دانلود مقاله ISI انگلیسی شماره 90468
ترجمه فارسی عنوان مقاله

تحقیق در مورد شبیه سازی و کنترل استراتژی سیستم پمپ حرارتی مبدل هیبریدی

عنوان انگلیسی
Research on the Simulation and Operation Control Strategy of Hybrid Ground Source Heat Pump System
کد مقاله سال انتشار تعداد صفحات مقاله انگلیسی
90468 2017 8 صفحه PDF
منبع

Publisher : Elsevier - Science Direct (الزویر - ساینس دایرکت)

Journal : Procedia Engineering, Volume 205, 2017, Pages 1507-1514

ترجمه کلمات کلیدی
پمپ حرارتی منبع زمین، سیستم هیبریدی، شبیه سازی دینامیک، استراتژی کنترل بهینه،
کلمات کلیدی انگلیسی
ground source heat pump; hybrid system; dynamic simulation; optimal control strategy;
پیش نمایش مقاله
پیش نمایش مقاله  تحقیق در مورد شبیه سازی و کنترل استراتژی سیستم پمپ حرارتی مبدل هیبریدی

چکیده انگلیسی

Large-scale commercial buildings served by ground source heat pump (GSHP) systems generally require a large land area for ground heat exchanger (GHE) installation. However it is difficult to provide such large area around the buildings, especially in urban area. Additionally, a large-scale GHE may consume more energy consumption compared with a medium or small GHE system because of the significantly large transmission energy consumption in the closed GHE loop. This study takes a commercial building located in northern China as a case study and proposes three different design schemes: chillers plus municipal central heating system, a single GHSP system and a hybrid GSHP system with chiller and municipal central heating as supplemental heat source and sink. The simulation models of the three systems have been established in the platform of TRNSYS. An optimal control strategy has been found with the aim of lowest annual operating cost. The results show that the municipal heating system can be put in operation when the outlet water temperature from GHE is less than 4℃ in winter; the cooling tower would be open to assist heat dissipation when the outlet water temperature from GHE is above 33℃ in summer. In this case the GSHP can provide 42% of the cooling and 83.5% of the heating loads, respectively.