A dimensionless parameter coupling the south and north roofs on the thermal environment of Chinese solar greenhouse: Ridge position ratio
Cite this dataset
Liu, Xingan et al. (2021). A dimensionless parameter coupling the south and north roofs on the thermal environment of Chinese solar greenhouse: Ridge position ratio [Dataset]. Dryad. https://doi.org/10.5061/dryad.44j0zpccb
This paper clarified the mechanism of the south and north roofs on the thermal environment of the Chinese solar greenhouse (CSG), using a new parameter: ridge position ratio (RPR), which can describe the dynamic dependency relationship between the south and north roofs. A mathematical model was established by using the method of combining computational fluid dynamics (CFD) with experiments, which then was used to analyze the effect of RPR on the thermal environment of the CSG. Based on this model, we compared the temperature distributions of the greenhouse with different RPR. Furthermore, the effects of different RPR on the amount of solar energy that entered the greenhouse were studied. Finally, the effects of different RPR on heat released capacity of the greenhouse envelopes at different moments were analyzed. The results showed the decline rate of the maximum temperature of each part in different RPR intervals increased as the increase of RPR during the daytime. The occurrence time of the maximum air temperature will be delayed when RPR increases to 0.3. As RPR increases, the heat storage layer of the soil gradually becomes thinner, but that of the north wall remains unchanged. RPR has a relatively small effect on the minimum temperature in each part of the greenhouse during the nighttime. Mathematical models of the relationships between RPR and the solar energy that entered the greenhouse, the released heat energy of the enclosure structures were established, respectively. The results can provide theoretical guidance for the structural design of the CSG.
Ministry of Science and Technology of the People's Republic of China, Award: 2019YFD1001902