考虑作物冠层高度的屋脊形大棚形状优化

    Optimizing ridge-shape greenhouses considering crop canopy height

    • 摘要: 为提高屋脊形大棚太阳辐射利用率,增强保温蓄热能力。该研究依据大棚内部作物对采光和蓄热保温的需求,提出了基于冠层高度和恒定体积约束的屋脊形大棚形状优化模型,设置大棚采光面捕获太阳辐射量大及有效种植面积尽可能大的约束条件,在内部能量需求恒定的条件下分析大棚高度比及方位角对太阳辐射捕获量的影响规律,并优选出不同脊位比大棚在不同地区下的最优参数组合。结果表明:1)大棚所捕获的太阳辐射量大多随高度比减小而逐渐减小,在高度比 k=5时为最大值;相同高度比下,脊位比越大,大棚所捕获的太阳辐射量越大;当高度比 k=5时,沈阳地区脊位比为0.65、0.75和0.85的大棚相对于脊位比为0.50时的增长率分别为2.67%、4.42%和6.17%。2)大棚太阳辐射捕获量大多随方位角增加呈先减小后增加趋势,在方位角0°~90°的范围内,脊位比越大,大棚所捕获的太阳辐射量越多,在90°~180°的范围内相反;当大棚脊位比为0.65、0.75和0.85时,随着地区纬度的增加,大棚太阳辐射捕获量最低值点所对应的方位角值逐渐减小,不同脊位比之间的差异逐渐减小。3)大棚在不同地区优选得到的高度比值仅与作物冠层高度有关;地区纬度越高,脊位比及高度比越大,大棚优选得到的方位角相对于南北走向偏转的角度越大。该研究可依据作物冠层高度大小在大棚捕获太阳辐射量尽可能多的前提下减少大棚供热成本,为推进塑料大棚的整体规划发展提供理论依据。

       

      Abstract: Greenhouse is one kind of protected cultivation facility with plastic film as the covering material and bamboo or steel frame as the supporting structure. Solar radiation is one of the most important influencing factors on the thermal energy environment inside the greenhouses. Only the greenhouse effect without heating can make the internal temperature higher than the outside in the cold regions. The solar radiation received by a greenhouse is strongly related to some parameters, such as geographical location, climatic conditions, orientation, and shape. Therefore, it is very necessary to optimize the shape, orientation, and size of greenhouses, in order to maximize the use of winter solar radiation and then effectively reduce winter heating requirements and operating costs. The optimal shape and orientation of greenhouses can vary slightly in the height of the crop canopy, such as fruit, leafy vegetables, and flowers. However, it is still lacking to consider the canopy height of the crops in the greenhouse structure, according to the capture of solar radiation on the lighting surfaces. In this study, a novel model was developed to optimize the ridge-shape greenhouse using canopy height and constant volume constraints. The amount of solar radiation was also maximized to capture the lighting surface and the effective planting area. A systematic analysis was implemented to explore the influence of the greenhouse height ratio and azimuth angle on solar radiation capture under the constant internal energy demand. The optimal combination of parameters was achieved in the different ridge ratios and regions. More light was harvested and converted at the expense of the greenhouse into heat stored in the greenhouse, thus reducing night-time heating costs. A comparative analysis was also made to verify the calculated and measured values of the solar radiation model. The results show that the solar radiation captured by the greenhouses was positively correlated with the height and ridge ratio. The difference in solar radiation with different ridge ratios decreased with the decrease in height ratio. The amount of solar radiation captured inside the greenhouse increased with the decrease of regional latitude at the same height ratio. Most solar radiation showed a decreasing and then increasing trend with the increase of azimuth angle. The preferred height ratios in different regions were related only to the height of the crop canopy. The higher the latitude under the same conditions was, the greater the ridge ratio and canopy height were. The greater angle of azimuth was preferably obtained by the greenhouse deflected with respect to the north-south direction. This finding can improve the thermal insulation and heat storage with heating cost savings in the greenhouse. A theoretical basis can also offer to advance the overall planning and development of greenhouses.

       

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