Aviation Business Enterprise
In a nutshell
Demand for air travel is predicted to increase and there are exciting technological advancements in flight. With the aviation industry in need of talented aircraft engineers with excellent technical knowledge and strong business acumen, start a high-flying career with a degree in aircraft engineering with pilot studies.
Salford is a regional UK centre for aeronautics study and research. Providing a gateway to professional status, our popular aircraft engineering course is professionally accredited by the Royal Aeronautical Society (RAeS) and Institution of Mechanical Engineers (IMechE), so you'll be educated to the highest industry standards.
The course combines practical and theoretical aspects of flight, with the underlying principles of aircraft engineering. Delivered over four years – or five with an industry placement year - you’ll study a suite of modules designed to embed theoretical knowledge and creative application and help you become a world-class aircraft engineer.
With our MEng integrated masters pathway, you'll advance to explore how you can enhance flight performance, as you develop flight assimilation and air navigation skills.
- Study the essential elements of aircraft design and complete experiments and project work in specialised aeronautical laboratories
- Specialise in propulsion, computational fluid dynamics, aerodynamics, materials and structures
- Experience a flight test project at Cranfield University’s National Flying Laboratory Centre
- Choose to include an optional structured pilot training programme leading to the opportunity to gain a Private Pilot Licence
- Take an industry placement year to increase your professional aviation and aeronautics skills
This is for you if...
You're fascinated by the opportunities in engineering and want a degree with professional status
You're excited by aircrafts and flight and desire a future career in this field
You're a keen problem-solver who enjoyed mathematics or physics at school/college
All about the course
Having the ability to apply technical detail is at the heart of engineering, and core to Salford’s values. We strive to embed this as a core learning objective throughout your studies. Aircraft Engineering with Pilot Studies combines mathematics, science, computer-based methods, design and engineering to solve complex aircraft engineering problems. As you gain theoretical knowledge and develop creative thinking, you'll build industry-ready practical skills.
In year one, you’ll follow a range of modules designed to enhance your core engineering knowledge and introduce aeronautics. As you progress into year two, you’ll explore specialist aviation modules, such as aircraft structures, flight systems, aerodynamics, flight simulation, route planning and navigation systems.
As you head into year three, you'll cover advanced modules including avionics and aircraft system design. You'll complete experiments and project work, culminating in your individual final year project. In your final year, you will take your studies to postgraduate level, completing modules in engineering computation, aerospace system design and aerodynamics.
Prior to the final year, you'll have the opportunity to experience a flight test course delivered at Cranfield University’s National Flying Laboratory Centre using specially instrumented Jetstream 31 aircraft. During the flight, the aircraft will conduct specific manoeuvres during which flight data is gathered for later analysis.
You can also choose to include an optional structured pilot training programme to gain a Private Pilot Licence. A total of 45 flying hours are offered within the training programme by external partners at an additional cost.
Industry placements are a great opportunity to get some hands-on experience and make career connections. On this course, you'll have the option to take an industry placement between years two and three. Although you’ll be responsible for securing your placement, our tutors will support you, monitor your progress and assess your final placement report. By successfully completing a placement year, you can also add 'with professional experience' to your final degree award.
This is your introduction to the history of air transport systems leading to the current state of the aviation business.
You will study topics such as the:
- Evolution of surface transportation systems – roadways, railways and waterways
- Beginnings of air transport – first generation airships and winged flying machines
- Development of technologies relating to improvements in civilian and military aircraft designs
- Passenger facility enhancements such as in-flight catering, conveniences and entertainment
- Birth of the modern airliner leading to the demise of the airships and the ocean liners.
Engineering Materials and Electrical Systems
You will develop an understanding of the basic properties and applications of materials and of the principles of electronic and electrical engineering. This will include learning about the relationship between the micro-structure and mechanical properties of materials, mechanisms of corrosion and corrosion protection, the principles of electronic and electrical engineering, and the response of electrical elements in circuits to AC or DC supplies.
You will build on the engineering mathematics module from your first year by developing advanced knowledge and skills in mathematical analysis. This will enable you to tackle more advanced engineering problems. Subjects covered include partial differentiation, determinants and matrices, vector analysis, Laplace transforms and functions of a complex variable.
Engineering Structures and Engineering Dynamics
This module will develop your knowledge and understanding of the basic principles of structural behaviour and the nature of stress and strain and provide you with a foundation in engineering dynamics, allowing you to tackle simple engineering problems, and preparing you for subsequent modules.
Project Management Aerofluid Mechanics
This module will introduce you to project management techniques, particularly in the areas of project planning, organisation and control. You will develop an understanding of project timings and resource allocation and a broad understanding of quantitative methods used for decision-making in industry. You will gain an understanding of the basic engineering principles that underpin the design of propulsion systems for the aerospace industry and have an introduction to the principles of gas turbine theory and jet engines. The module also covers the principles of aerodynamics for a range of flight conditions and consolidates a good understanding of flight manoeuvres and design aspects with case studies.
Principles of Air Navigation and Meteorology for Aviation
In this module you will gain proficiency and knowledge in the planning of multiple leg flight plans and build awareness and experience of aviation meteorology. On completion you should have developed skills including practical knowledge of operational procedures; requirements for safe and adequate flight planning; understanding requirements for time planning; the principles of aviation meteorology; and be able to make rational assessments for flight safety by interpreting synoptic weather forecasts.
Engineering Mathematics (year 2)
Develop more advanced knowledge and skills in mathematical analysis relevant to engineering applications. Gain the confidence to apply your skills to tackle advanced engineering challenges.
Safety Assessment in Aviation and Human Factors and Crew Resource Management
The aims of this module is for you to, develop an in depth knowledge of aviation safety issues, use and evaluate analysis so you can anticipate and alleviate safety risks in aviation and to develop an understanding of Human Factors and CRM to optimise capability to operate in a safe and efficient aviation environment.
Flight Systems (Year 2)
You'll learn the basic principles and theory of statics and dynamics as related to the static and dynamic behaviour of an aircraft and the theory of flight control as related to the dynamic behaviour of an aircraft.
Route Planning and Navigation Systems
This module will introduce the theory of business economics in route planning. You will learn the techniques and methodologies used for navigating an aircraft using modern navigation aids.
On completion of this module you will be able to establish the integrity of typical basic structural aircraft components and explain the process of material selection for the structural items of an aircraft.
Aerodynamics (year 2)
Topics and concepts covered in this module include fluid mechanics, boundary layer theory, sources of drag in particular aircraft drag, thin aerofoil theory, lifting line theory as it applies to the aerodynamic analysis of unswept wings in low speed flow. In addition to the apparatus used and techniques employed in wind tunnel testing.
Aircraft Systems Design
In this module you will learn about aircraft design, including detailed refinement of component design and major interactions that have a crucial influence on the overall effectiveness of the design. You will study the interactive nature of aircraft design, including business and commercial influences, and be able to report outcomes effectively. On completion you should also have an appreciation of market requirements in the design process.
This module will give you an in depth knowledge of avionic systems currently fitted to modern aircraft, including communication, flight instruments, flight management, automatic flight, warning and recording and passenger systems.
Flight Systems (year 3)
Following on from Flight Systems module in your second year, you will develop a deeper understanding of the theory of statics and dynamics and flight control as related to the dynamic behaviour of an aircraft.
Industrial Management and Project Preparation
This module has two main components. Industrial management in which you will be introduced to the commercial issues which must be addressed by engineering businesses, and the principles of quality management systems; and project preparation which will develop your ability to work independently, become competent in analysing and assessing the value of information, and develop effective communication skills both written and orally.
Final Year Project
A vital part of your career preparation, whether in industry or research, is to complete an individual project. Your final project will be based on an engineering theme of industrial relevance.
Aerodynamics (year 3)
This module is concerned with the analysis of gas turbine engines as used in aircraft propulsion and high speed aerodynamics. Emphasis is placed on the aerodynamic and thermodynamic aspects which influence the performance of a given engine design. Wherever possible, data for actual aircraft engines is used to support the analysis.
Aerospace System Design
In this module you will develop an in-depth knowledge of design of unmanned aerial vehicles and their associated systems. You will develop a critical understanding of aerospace system developments for future system requirements.
This module provides a systematic understanding of knowledge on finite element analysis as a tool for the solution of practical engineering problems. You will develop a comprehensive understanding of the development of appropriate finite element models of physical systems, and how to interpret the results of the analysis. The module also covers advanced aspects of finite element analysis including harmonic vibration analysis and will give practical instruction in the use of an industry-standard finite element analysis program.
This module introduces you to Computational Fluid Dynamics (CFD) methods for the numerical prediction of aerodynamic flows. You will study finite-difference and finite-volume techniques, the vortex-lattice method, the modern CFD method for the prediction of transonic aerofoil flows and be given an introduction to the requirements for turbulence modelling and review classes of turbulence models.
Plus one optional module:
This module will expose you to real engineering problems in an industrial or aerospace environment. You will gain a comprehensive understanding of the processes associated with the assembly of very large aircraft structures, including the techniques of forming, joining and fixturing, and an awareness of the regulatory and design standards that have to be met, and the processes that must be used to ensure conformity with those standards.
Flight Dynamics and Control
This module provides a comprehensive and systematic understanding of the analysis of flight dynamics and the design of flight control systems.
Please note that it may not be possible to deliver the full list of options every year as this will depend on factors such as how many students choose a particular option. Exact modules may also vary in order to keep content current. When accepting your offer of a place to study on this programme, you should be aware that not all optional modules will be running each year. Your tutor will be able to advise you as to the available options on or before the start of the programme. Whilst the University tries to ensure that you are able to undertake your preferred options, it cannot guarantee this.
What will I be doing?
You will develop your knowledge and skills through a blend of theoretical, collaborative and practical methods:
- Practical activities
You will be assessed through a combination of formats:
- Lab exercises
School of Science, Engineering and Environment
From cyber security to biomedicine to architecture, our expanding suite of multidisciplinary courses shapes the next generation of scientists, engineers, consultants and conservationists. Through advanced research, we’re pioneering robotics and AI, smart environments and the appliance of data. With a team of over 200 dedicated academic, technical and administrative staff, you’ll experience a supportive, professional environment where you can realise your potential.
The Mechanical Laboratory is used to understand material behaviour under different loading conditions and contains a tensile test machine and static loading experiments. Typical laboratory sessions include tensile testing of materials and investigation into the bending and buckling behaviour of beams.
The Aerodynamics Laboratory contains low speed and supersonic wind tunnels. Typical laboratory experiments include determining the aerodynamic properties of an aerofoil section and influence of wing sweep on the lift and drag characteristics of a tapered wing section.
The Control and Dynamics Laboratory is home to flight simulators and programmable control experiments. Typical laboratory sessions include studying the effects of damping and short period oscillation analysis, forced vibration due to rotating imbalance, and understanding the design and performance of proportional and integral controllers.
Our Merlin MP520-T Engineering Flight Simulator supports the design modules, by giving a more practical experience of aircraft design. Our Elite Flight Training System is a fixed base Piper PA-34 Seneca III aircraft simulator certified by the CAA as a FNPT II-MCC Multi-Crew Cockpit training environment.
What about after uni?
On successful completion of the course, you’ll be closer to realising your ambition to work in aviation. Aerospace and aviation is one of the UK’s largest employment fields, and with a growing air travel market, career opportunities are expected to increase.
A degree in Aircraft Engineering with Pilot Studies can lead to fascinating and rewarding career pathways. Opportunities can range from supporting air traffic control to operating as an airworthiness engineer. You may even have ambitions to fly aircraft and add to your skills by taking further training to become a fully-registered pilot.
Salford’s aircraft engineering alumni work throughout the world at leading companies and aviation-specific organisations, including the National Air Traffic Services (NATS), CTC Aviation and Goodrich.
You might find you want to learn more about aerospace and engineering, so we offer a range of specialist postgraduate courses to help you take your career and interests even further. Salford graduates and alumni also receive a significant fees discount.
- MSc Aerospace Engineering
- MSc Advanced Control Systems
- MSc Advanced Mechanical Engineering Design
- MSc Robotics and Automation
This course is extensively informed by collaboration between the university’s academics and industry partners from aeronautics, engineering and technology fields.
The course team has a wide range of long-standing and professional relationships with the aviation industry in the North West and beyond. Continued collaboration with the professions also ensures a stimulating range of external guest lecturers and career networking opportunities.
External validation of the course content recognises that it meets both UK and international standards required by the engineering profession.
What you need to know
We're looking for applicants with strong numerate skills, demonstrated by good A Levels in relevant subject areas. Ideally, you'll have a keen interest in aeronautics and aviation, with aspirations for an engineering-focused career. You may also be interested in becoming a pilot, but want the academic engineering background so you have a wider range of career options.
ENGLISH LANGUAGE REQUIREMENTS
International applicants must demonstrate proficiency in English. An IELTS score of 6.0, no element below 5.5, is proof of this.
English language and Mathematics at grade C/grade 4 or above
You must fulfil our GCSE entry requirements as well as one of the requirements listed below.
UCAS tariff points
128 UCAS points to include the study of Mathematics and a numerate science.
128 points with grade B or above in maths and numerate science. A pass in the Practical Element of science A levels must be achieved.
BTEC National Diploma
DDM from Engineering or Science subjects, must include Distinctions in Mathematics modules.
Access to HE
Pass with 128 UCAS points from a QAA-approved Engineering course; including 60 credits overall with a minimum of 45 credits at level 3 and Distinctions in numerate modules.
128 UCAS points to include Advanced Higher level Mathematics and Physics at grade B.
Irish Leaving Certificate
128 UCAS points to include A1 in Higher Level Mathematics and Physics.
Pass in Diploma of at least 60% from Science or Engineering.
32 points to include grade 6 in Higher Level Mathematics and Physics.
Salford Alternative Entry Scheme (SAES)
We positively welcome applications from students who may not meet the stated entry criteria but who can demonstrate their ability to pursue the course successfully. Once we receive your application, we'll assess it and recommend it for SAES if you are an eligible candidate.
There are two different routes through the Salford Alternative Entry Scheme and applicants will be directed to the one appropriate for their course. Assessment will either be through a review of prior learning or through a formal test.
Please contact Admissions for further information.
|Type of study||Year||Fees|
|Full-time home/EU||2019/20||£9,250per year|
|Full-time international||2019/20||£14,820per year|
|Part-time||2019/20||Your annual fee will be calculated pro rata to the full-time fee according to the number of credits you are studying.|
|Full-time home/EU||2020/21||£9,250per year|
|Full-time international||2020/21||£15240per year|
|Part-time||2020/21||Your annual fee will be calculated pro rata to the full-time fee according to the number of credits you are studying.|
You should consider further costs which may include books, stationery, printing, binding and general subsistence on trips and visits.
Scholarships for International students 2020/21
To celebrate the University of Salford's expertise and industry links in Computing and Engineering, high achieving international students may be eligible for our Computing, Science and Engineering International Excellence Scholarship of £3,500.
For more information go to International Scholarships.
All set? Let's apply
Course ID H492