In this study, a mathematical model has been developed that can compute various hydrodynamic characteristics of a multiple-row curtainwall-pile breakwater. To examine the validity of the developed model, laboratory experiments have been conducted for double- and triple-row breakwaters with various combinations of drafts of curtain walls, porosities between piles, and distances between rows. Comparisons between measurement and prediction show that the mathematical model adequately reproduces most of the important features of the experimental results. As a whole, the transmission coefficient decreases with an increase in relative water depth, whereas the reflection coefficient, normalized run-up and force exhibit an opposite trend in their variations. With fixed values of the draft of the curtain wall and the porosity of lower perforated part of the first row of a double-row breakwater, as these values of the second row increase and decrease, respectively, the transmission coefficient decreases, as expected. On the other hand, their effects on wave reflection, run-up, and wave force change with the relative depth. As for the distance between the rows, the transmission coefficient becomes a maximum when it is about one half of the wave length, suggesting that this condition should be avoided to achieve the advantage of the breakwater in reducing wave transmission. It is shown that for prototype breakwaters, on an average, the transmission coefficient would be smaller than 0.3 for wave periods less than 6.0 s, and it would be about 0.45 even for the wave period of 9.0 s, although there would be a variation depending on the geometry of the breakwater. It is also shown that wave transmission is significantly reduced by multiple-row breakwaters compared with a single-row breakwater, while the difference between double-row and triple-row breakwaters is marginal. Finally, engineering monograms are provided for double-row breakwaters to be used in practical engineering applications of the breakwaters. 相似文献
Boron is an essential, widely used, micronutrient element and is abundant in salt lakes on the Qinghai-Tibet Plateau. The origin and distribution of boron brine deposits on the Qinghai-Tibet Plateau is an important foundation for B resource formation, evolution, and enrichment, which have long been the subject of debate. The boron isotope system is a sensitive geochemical tracer, making it useful for effectively and precisely tracking a wide range of geological processes and sources. This study investigates the major cations, [B], and δ11B values of samples (lake brine, river waters, and cold spring water) from the Bangor Co Lake which is a typical salt lake rich in boron in Tibet, China. There are magnitude-scale differences in [B] among different sample types: river samples < cold spring water < < brine lakes. [B] values vary from 0.73 to ~ 1113 mg/L. Similar to [B], the δ11B values of the samples exhibit magnitude-scale variations as [B], ranging from − 7.35‰ to + 7.66‰. There are also magnitude-scale differences in δ11B among different sample types. The δ11B values of cold spring water are relatively low, and the values range from − 1.26‰ to -7.75‰. However, the river water samples and saline lakes have higher values, from 0.38‰ to 4.62‰, and the δ11B values of river water samples are basically in the distribution range of those of Bangor Co Lake. This indicates that the sources of boron in Bangor Co Lake are mainly the recharge water with higher δ11B values and spring water with lower δ11B values, and the boron sources and the uneven mixing of lake water are two reasons that account for the large change in the δ11B value of Bangor Co Lake.