TOKYO, May 24, 2017 - Mitsubishi Electric Corporation (TOKYO: 6503) announced today the development of what it believes is the world's-first technology for determining the operational status of power generators using electromagnetic-field analysis of up to an unprecedented 30 million meshes and coupled-numerical analysis. The new technology will help improve generator performance by reducing loss, raising cooling efficiency and reducing vibration, etc. for strengthened reliability, ultimately to enhance the stability of electricity supply. Mitsubishi Electric will use the new technology for its current VP-X Series turbine generators and future models. The company also aims to combine the above technologies in a comprehensive system that provides full analysis of generators by around 2020.
The technology analyzes the interaction between electromagnetic-field and thermal-fluid-flow-field, as well as the structural configurations of power generators, enabling the detailed distribution of temperature and vibration to be calculated based on detailed loss distribution and electromagnetic force.
Mitsubishi Electric developed its large-scale electromagnetic field analysis technology by using an original modeling method for domain decomposition. Electromagnetic loss distribution in a stator coil's 100-some copper strands is evaluated with high accuracy. Compared to conventional part-by-part small-scale analysis, the new technology accurately evaluates electromagnetic-loss distribution by analyzing the stator end-region structures, which significantly affect generation efficiency, as a whole.
Further, the technology enables detailed calculation and mapping of temperature distribution and deformation by using coupled analysis of the generator's electromagnetic- and thermal-fluid-flow-fields and structure.
Additionally, Mitsubishi Electric used the data generated with the new technology for analysis of the initial condition of thermal fluid, making it possible to calculate the detailed temperature distribution inside a generator. Also, structural analysis based on the electromagnetic-force data, as well as analysis of vibration throughout the generator, can be used to determine which kinds of sensors cannot be installed due to a high-noise, high-voltage and/or high-vibration environment.
|New||- Electromagnetic field: 30 million meshes
- Detailed coupled analyses of electromagnetic field, thermal-flow fields, and structure
|- Electromagnetic field: evaluation of low-loss structure as a whole
- Thermal-flow fields: large-area thermal fluid analysis for temperature evaluation
- Structure: total design of vibration and strength
|Existing||- Electromagnetic field: 7 million meshes
- Individual analyses of electromagnetic field, thermal-flow fields, and structure
|- Electromagnetic field: part-by-part evaluation of low-loss structure
- Thermal-flow fields: partial thermal fluid analysis for temperature evaluation
- Structure: individual design of vibration and strength
Note that the releases are accurate at the time of publication but may be subject to change without notice.