Antônio Reynaldo de Sousa Costa, L. A. Alvarenga, M. Thebaldi, P. A. Melo, A. Colombo, J. Isidoro
{"title":"Portable rainfall simulator: evaluation and suitability of plot geometry to improve rainfall uniformity","authors":"Antônio Reynaldo de Sousa Costa, L. A. Alvarenga, M. Thebaldi, P. A. Melo, A. Colombo, J. Isidoro","doi":"10.1590/s1413-415220220198","DOIUrl":null,"url":null,"abstract":"ABSTRACT Rainfall simulators are an important tool in many areas of geosciences. The authors of most of the studies published with rainfall simulators try to get the most uniform distribution of precipitation as possible. However, since this is very difficult, indexes are used to assess the greater or lesser uniformity of precipitation in the plot area under study. One of the most used indexes is the Christiansen uniformity coefficient. In this work, changes in the geometry of the wetted area of the plot were analyzed to improve the uniformity of precipitation. This was evaluated through the intensity of precipitation and Christiansen uniformity coefficient in the wet area. The tests were carried out using two models of spray nozzles and different operating pressures. The initial plot geometry was 0.7 x 1.0 m (0.7 m2). The Christiansen uniformity coefficient results were classified as low, while the best performance in terms of precipitation uniformity was obtained at a pressure of 48.3 kPa. Non-uniform precipitation was observable near the outer limits of the plot. Based on the best Christiansen uniformity coefficient results, it was proposed to reduce the effective area of the experimental plot from 0.70 to 0.56 m2, leading to a precipitation intensity of 114.07 and 149.20 mm·h−1, and a Christiansen uniformity coefficient of 81.6 and 83.8%, with the two models of spray nozzles. The results showed that adjusting the geometry of the plot can lead, in a simple and fast way, to a better uniformity of artificial rainfall.","PeriodicalId":11619,"journal":{"name":"Engenharia Sanitaria E Ambiental","volume":"1 1","pages":""},"PeriodicalIF":0.4000,"publicationDate":"2023-04-03","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Engenharia Sanitaria E Ambiental","FirstCategoryId":"93","ListUrlMain":"https://doi.org/10.1590/s1413-415220220198","RegionNum":4,"RegionCategory":"环境科学与生态学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"WATER RESOURCES","Score":null,"Total":0}
引用次数: 0
Abstract
ABSTRACT Rainfall simulators are an important tool in many areas of geosciences. The authors of most of the studies published with rainfall simulators try to get the most uniform distribution of precipitation as possible. However, since this is very difficult, indexes are used to assess the greater or lesser uniformity of precipitation in the plot area under study. One of the most used indexes is the Christiansen uniformity coefficient. In this work, changes in the geometry of the wetted area of the plot were analyzed to improve the uniformity of precipitation. This was evaluated through the intensity of precipitation and Christiansen uniformity coefficient in the wet area. The tests were carried out using two models of spray nozzles and different operating pressures. The initial plot geometry was 0.7 x 1.0 m (0.7 m2). The Christiansen uniformity coefficient results were classified as low, while the best performance in terms of precipitation uniformity was obtained at a pressure of 48.3 kPa. Non-uniform precipitation was observable near the outer limits of the plot. Based on the best Christiansen uniformity coefficient results, it was proposed to reduce the effective area of the experimental plot from 0.70 to 0.56 m2, leading to a precipitation intensity of 114.07 and 149.20 mm·h−1, and a Christiansen uniformity coefficient of 81.6 and 83.8%, with the two models of spray nozzles. The results showed that adjusting the geometry of the plot can lead, in a simple and fast way, to a better uniformity of artificial rainfall.
降雨模拟器是地球科学许多领域的重要工具。大多数使用降雨模拟器发表的研究的作者都试图获得尽可能均匀的降水分布。然而,由于这是非常困难的,因此使用指数来评估研究地块内降水均匀性的大小。最常用的指标之一是克里斯蒂安森均匀系数。在这项工作中,分析了地块湿区几何形状的变化,以改善降水的均匀性。这是通过降水强度和湿区Christiansen均匀系数来评价的。试验采用了两种型号的喷嘴和不同的工作压力。最初的地块几何尺寸为0.7 x 1.0 m (0.7 m2)。在降水均匀性方面,在48.3 kPa压力下表现最佳,christensen均匀性系数较低。在小区外边界附近可观测到不均匀降水。根据最佳Christiansen均匀系数结果,提出将试验田有效面积从0.70 m2减小到0.56 m2,两种喷头的降水强度分别为114.07和149.20 mm·h−1,Christiansen均匀系数分别为81.6和83.8%。结果表明,调整地块的几何形状可以简单、快速地提高人工降雨的均匀性。