各月水汽压的最小值出现在东北山区。
The lowest water vapor press of each month appeared in the Northeast Mountain Areas.
水汽压递减系数在不同时间是不相同的。
Water vapor press decreasing coefficients are different in different time.
分析表明:随着海拔高度的增加,水汽压逐渐减小;
The analysis shows that water vapor pressure decreased with the increasing of sea level elevation;
地理位置和海拔高度是水汽压空间分布的主要影响因子。
Geographical situation and sea level elevation are the main influencing factors to the spatial distribution of water vapor press.
利用冠层温度下的饱和水汽压估算了玉米冠层顶部结露的持续时间和结露量。
The duration of dew formation and the amount of dew are estimated by predicting the time when the temperature of upper leaves falls below the dew point.
计算结果表明,可降水量和相应的地面水汽压之间,存在着良好的数值对应关系。
The calculating results show that the precipitable water is well related with the ground water vapor pressure.
证实利用地面水汽压资料可相当精确地计算出各地的可能太阳直接辐射日平均通量密度。
The results show that the daily average flux-density regime can be calculated quite accurately for various parts of the country by making use of the surface vapor pressure data.
结果表明。布里渊散射光频移受大气压、水汽压的影响很小。而受大气温度的影响很大。
The result shows that the frequency shift of Brillouin scattering light is scarcely influenced by air pressure and vapor pressure, and greatly affected by air temperature.
年、季日照时数减少与低云量增加关系密切,而冬季日照时数的减少还与水汽压的增加有关。
Annual and seasonal sunshine hours decreased with the increasing of low level cloud amount, and the reduction of sunshine hours increased along with vapor pressure in winter.
采用机械加压通风增湿调节供风管道内的相对湿度,将水汽压入粮堆使谷粒自然吸湿并平衡水分。
The RH in aeration pipe increased and the moisture was pressed into the grain bulk through the aeration pipe. The moisture was absorbed by grains and equilibriumed.
再利用地面温度、气温、水汽压和总云量,计算得出福建省各地的地面有效辐射的月、年平均辐照度。
The ground effective radiations are calculated based on the ground temperature. air temperature. water vapour pressure and total cloud cover.
第二阶段是由近地面微气象条件决定的水分凝结过程,所吸收水量受空气水汽压、地面温度和地表可利用能量的影响。
The second is the process of water condensation determined by air vapor, soil surface temperature and the available energy of soil.
此回归方程为不具有探空条件的气象站点提供了利用地面水汽压计算水汽总量的简便方法,具有良好的实际应用价值。
This regression equation offers an easy way to calculate precipitable water vapor by means of surface vapor pressure for the stations without Sounding conditions, so it has great practical value.
空气温度、叶面温度、饱和水汽压差和气孔导度是影响水稻的蒸腾速率的关键因素,并在水稻不同生育阶段表现不同的影响程度;
Air temperature, leaf temperature, vapor pressure deficit and stoma conductance were the key factors affecting transpiration, and the effects would be different in different growing stages.
空气温度、叶面温度、饱和水汽压差和气孔导度是影响水稻的蒸腾速率的关键因素,并在水稻不同生育阶段表现不同的影响程度;
Air temperature, leaf temperature, vapor pressure deficit and stoma conductance were the key factors affecting transpiration, and the effects would be different in different growing stages.
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