Prediction of water level at Huayuankou station based on rating curve.

IF 3.8 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2024-09-07 DOI:10.1038/s41598-024-71510-3

Ming Li, Zhao Zheng, Chaojie Niu, Liyu Quan, Chengshuai Liu, Xiang Li, Chen Shi, Dongyang Li, Lianjun Zhao, Shasha Han, Caihong Hu

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Abstract

The construction of large reservoirs has modified the process of water and sediment transport downstream, resulting in changes in the morphology of the river cross-section. Changes in water and sand transport and cross-sectional morphology are reflected in the rating curve at the cross-section. This study analyzed the variations in the rating curve at the Huayuankou (HYK) section and their influencing factors, and conducted water level predictions based on this relationship. The findings revealed that while the annual mean water level has shown a declining tendency over the past 20 years, the annual mean discharge has shown a constant pattern. The rating curve at this stretch narrowed from a rope-loop type curve in its natural condition to a more stable single curve as a result of the construction of the dam upstream of the HYK section. The effect of pre-flood section morphology and the water-sediment process on the scattering degree of the rating curve is inverse; increasing roughness and hydraulic radius decreases scattering degree, while increasing sand content and sand transport rate increases scattering degree. Using the measured data from 2020 as an example, the feasibility of predicting cross-sectional water levels using the rating curve was verified. The prediction results were accurate when the flow was between 1000 and 2800 m³/s; However, when the flow was between 2800 and 4000 m³/s, the forecast results were typically slightly lower than the measured values. Overall, the method demonstrates good predictive accuracy. Insight from the method can be used to predict water levels to better inform decision making about water resources management, and flood emergency response in the lower Yellow River.

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根据等级曲线预测花园口站的水位。

大型水库的修建改变了下游的水沙输运过程，导致河流断面形态发生变化。水沙输移和断面形态的变化反映在断面的等级曲线上。本研究分析了花园口（HYK）断面额定曲线的变化及其影响因素，并在此基础上进行了水位预测。研究结果表明，在过去的 20 年中，年平均水位呈下降趋势，而年平均排水量则呈恒定模式。由于在 HYK 河段上游修建了大坝，该河段的水位曲线从自然状态下的绳圈型曲线变窄为更加稳定的单曲线。汛前断面形态和水沙过程对等级曲线散度的影响成反比；粗糙度和水力半径增大，散度减小，而含沙量和输沙率增大，散度增大。以 2020 年的实测数据为例，验证了利用等级曲线预测断面水位的可行性。当流量在 1000 至 2800 立方米/秒之间时，预测结果准确；但当流量在 2800 至 4000 立方米/秒之间时，预测结果通常略低于实测值。总体而言，该方法具有良好的预测准确性。该方法可用于预测水位，为黄河下游的水资源管理决策和洪水应急响应提供更好的信息。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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