In the past years, several industrial programmes have initiated the concept of a More Electric Aircraft in order to reach objectives of reduced environmental emissions and noise. In fact, there is a general consensus in the aerospace community that more electrically powered systems will lead to weight saving, reliability improvement and life-cycle cost reduction. Therefore, the use of electromechanical actuation (EMA) can be a solution to help the development of a cleaner aviation because, with respect to traditional hydraulic actuation, it is:
• Less complex because of the absence of a hydraulic system
• Better suited to long term storage since there is no leak potential
• More energy efficient compared with hydraulic systems
• Easier to install and maintain (no filtration, no bleeding)
• Less complex to control from a power-distribution and power-management perspective (power is transmitted without mass transfer)
Nevertheless, some critical issues of this technology need to be addressed. Based on this scenario, the REPRISE project is specifically focused on overcoming these issues and improving technology performance, reliability and safety using new technologies and health-management algorithms. Main technical objectives are as follows:
• An innovative electromechanical actuator (EMA) for flight-control surfaces with reduced spatial envelope and weight and with improved reliability
• Reliable health-management software for the electromechanical actuator to increase safety margins.
The project developed an enhanced actuator by pursuing following main objectives:
- the architecture definition, the design and the manufacturing of a fault-tolerant/jamming-tolerant EMA for safety-critical aerospace applications. The results and performances reached in the REPRISE project allow to use this new and revolutionary actuator’s architecture in the next MEA generation both for primary slight surface control both for Landing Gears applications on A/C of mayor aerospace players which UMBRAGROUP spa is already in contact.
- the design and the verification at TRL 3 of condition-monitoring algorithms, with particular reference to ones dedicated to jamming faults.