| Summary: | This study proposes a multiple-mode collaborative operation strategy for the first time, which integrates compressor inlet air heating mode, gas turbine interstage extraction mode, and back pressure heating mode. This operation strategy can improve the peak shaving flexibility of the cogeneration system based on gas turbine combined cycle (GTCC). This article uses Ebsilon software to simulate cogeneration system based on GTCC under different heat and power decoupling technologies and obtain the heat and power operation region. The peak performance of different heat and power decoupling technologies on heating characteristic days are analyzed. Meanwhile, the impact of objective power load changes is studied. The results show that during the whole heating season, compared with the conventional operation mode without heat and power decoupling technology, the multiple-mode collaborative operation strategy, electric boiler (EB) technology, and heat storage tank (HST) technology are adopted, and the renewable energy integration of the cogeneration system based on GTCC are increased by 1.16 × 105 MW, 1.37 × 105 MW and 5.65 × 104 MW, respectively. In addition, When the objective power load is 197.5 MW or 120 MW, taking into account the integration of renewable energy, natural gas consumption, and system benefits, the multiple-mode collaborative operation strategy is the optimal choice.
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