Research on Constant Temperature and Humidity Energy Saving and Coupling of Double-loop Surface Cooler in Converged High Quality Power System
DOI:
https://doi.org/10.52152/4179Keywords:
Power system optimization, Double circuit surface cooler, Constant temperature and humidity technology, Coupling effectAbstract
Through theoretical construction, model establishment and performance analysis, it is found that compared with traditional cooling and environmental control technologies, the coupling strategy achieves a 15% reduction in energy consumption, a 20% increase in thermal efficiency, and a return on investment of 30% within two years, and the energy-saving performance is at least 25% higher than that of traditional methods, and the environmental control accuracy is improved by 35%. Compared with the existing technology, its unique advantage is that it can better adapt to variable loads, achieve more stable temperature (fluctuation ±0.5°C) and humidity (fluctuation ±3% RH) control, and higher energy efficiency (COP up to 3.8), but in extreme humid and hot environments, there may be slight condensate overregulation that increases fan energy consumption by 5-8%, and occasional refrigerant flow oscillation at low load causes instantaneous energy consumption fluctuations (<3%), which are currently being optimized for these limitations, The research results provide theoretical and practical support for power system optimization, and are of great significance for the future intelligent development.
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