Review of Failure modes: The state of the art in cable design & manufacturing for aerospace applications and failure mechanisms was reviewed. The potential impact and risk of increased power levels of 40MVA, related voltage (3kV), current (600A) levels and increased frequency related to PWM systems (>20kHz switching frequency; 1-3kHz fundamental frequency) were considered. A formal FMEA was conducted: allowing to identify and investigate risks related to the interface between the cable & connector. For screened cables, the field distortion at the triple point (between insulation, screen & air) may cause partial (surface) discharges. This may require field grading techniques specific to the aerospace environment. A UNIMAN PhD will investigate the subject further.
Development of electrostatic, electro-thermal and ageing models: Models using the streamer inception criteria to estimate the partial discharge (PD) inception voltage (PDIV) of unscreened cables were established & confirmed. The PDIV does not increase proportionally with the insulation thickness. Electro-thermal models were developed & confirmed in the test bench set up in the project, taking into account the cable design (dimensions & material properties), current waveform (amplitude, fundamental frequency & harmonics), shield (EMC braid) configuration (unshielded, individual shield on each phase, common shield around the 3 phases) and installation configuration (trefoil, flat). The current carrying capacity of screened cables increase slightly with increasing insulation thickness as the heat dissipation is favored by the increased cable surface. For unscreened cables the highest power density (VA/kg) is obtained with an optimum insulation thickness of 2mm (for PFA insulation). Cable ageing and long term risk of failure were analysed. The isothermal degradation kinetics of aerospace insulation materials polyimide, PTFE and PFA were compared. At temperatures below 250°C PFA has a higher lifetime compared to polyimide and PTFE. At higher temperatures polyimide behaves better than PTFE and PFA.
Development of HVAC cables: Several small (AWG12) and big size (AWG0) model cables were manufactured and analysed. Different manufacturing techniques to apply the insulation on the conductor were investigated. Advantages & disadvantages were highlighted, the most appropriate technique selected. Different design concepts were also evaluated. Based on this and simulation results, 3 HIVACS cables with the same conductor AWG00 (aluminium) but different electrical insulation systems (screened, unscreened) and shielding (metallic braid, unshielded) were designed, manufactured & tested for a PDIV above 9000V peak to peak PWM phase to phase. The screened cable has a PD inception and extinction voltage that do not change with pressure (semiconductive layers contain the electrical field inside the insulation). The advantage of a EMC braid around each phase is that phase-to-phase voltage is reverted to phase-to-ground voltage requiring less insulation thickness. For example the unscreened but shielded cable required a 2mm insulation thickness whereas the unscreened and unshielded cable required a thickness of 3.2mm (i.e. 6.4mm between 2 phases). On the other hand the unscreened & unshielded cable has a current carrying capacity 20% higher than shielded cables.