A methodology of photovoltaic power integration in air conditioning system – An inverter-less approach

IF 1.6 Q4 ENERGY & FUELS IET Energy Systems Integration Pub Date : 2022-03-30 DOI:10.1049/esi2.12066
Dhiman Das, Sukumar Mishra, Bhim Singh
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Abstract

The photovoltaic (PV) power generation and cooling demand of the air conditioner are increased along with an increase in solar irradiation. Therefore, considering such fact, in this paper, PV power is integrated with the air conditioner to support the grid. With recent developments in power electronics, the air conditioning systems are operated in variable speed using variable frequency drive (VFD) technology. In this paper, taking the advantage of the VFD technology, PV power is directly injected into the DC bus of VFD using an isolated DC-DC converter. In this methodology, due to the high-frequency DC-DC conversion, high power DC-AC (50 Hz) stage is eliminated, and seamless power is transferred from PV generation to the load without interrupting the main operation of the air conditioner. Thus, the reliability of the system is enhanced with the reduction in overall cost, conversion losses and bulkiness. With the PV power support, the peak amplitude of the grid current is reduced and consequently the power consumption, reactive power intake from the grid, as well as the harmonics component of the grid current, are reduced. This scheme is used in rural or suburban areas where the solar profile is significant and air conditioner is extensively used.

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空调系统光伏电力集成方法——无逆变器方法
随着太阳辐照量的增加,空调的光伏发电和制冷需求也随之增加。因此,考虑到这一事实,本文将光伏发电与空调集成以支持电网。随着电力电子技术的最新发展,空调系统采用变频驱动(VFD)技术以变速运行。本文利用VFD技术的优势,利用隔离型DC-DC变换器将光伏电源直接注入VFD的直流母线。在该方法中,由于采用高频DC-DC转换,消除了大功率DC-AC (50 Hz)阶段,在不中断空调主要运行的情况下,将光伏发电的电力无缝传输给负载。因此,随着总体成本、转换损失和体积的减少,系统的可靠性得到了提高。在光伏电源的支持下,电网电流的峰值幅度减小,从而减少了电网的功耗、无功功率以及电网电流的谐波分量。本方案适用于太阳能分布明显、空调广泛使用的农村或郊区。
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来源期刊
IET Energy Systems Integration
IET Energy Systems Integration Engineering-Engineering (miscellaneous)
CiteScore
5.90
自引率
8.30%
发文量
29
审稿时长
11 weeks
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