a student may qualify for a Certificate of Higher Education or a Diploma of Higher Education.? 

Note: Guidance on Interim and Exit awards (and the difference between than can be viewed here: http://as.exeter.ac.uk/academic-policy-standards/tqa-manual/pma/introduction/#exit-interim

5. Programme Modules

The following tables describe the programme and constituent modules. Constituent modules may be updated, deleted or replaced as a consequence of the annual programme review of this programme.

Stage 1

---

120 credits of compulsory modules.

Compulsory Modules

Code	Module	Credits	Non-condonable?
ENG1002	Engineering Mathematics and Scientific Computing	30	Yes
ENG1005	Multi-Disciplinary Group Challenge Project	30	Yes
ENS1000	Fundamentals of Engineering	15	Yes
ENG1007	Fundamentals of Mechanics	15	Yes
ENG1008	Fundamentals of Materials	15	Yes
ENG1009	Fundamentals of Electronics	15	Yes

Stage 2

---

120 credits of compulsory modules.

Compulsory Modules

Code	Module	Credits	Non-condonable?
ENS2008	Chemical Engineering Challenge Project	30	Yes
ENS2003	Principles of Chemical Engineering	15	Yes
ENS2009	Reaction and Reactor Engineering 1	15	Yes
ENG2007	Introduction to Fluid Dynamics	15	Yes
ENG2009	Modelling of Engineering Systems	15	Yes
ENG3016	Thermodynamics and Heat Transfer	15	Yes

Stage 3

---

120 credits of compulsory modules.

Compulsory Modules

Code	Module	Credits	Non-condonable?
ENS3006	Chemical Engineering Design: 1 - Research	15	Yes
ENS3007	Chemical Engineering Design: 2 - Development	15	Yes
ENS3019	ENS3019 Reaction and Reactor Engineering 2	15	No
ENS3020	Energy Storage	15	No
ENS3021	Separation Processes and Particle Technology 1	15	No
ENS3022	Separation Processes and Particle Technology 2	15	No
ENS3023	Transport Phenomena	15	No
ENG3005	Fluid Dynamics and CFD	15	No

---

6. Programme Outcomes Linked to Teaching, Learning and Assessment Methods

Intended Learning Outcomes
A: Specialised Subject Skills and Knowledge

Intended Learning Outcomes (ILOs) On successfully completing this programme you will be able to:	Intended Learning Outcomes (ILOs) will be...
	...accommodated and facilitated by the following learning and teaching activities (in/out of class):	...and evidenced by the following assessment methods:
1. Have a knowledge and understanding of mathematical and computational modelling and apply them to problems related to Chemical Engineering. 2. Have a knowledge and understanding of science and associated engineering disciplines and apply them to problems related to Chemical Engineering. That should include relevant scientific principles (physics, chemistry, biochemistry, biology and materials science).	A variety of teaching methods will be used to deliver the programme, with sessions ranging from lectures, tutorials, laboratory and workshop practical sessions, problem-based and computer-aided learning. External contributions, including from Industry, are also included in the final years, alongside project supervision.	A variety of assessment methods aligned with the intended learning outcomes are used throughout the programme in the form of, for example, written examination papers and marked coursework (e.g. problem sheets, laboratory reports, computer exercises, group or individual reports and presentations with visual aids). Where possible, group assessments will have an individual component. All assessments will be based on clearly stated criteria, with a robust quality assurance process to ensure consistency and fairness in outcomes, and safeguards against academic misconduct.

Intended Learning Outcomes
B: Academic Discipline Core Skills and Knowledge

Intended Learning Outcomes (ILOs) On successfully completing this programme you will be able to:	Intended Learning Outcomes (ILOs) will be...
	...accommodated and facilitated by the following learning and teaching activities (in/out of class):	...and evidenced by the following assessment methods:
1. The learning outcomes listed here are based on the IChemE accreditation guide. 3. Foundation and Core Chemical Engineering Principles, including: 3.1. Fundamentals: materials and energy balances, momentum, heat and mass transfer, thermodynamics and transport properties, and reaction/reactor engineering. 3.2. Mathematical modelling and quantitative methods, including commercial software, to solve chemical engineering problems. 3.3. Process and product technology: unit operations, separation and particle technology, equipment sizing and processing steps. 3.4. Systems: batch and continuous operation, interdependence, multi-step processes and system dynamics. 3.5. Process safety: identify and prevent hazards, risk assessment and specialist aspects of safety and environment. 4. Foundation and Core Chemical Engineering Practice, namely the context of engineering processes, relevant legal requirements, codes of practice and quality assurance, and laboratory practice (from bench to plant). 5. Foundation and Core (and Advanced for M-level) Chemical Engineering Design, in an integrated approach, from business requirements to technical requirements and sustainability.	See above.	See above.

Intended Learning Outcomes
C: Personal/Transferable/Employment Skills and Knowledge

Intended Learning Outcomes (ILOs) On successfully completing this programme you will be able to:	Intended Learning Outcomes (ILOs) will be...
	...accommodated and facilitated by the following learning and teaching activities (in/out of class):	...and evidenced by the following assessment methods:
6. Understand the need for high ethical and professional standards and how they are applied, including an inclusive approach to engineering practice, an effective ethics culture, and safety, health and environment. 7. Work in a team and recognise the importance of project planning, time management, and leadership skills, being able to reflect on their work and implement strategies for personal improvement and professional development. 8. Communicate effectively and present outcomes clearly, including written reports and presentations.	See above.	See above.

7. Programme Regulations

Classification

Full details of assessment regulations for all taught programmes can be found in the TQA Manual, specifically in the Credit and Qualifications Framework, and the Assessment, Progression and Awarding: Taught Programmes Handbook. Additional information, including Generic Marking Criteria, can be found in the Learning and Teaching Support Handbook.

8. College Support for Students and Students' Learning

In accordance with University policy, a system of Academic Tutors and a Pastoral Mentor is in place for all students on this programme. A University-wide statement on such provision is included in the University's TQA Manual. As a student enrolled on this programme, you will receive the personal and academic support of the Programme Coordinator and will have regular scheduled meetings with your Academic Tutor. You may request additional meetings as and when required. The role of personal tutors is to provide you with advice and support for the duration of the programme and extends to providing you with details of how to obtain support and guidance on personal difficulties such as accommodation, financial difficulties and sickness. The departmental Pastoral Mentor is also there to help you and refer you to specialist support. You can also make an appointment to see individual teaching staff.

Online Module study resources provide materials for modules that you are registered for on the Exeter Learning Environment (ELE). Coursework is also submitted through ELE, with marks and feedback available through the system as well. Each module page is linked to the Library, with easy access to reading lists. Our Library is a digital-first library, with most items accessible online, and an Engineering-specific subject guide and liaison librarian.

Information Technology (IT) Services provide a wide range of services throughout the Exeter campuses including open access computer rooms, some of which are available 24 hours, 7 days a week. Help may be obtained through the Helpdesk, and most study rooms in halls and flats are linked to the University's campus network. Additionally, the University has its own dedicated IT support staff, helpdesk and computer facilities which are linked to the wider network, but which also provide access to some specialised software packages. Email is an important channel of communication between staff and students in the Faculty and an extensive range of web-based information is available.

9. University Support for Students and Students' Learning

Please refer to the University Academic Policy and Standards guidelines regarding support for students and students' learning.

10. Admissions Criteria

Undergraduate applicants must satisfy the Undergraduate Admissions Policy of the University of Exeter.

Postgraduate applicants must satisfy the Postgraduate Admissions Policy of the University of Exeter.

Specific requirements required to enrol on this programme are available at the respective Undergraduate or Postgraduate Study Site webpages.

11. Regulation of Assessment and Academic Standards

Each academic programme in the University is subject to an agreed College assessment and marking strategy, underpinned by institution-wide assessment procedures.

The security of assessment and academic standards is further supported through the appointment of External Examiners for each programme. External Examiners have access to draft papers, course work and examination scripts. They are required to attend the Board of Examiners and to provide an annual report. Annual External Examiner reports are monitored at both College and University level. Their responsibilities are described in the University's code of practice. See the University's TQA Manual for details.

(Quality Review Framework.

14. Awarding Institution

University of Exeter

15. Lead College / Teaching Institution

Faculty of Environment, Science and Economy (ESE)

16. Partner College / Institution

Partner College(s)

Not applicable to this programme

Partner Institution

Not applicable to this programme.

17. Programme Accredited / Validated by

Not applicable to this programme.

18. Final Award

BEng (Hons) Chemical Engineering

19. UCAS Code

H114

20. NQF Level of Final Award

6 (Honours)

21. Credit

CATS credits	360	ECTS credits	180

22. QAA Subject Benchmarking Group

Level 1

23. Dates

Origin Date	26/09/2024	Date of last revision	02/10/2024