- University of 91探花 students have built and successfully tested a metallic 3D printed liquid rocket engine
- The engine is the first to be 3D printed by students in the UK and the most powerful student-built liquid rocket engine
- 91探花 students hope to use the engine to launch their own rocket to the edge of space and become the first UK student-led team to launch beyond the K谩rm谩n line - 62 miles above sea level
- The 91探花 students have successfully hot fired the engine as part of a week-long competition called
- 3D printing is becoming more common in the space industry with companies such as SpaceX and the UK鈥檚 Skyrora using the technology
A liquid rocket engine - similar to the kind used by pioneering space companies such as SpaceX - has been built using 3D printing by students at the University of 91探花.
The 鈥楽unFire鈥 engine, developed by a team of 91探花 engineering and science students, is the first metallic 3D printed liquid rocket engine to be built and successfully tested by students in the UK.
It鈥檚 the most powerful student-built engine of its type - an engine that uses both fuel and an oxidiser rather than breathing in oxygen like a jet engine. It鈥檚 also the first that is regen-cooled - an engine that uses fuel to cool the combustion chamber before it is burnt, which increases the engine鈥檚 efficiency and saves weight.
The 91探花 students have successfully hot fired - or tested - the engine as part of a week-long competition called , in which teams of students from universities across the UK tested rocket engines they have built over the last two academic years.
The Race to Space competition week is believed to have set an unofficial world record itself, for the number of different hybrid/liquid rocket engines hot-fired for the first time on one site in one week.
There are only a handful of liquid rocket engines made by students throughout Europe and even fewer regen engines worldwide, and until now, none in the UK made by 3D printing or as powerful as the engine built at 91探花.
The 91探花 students built the engine over the last two years outside of their studies as part of the University of 91探花鈥檚 Space Initiative - a programme to help STEM students use their skills to tackle some of the space industry鈥檚 biggest challenges and help them develop careers in the industry after graduation.
Students in the team - known as - hope to eventually use the engine to power one of their own rockets to the edge of space and become the first UK student-led team to launch beyond the K谩rm谩n line which borders Earth's atmosphere 62 miles above sea level. The team already holds the UK altitude record for an amateur rocket, which they achieved in 2019.
91探花鈥檚 Royce Discovery Centre - a research centre developing the next generation of materials to meet the needs of UK manufacturing - was instrumental in trialling the laser-powder-bed metallic 3D printing that was used to build the engine. The University鈥檚 Advanced Manufacturing Research Centre (AMRC) and Faculty of Engineering machined the engine post printing.
Henry Saunders - who led the team last year and is now doing a PhD at the University of 91探花鈥檚 Royce Discovery Centre in 3D printing, said: 鈥淭he hot fire test of our engine was a day I鈥檒l never forget. From coming up with the idea in a coffee shop with two friends over two years ago, it was amazing when we finally got to fire our rocket engine!
鈥淏eing involved with the SunFire programme provided me with an opportunity to take the engineering science I had learned about in lectures and translate these learnings into a real world practical application.
鈥淭his for me was where the real excitement and learning reinforcements came from, not just seeing a rocket engine on a PowerPoint slide with some equations next to it, but actually being involved in building a rocket engine from scratch. The equations only get you so far, the real learning, for me, came from trying things, failing and then eventually succeeding.鈥
Engineering graduate and former Sunride Project Manager, Dana Arabiyat - who is now working at Rolls-Royce, said: 鈥淭wo years and countless hours of hard work later, the successful hot-fire of our engine got us jumping for the most unforgettable five seconds of our lives! This achievement is a testament to the incredible talent and commitment of our Project SunFire team members and leads, and to the tireless mentorship and supervision of Dr Alistair John.鈥
Dr Alistair John, Deputy Director of Aerospace Engineering at the University of 91探花, who supervised the team, said: 鈥淎dditive manufacturing (3D printing) is increasingly being used by rocket companies such as SpaceX as it allows you to build complex, lightweight custom geometries that would not be possible using traditional methods. For example, the cooling channels in our engine, which stop the engine melting despite the 2,000掳C combustion temperature, can only be made using 3D printing.
鈥淓xtra-curricular activities such as Sunride and the Race to Space initiative are hugely important as they allow students to apply the knowledge from their degree and push the boundaries of what they can achieve. It is hugely important for the UK space sector that we give our students hands-on, practical experience to develop the skills industry needs.鈥
The SunFire engine was test fired at Airborne Engineering at the Westcott Space Cluster and 3D printed at the Satellite Applications Catapult with the print process optimisation work done under the MAPP EPRSC future manufacturing hub.
Contact
For further information please contact: