Your search keyword '"Yingya Chen"' showing total 2 results

1. Experimental Study on the Effect of Dust Deposition on Photovoltaic Panels

Author

Yingya Chen, Yanfeng Liu, Dengjia Wang, Xiaowen Wang, Yong Zhou, Tian Zhijun, and Yu Dong

Subjects

Maximum power principle, 020209 energy, Energy conversion efficiency, Photovoltaic system, Energy current, Environmental engineering, 02 engineering and technology, Electricity generation, 020401 chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, Shielding effect, Environmental science, 0204 chemical engineering, Deposition (chemistry), Voltage

Abstract

In recent years, PV is considered to be one of the main way to solve the current energy crisis. PV is generally built in exposed areas such as deserts and wasteland. And the efficiency of power generation of PV is easy affected by the dust accumulated on it. The research expounds the "three factors" of the effect of dust on PV, namely shielding effect, temperature effect and corrosion effect, then an efficiency evaluation method for photovoltaic cells is proposed. Finally, the field experiments show that with the increase of dust density, the short-circuit current, open-circuit voltage, and output power of the PV both decrease. The dust with a density of 10 g/m2 can reduce the maximum power of the PV by about 34%. In the initial stage of PV dust accumulation, dust has the greatest impact on its output performance. In addition, the dust density and the conversion efficiency have better nonlinear correlation. As the dust accumulation density gradually increases, the PV conversion efficiency gradually decreases. When the dust density increases to a certain extent, the PV conversion efficiency tends to be stable.

Published

2019

2. Experimental Study on Performance Test of Serpentine Flat Plate Collector with Different Pipe Parameters and A New Phase Change Collector

Author

Yingya Chen, Dengjia Wang, Xiaowen Wang, Yanfeng Liu, and Kang Wenjun

Subjects

Temperature resistance, Materials science, 020209 energy, Low melting point, 02 engineering and technology, Radiation, Phase-change material, Phase change, 020401 chemical engineering, Thermal, 0202 electrical engineering, electronic engineering, information engineering, Melting point, 0204 chemical engineering, Composite material, Overheating (electricity)

Abstract

In this paper, the thermal performance of serpentine pipe flat plate collectors with different pipe diameters and pipe spacings was tested by experiments. On this basis, two phase change materials with high melting point (70 °C) and low melting point (15 °C) were laid on the upper and lower parts of the pipeline to enhance the frost resistance and high temperature resistance of the collector. The experimental results show that under strong solar radiation conditions, high-melting phase change materials can absorb a lot of heat when the water temperature of the collector is high, thereby slowing down the water temperature rise and avoiding overheating, and when the collector is cooled, phase change can be effectively utilized to slows down the rate of temperature drop of the collector, so as to achieve reasonable utilization of the overheating of the collector; in the low temperature environment, the low melting point phase change material can significantly reduce the cooling of the collector and improve the frost resistance of the collector. The placement of the two kinds of different melting point phase change materials was investigated, and the results show that the low-melting phase change material under the pipe is more conducive to the collector antifreezing. However, for the hot regions, the high-melting phase change material placed at the top of the pipe is more conducive to preventing overheating.

Published

2019