OK
Plastics & Elastomers
Industry News

AMRC to Produce Lightweight Propeller Blades Using Composites

Published on 2020-04-02. Edited By : SpecialChem

TAGS:  Cost Efficiency    

amrc-propellor-blasdes The University of Sheffield AMRC is carrying out on a £20 million project to develop lightweight propeller blades using composites, that will help the UK aviation sector reduce its carbon footprint and noise emissions at airports as part of an industry-led consortium with two other members of the High Value Manufacturing Catapult.

The AMRC, along with the National Composites Centre in Bristol and the Manufacturing Technology Centre in Coventry, is supporting private sector partner Dowty Propellers (part of GE Aviation Systems) for the Innovate UK funded Digital Propulsion project.

Digitalization to Cut Production Costs


The consortium is tasked with growing the UK’s aerospace propeller manufacturing base by harnessing composite technology with industrial digitalization to cut production costs and increase the performance of future propulsion systems in Europe’s €200 billion aviation sector.

Elaine Arnold, automation technical lead for the AMRC Composite Centre, said, “In a world of increasing passenger numbers the demand for cleaner, cheaper and yet more comfortable air travel has never been greater. To meet this demand, it is vital that the UK maintains and extends its world leading capability in sustainable UK aviation propulsion technologies.”

The Digital Propulsion project aims to evolve technologies within a new digital infrastructure to realize innovations in propulsion performance and cost.
Arnold says the development of technologies to reduce propeller noise and lower fuel burn through the Digital Propulsion program demonstrates a clear commitment to these goals.

Arnold added “The Digital Propulsion project aims to evolve technologies within a new digital infrastructure to realize innovations in propulsion performance and cost.
Exploring Innovative Ways to Design Propeller Blades

Part of the role of AMRC is to explore novel and innovative ways to design and manufacture varying types of propeller blades, from regional to small, including the load bearing structure, the cores, the blade roots and relevant hub connections. This is being carried out alongside the National Composites Centre (NCC) who will be exploring the use of their specific manufacturing and design technologies.

“The other side to it, and much more excitingly, is that both the AMRC and NCC are collaborating to form a new braid that fits these new shapes. Engineers have been coming up to Sheffield and us down to Bristol which means a cross pollination of ideas and for everyone to see that we are better working together.”

Arnold said “Our portfolio of cutting-edge equipment means we’re able to access a wide range of advanced technologies to do this work including finite element analysis, braiding, tailored fibre placement, resin transfer molding and press forming.

Braiding of Multiple Parts of The Blade


The next steps will be to look at the braiding of multiple parts of the blade and then the thermoforming of the foam that sits on the inside of the blade. Excellent progress has been made so far and the goal is for us to make a section of the full blade.

It is very much a collaborative piece of work and a great example of why collaboration across the High Value Manufacturing Catapult centers is of tremendous benefit to industry; engineers from the AMRC and NCC are exchanging their understanding and knowledge of capabilities to find and develop innovative manufacturing methods that will not only reduce costs but increase performance, positioning the UK as a world leader in this field.

Cost-effective Route to Manufacture Composite Blades


Dowty has flown the flag for the British aerospace industry across the world for many years, and this project will ensure it continues to do so into the future. For the AMRC, the outputs of the program will be a proven cost-effective route to manufacture composite blades and a springboard for further research and development.

The three-year program has allowed Dowty to investigate multiple technologies to design the next generation of composite propeller blades, incorporating new and novel geometries beyond current capabilities offered by existing manufacturing techniques.

Jonathan Chestney, Dowty Propellers’ Engineering Leader, said, “This program paves the way for new business opportunities within Dowty. The technology development led by the Catapults is allowing us to explore both current and emerging markets and create offerings for prospective customers which are both innovative and cost effective. The cross-Catapult collaborative effort is enabling detailed technology development to occur at a fast pace due to the sharing of resource and expertise, all of which benefits Dowty and, ultimately, its customers.

The AMRC is working with Catapult colleagues in the Bristol based National Composites Centre and the Coventry based Manufacturing Technology Centre in the ATI-funded program. They are also investigating the shift from manual to automated blade manufacturing processes.


Source: University of Sheffield
Back to Top