Environmental Performance Evaluation for a Small Scale Trigeneration System

Bulletin of the Polytechnic Institute of Iași. Electrical Engineering, Power Engineering, Electronics Section Pub Date : 2021-12-01 DOI:10.2478/bipie-2021-0023

B. Neagu, M. Gavrilas, M. Tirsu, Nicolae Covalenco, Ion Negura

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Abstract

Abstract The modern buildings must have very high standards and require highly efficient energy supply systems due to space limitations for renewable installations. Electricity and thermal energy can be produced simultaneously with a photovoltaic-thermal (PVT) system. In the paper, an innovative concept of PVT system for a hospital is studied. PVT collectors serve as both a heat source and a heat sink for a reversible heat pump in the examined system. Due to the reduced electricity consumption from the network for heat rejection, the overall efficiency was improved by using a reversible water-to-water heat pump as heat and cold source compared to a conventional solar cooling system. Primary energy savings can be achieved with a maximum utilization of PV for electricity, heating and cooling (as air conditioning). The paper presents an original methodology for determining the environmental impact of the real PVT operation. The case study shows that for a real 4kWp PVT, the yearly energy savings reduce the greenhouse gas (GHG) emissions with 281.8 kg/year for SO2 and 152.4 for CO2.

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小型三联发电系统的环境性能评价

由于可再生能源设施的空间限制，现代建筑必须有很高的标准，并要求高效的能源供应系统。电能和热能可以同时产生与光伏热(PVT)系统。本文研究了医院PVT系统的创新理念。PVT集热器作为热源和散热器的可逆热泵在检查系统。由于减少了网络用于散热的电力消耗，与传统的太阳能冷却系统相比，使用可逆的水对水热泵作为冷热源，整体效率得到了提高。通过最大限度地利用光伏发电、供暖和制冷(如空调)，可以实现初级能源节约。本文提出了一种确定实际PVT作业对环境影响的原始方法。案例研究表明，对于一辆真正的4kWp PVT，每年节省的能源减少了温室气体(GHG)排放281.8千克/年的二氧化硫和152.4千克/年的二氧化碳。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Bulletin of the Polytechnic Institute of Iași. Electrical Engineering, Power Engineering, Electronics Section

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