DYNAMIC MODELING AND EXPERIMENTAL INSIGHTS IN A 10 kWe MICRO GAS TURBINE PROTOTYPE: EXPERIMENTAL VALIDATION AND TESTING

The growing energy need for decentralized and renewable power production increases the demand for flexible and very efficient small scale power generation units. Micro gas turbines (mGTs) are promising candidates for small-scale combined heat and power (CHP) generation for the residential, commercial and industrial sectors with a usual power output below 500 kW e. Such units are well-suited for compensating demand fluctuations in renewable-dominated grids. Since their operation must be reliable under transient and part-load conditions, a thorough understanding and examination of their dynamic behavior are crucial. This calls for the development of computationally efficient models for the real-time prediction of key performance parameters that can enable effective control and optimization strategies in mGT systems. For this paper, a dynamic real-time 0D model of a 10 kW e mGT prototype has been constructed and validated. The model is developed following a modular approach in MATLAB/Simulink environment, allowing the flexible integration of different engine components: compressor, turbine, recuperator, combustor, and control system. Each module implemented refined differential equations, ensuring fast computation while capturing the most important transient behaviors. The mGT prototype of 10 kWe was designed and manufactured by MITIS SA to target the residential energy market, biomethanization plants or decentralized power system for 5G antenna. The machine was tested, and key performance parameters were measured in different locations of the cycle.