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Experimental Modeling of Horizontal and Vertical Wave Forces on an Elevated Coastal Structure. 高架海岸结构上水平和垂直波浪力的实验模型。
Pub Date : 2017-10-01
Hyoungsu Park, Tori Tomiczek, Daniel T Cox, John W van de Lindt, Pedro Lomonaco

A large-scale physical model was created in Oregon State University's Large Wave Flume to collect an extensive dataset measuring wave-induced horizontal and vertical forces on an idealized coastal structure. Water depth was held constant while wave conditions included regular, irregular, and transient (tsunami-like) waves with different significant wave heights and peak periods for each test. The elevation of the base of the test specimen with respect to the stillwater depth (air gap) was also varied from at-grade to 0.28 m above the stillwater level to better understand the effects of raising or lowering a nearshore structure on increasing or decreasing the horizontal and vertical wave forces. Results indicate that while both horizontal and vertical forces tend to increase with increasing significant wave height, the maximum and top 0.4% of forces increased disproportionally to other characteristic values such as the mean or top 10%. As expected, the horizontal force increased as the test specimen was more deeply submerged and decreased as the structure was elevated to larger air gaps above the stillwater level. However, this trend was not true for the vertical force, which was maximized when the elevation of the base of the structure was equal to the elevation of the stillwater depth. Small wave heights were characterized by low horizontal to vertical force ratios, highlighting the importance of considering vertical wave forces in addition to horizontal wave forces in the design of coastal structures. The findings and data presented here may be used by city planners, engineers, and numerical modelers, for future analyses, informed coastal design, and numerical benchmarking to work toward enabling more resilient nearcoast structures.

在俄勒冈州立大学的大型波浪水槽中建立了一个大型物理模型,以收集大量数据集, 测量波浪对理想化海岸结构的水平和垂直作用力。水深保持不变,而波浪条件包括规则波浪、不规则波浪和瞬时波浪(类似海啸),每次试验都有不同的显著波高和峰值周期。为了更好地了解升高或降低近岸结构对增大或减小水平和垂直波力的影响,还改变了试样基 部相对于静止水深的高度(气隙),从地面到静止水位以上 0.28 米不等。结果表明,虽然水平力和垂直力往往会随着显著波高的增加而增加,但最大值和最高 0.4%的力的增加与其他特征值(如平均值或最高 10%)不成比例。正如预期的那样,水平力随着测试样本浸没更深而增加,随着结构升高到静水水位以上更大的空气间隙而减小。然而,垂直力却不是这种趋势,当结构底部的高度等于静水深度的高度时,垂直力最大。小波高的特点是水平力与垂直力的比值较低,这突出了在沿岸结构设计中除了考虑水平 波力外,还要考虑垂直波力的重要性。城市规划者、工程师和数值建模人员可以利用本文的研究结果和数据进行未来的分 析、海岸设计和数值基准测试,以提高近岸结构的抗冲击能力。
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Coastal engineering
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