Presentation
PYLEECAN project provides a user-friendly, unified, flexible simulation framework for the multiphysic design and optimization of electrical machines and drives.
The main objective of PYLEECAN is to boost reproducible research and open-science in electrical engineering. Thus, it is intended for researchers, R&D engineers and teachers in electrical engineering, both on standard and novel topologies of electrical machines.
For example, PhD students should start with PYLEECAN:
- You can save a lot of time by using existing algorithms dedicated to electrical engineering (e.g. coupling Scilab or Matlab with Femm),
- You can benefit from the community expertise for your research.
- You can contribute to the project to make sure your code is maintained and to enable other researchers to easily reproduce your results.
To achieve all of that, Pyleecan is open source with a very permissive license (Apache V2 license).
Getting Started
The procedure to install and use Pyleecan is detailed on pyleecan website Warning: Pyleecan is not yet compatible with Python 3.11 due to PySide2. We plan to update pyleecan to 3.11 when we will have the time to do so.
Origin and Current Status of the Project
EOMYS ENGINEERING initiated this open-source project in 2018 for the study of electric motors. The project is now backed by Green Forge Coop non profit organization, who also supports the development of Mosqito for sound quality and SciDataTool for efficient scientific data exploitation.
Main Models and Couplings:
- PYLEECAN is fully coupled to FEMM to carry non-linear magnetostatic analysis including sliding band and symmetries. For now this coupling is available only on Windows OS.
- PYLEECAN includes several losses model (based on FEMM coupling output).
- PYLEECAN includes an electrical model to solve the equivalent circuit of PMSM and SCIM machines.
- PYLEECAN is coupled to GMSH 2D/3D finite element mesh generator to run third-party multiphysic solvers.
- PYLEECAN is coupled to two different multiobjective optimization libraries to carry design optimization of electrical machines.
- PYLEECAN enables to define Parameter Sweep of variable speed simulations.
Main Topologies Features:
- PYLEECAN includes a Graphical User Interface to define main 2D radial flux topologies parametrized geometries (SPMSM, IPMSM, SCIM, DFIM, WRSM, SRM, SynRM) including material library and automatic single speed current driven Magnetic FEMM simulations.
- Possibility to import Slot or Hole from DXF files
- Star of Slot Winding (with swat-em) and User Defined Winding
- Generic Geometry modeler to draw complex machines in the software coupled with PYLEECAN
- Notches (Yoke and Bore) / Uneven Bore or Yoke shape (compatible with slot/notches) / Machine with more than 2 laminations Examples can be found in the gallery.
If you are interested by a topology or a specific model, you can open an issue or a discussion on this Github repository to talk about it. We will gladly explain how to develop it yourself or we will add it to the development list. We are always looking for experimental data and model validation based on the last scientific research work. Even if you don't have time to work on pyleecan, sharing your expertise will be valued by the community.
RoadMap
The mid/long term roadmap of the project is detailed here
Documentation / Website
All the information on the project are available at www.pyleecan.org. In particular, the media page gathers the publications, video and screenshots of the project.
Contact
You can contact us:
- By opening an issue on Github (to request a feature, ask a question or report a bug) or starting a discussion
- By sending an email at pyleecan(at)framalistes.org that redirect to all the maintainers.
You can follow us:
- On our newsletter
- On GFC youtube channel (with webinars and tutorials video)
- On GFC Linkedin page