Kenneth M. Wacha, Chi-hua Huang, Peter L. O'Brien, Athanasios N. Papanicolaou, Jerry L. Hatfield
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引用次数: 2
摘要
雨滴撞击来自于雨滴下落时的动能。测定降雨动能需要测定雨滴的大小分布和终端速度,这就需要复杂的仪器。为了避免这种情况,已经建立了将降雨强度与动能速率(即时间比动能(KEtime))联系起来的经验关系。在本研究中,采用动态雨量计系统(DRGS)来量化由降雨模拟器产生的KEtime,而无需测量雨滴大小分布或冲击速度。在10次降雨试验中,KEtime和降雨强度分别为860.9(±88.6)J m2 h - 1和72.1(±1.9)mm h - 1。对于高强度模拟降雨,发现估计的KEtime与petrdv和kalibov提出的幂律关系很好地吻合,这是发生较大偏差的条件。DRGS可能是量化降雨模拟器KEtime的有用工具,希望能更好地了解雨滴的影响机制。
Quantifying the time-specific kinetic energy of simulated rainfall using a dynamic rain gauge system
Raindrop impact derives from the kinetic energy of falling raindrops. Determining the kinetic energy of rainfall requires the size distribution and terminal velocity of raindrops, which necessitates complex instrumentation. To avoid this, empirical relations have been developed that relate rainfall intensity and the rate of kinetic energy, i.e., time-specific kinetic energy (KEtime). In this study, a dynamic rain gauge system (DRGS) was used to quantify the KEtime generated by a rainfall simulator without need of measuring raindrop size distributions or impact velocities. In a series of 10 rainfall tests, the KEtime and rainfall intensity were 860.9 (±88.6) J m2 h−1 and 72.1 (±1.9) mm h−1, respectively. Estimated KEtime was found to agree well with the power-law relation presented by Petrů and Kalibová for high-intensity simulated rainfall, which are the conditions when higher deviations occur. The DRGS may be a useful tool in quantifying the KEtime of rainfall simulators in hopes to better understand raindrop impact mechanisms.
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