天气对直径为10m的波纹钢仓的粮仓部件和顶部空间温度的影响。

Q4 Engineering

Canadian Biosystems Engineering / Le Genie des biosystems au Canada Pub Date : 2022-12-31 DOI:10.7451/cbe.2022.64.3.1

V. Bharathi, F. Jian, D. Jayas

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引用次数: 0

摘要

由于气候变化，全球平均气温正在上升。为了了解环境天气的变化如何影响储存谷物的温度，从2019年8月中旬到2021年10月底，在加拿大温尼伯监测了地板、屋顶、侧壁和顶空的温度波动模式。在初始平均含水量为12.5±0.1%(湿基)的条件下，向仓内填充300 t小麦。热电偶分别安装在仓的地板、屋顶(外部)和侧壁(外部)的17、9和12个位置。16个温度和相对湿度传感器安装在离顶空谷物表面不同距离的不同位置。在研究期间，还测量了垃圾箱附近的环境天气(气温(°C)、相对湿度(%)、气压(kPa)、平均太阳辐射(W/m2)、降水量(mm)、风速(m/s)和风向(相对于北方的度数)。屋顶、侧壁和顶空的温度受环境温度和太阳辐射的影响。在第二年(2020年11月至2021年10月)，地板、屋顶、侧壁和顶空温度分别比第一年(2019年11月至2020年10月)高2.1±0.1°C、3.9±0.1°C、3.5±0.2°C和1.9±0.1°C。与第1年相比，第2年的环境温度升高了1.8°C，这些结果可用于预测天气变化引起的粮仓温度。

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Effects of weather on temperatures of the grain bin components and headspace of a 10-m diameter corrugated steel bin.

The mean global temperatures are increasing as a result of climate change. To understand how the change in ambient weather influences the temperature of the stored grain, the temperature fluctuation patterns of the floor, roof, sidewalls, and headspace were monitored from mid-August 2019 to the end of October 2021 in Winnipeg, Canada. The bin was filled with 300 t of wheat at an initial average moisture content of 12.5 ± 0.1% (wet basis). The thermocouples were installed at 17, 9, and 12 locations on the floor, roof (outside), and sidewalls (outside) of the bin, respectively. Sixteen temperature and relative humidity sensors were installed at different locations with varying distances from the surface of the grain in the headspace. The ambient weather (air temperature (°C), relative humidity (%), barometric pressure (kPa), average solar radiation (W/m2), precipitation (mm), wind speed (m/s), and wind direction (degrees with reference to the north)) were also measured near the bin during the study period. The temperatures of the roof, sidewalls, and headspace were influenced by the ambient temperature and solar radiation. In Year II (November 2020 – October 2021), the floor, roof, sidewalls, and headspace temperatures were higher by 2.1 ± 0.1°C, 3.9 ± 0.1°C, 3.5 ± 0.2°C, and 1.9 ± 0.1°C than that in Year I (November 2019 - October 2020), respectively. The ambient temperature increased by 1.8°C in year II, compared to year I. These results can be used in the prediction of temperatures in grain bins caused by weather changes.

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来源期刊

Canadian Biosystems Engineering / Le Genie des biosystems au Canada Engineering-Mechanical Engineering

CiteScore

0.30

自引率

0.00%

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