The development of high performance and efficient MIP, with a minimum impact on the size and weight of the systems, includes an adequate design based on advanced topologies that allow a minimization of the passive components in terms of size and weight.
Two main lines are pursued: the use of broadband semiconductors and a multilevel topology to reduce the size of passive elements, such as filters.
These two issues have been developed throughout the project. By selecting components and focusing on the analysis of broadband semiconductors. In the Module Architecture Definition, the multilevel topology has been analyzed. In addition, functional models of the preliminary design, based on minimizing size and weight, are currently being developed to achieve high performance based on the use of high-efficiency broadband semiconductors and their integration into the most appropriate multilevel topology. On the other hand, the optimization of passive filters, in order to increase efficiency.
Broadband semiconductors have been analyzed and thanks to the nature of these, the switching frequency can be significantly increased compared to conventional technology. Therefore, the size and weight of the passive elements can be reduced. The appropriate switching frequency is defined in the design to minimize these elements which comprise a high percentage of the size and weight of the converter.
The high reliability and robustness based on a multilevel modular approach, its interleaved topology, eliminates the affected module in case of failure or divides the power in the other available branches, avoiding an interruption of the operation.
The operating modes will manage the configuration of the topology under a cell failure that bypasses it. This also affects the design of the cell and its integration into the topology so that it can be easily bypassed.
A high modularity and scalability with a high percentage of common design of AC/DC and DC/DC modules (almost equal converters), optimizes the integration of both power stages, the manufacturing process and the average time between repairs.
All work is based on the use of similar cells for both DC/DC and DC/AC. The semiconductors analysed will be similar for both converters, as well as the derivation strategy followed by the converters' operating modes in case of failure. In addition, the following has been taken into account for the preliminary design
A superior hierarchical controller will provide full control of both power stages, based on an advanced hardware/software architecture with a multi-core approach (FPGA + DSP+ARM) that fully controls each power module with a high bandwidth capacity. The built-in electronics have advanced protection and fault management features, for fast response and implementation of autonomous and/or emergency strategies
The multi-core approach has been analysed and high performance processors have been chosen. The difference is the lower level that will depend on the final control and modulation strategy, the simulation tests will also help to choose the best option.
The preliminary design is at a schematic level, as the other levels are being delayed due to the development of the power stage,the project has made some progress in the detailed design and at this status waiting from final feedback from SAFRAN.
Based on the preliminary design, the detailed design is carried out (mechanical, electrical, thermal), and detailed cad drawings including final safety analysis, prior to launch equipment manufacturing. The following issues will be covered:
- Mechanical, electrical and thermal design of the power stage.
- PCB design of the hardware electronics
- support and verify all the issues related to the semiconductors, especially in the case of the drivers.
- Software design and development of the software
- Implementation of the modulation algorithms by the
- Communication design by HESS supported by Edair.
- Manufacture of all electronics and IPM
- Test campaign associated with IPM