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直立式双板桩防波堤是一种对深水软土地基有较强适应性的防波堤结构,但是目前尚无系统的设计方法。本文以某外海深水直立式双板桩防波堤为例,分别采用国内规范和日本规范给出的方法计算直立式双板桩防波堤的入土深度和桩身内力。结果表明,中日规范在直立式双板桩防波堤的设计中均有一定的局限性:对于国内规范,当堤顶宽度较小时,其墙后主动土压力的计算会与实际情况有较大差别;对于日本规范,当堤顶宽度较大时,墙后填土产生的抵抗弯矩不符合实际情况。由此,对直立式双板桩防波堤的设计,建议同时采用中日两种计算方法进行设计并相互验证,共同拟定合理的结构断面。 相似文献
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斜搜式防波堤港内一侧为直立式码头的结构型式在我国已多见使用。为了减小波浪穿过堤面和堤心后对直立式码头产生的波压力,从而减小防波堤和码头结构的断面,本文试验研究了几种■荷措施。试验结果表明,设置透空导流排水孔的直墙上的波压力显著地减小。 相似文献
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为使防波堤同时具有良好的掩护效果和水体交换能力,提出了两种带有透浪通道的新型直立式防波堤。基于Fluent求解器建立了三维数值波浪水槽,通过与试验结果对比,验证了该数值水槽求解波浪与透空堤作用具有较高的精度。对两种防波堤在规则波作用下的透浪特性进行了研究,结果表明:透射系数K_t与透空率呈正线性相关,且可通过调整透浪通道间距,使相同透空率下K_t降低20%~30%。对同一结构,K_t随相对波长的增大而显著增大,但受相对波高的影响较小。在透空率大于0.16后,异型沉箱防波堤的消浪性能明显优于错位沉箱。基于数值计算结果,给出了以上两种透空堤波浪透射系数的经验公式。 相似文献
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本文通过室内试验,对砌石护面斜坡堤上直立式防浪胸墙墙顶设置挑浪嘴的挑浪效应进行了探讨。文中研究了挑浪嘴尺寸、墙顶超高与挑浪效果的关系;挑浪嘴引起的波压力变化及其对胸墙稳定的影响等,并根据实测数据,经统计分析,得出了它们之间的经验关系式,可供设计挑浪嘴的尺度时作参考。 相似文献
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分层斜坡越浪式波能发电装置作为一种重要的波能转换型式,在开发利用波浪能的同时,可与防波堤或护岸工程相结合,将海岸工程的被动消能变为主动吸能,提高综合效益。在实际工程应用中,分层斜坡越浪式发电装置引浪面在波浪荷载作用下的安全性成为首要问题,由于其引浪面与防波堤或护岸的护面对水体磨阻影响不同,因此水体对结构的作用力不同,已有的斜坡式防波堤所受波浪荷载的研究无法用于指导分层斜坡越浪式发电装置引浪面的结构强度设计。通过水工物理模型试验,对分层越浪装置引浪面在不同波况条件下的结构受力进行研究分析,获得越浪装置引浪面上点压力及波浪力的分布规律,为装置的结构设计提供理论指导及设计支持。 相似文献
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对国内第一个岛屿地形下核电厂的护岸防洪设计进行了研究,提出直立式护岸结构方案以满足核电厂防洪和避让毗邻海岛的要求。在波浪数值模拟计算结果基础上,开展了波浪整体物理模型试验、波浪局部整体物理模型试验和波浪断面物理模型试验,对护岸的越浪量和结构稳定性进行了优化验证。研究结果表明,岛屿地形下,波浪破碎和波能集中导致护岸堤身坡脚处波高增大,须加高挡浪墙和优化挡浪墙结构型式;在相同的越浪量标准下,采用直立堤结构相对斜坡堤结构对应的护岸挡浪墙的高程须明显加高;利用部分海岛地形斜坡高地作为厂区护岸一部分时,原状海岛地形斜坡高地处的波浪爬高效应明显,须加高邻近护岸挡浪墙的高程。 相似文献
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底部透空不透水建筑物是近海工程中的一种新型结构,与传统水工建筑物相比,其能灵活适应基床不发生变形、阻止波浪进入后方造成破坏。本文通过构建物理模型,在波浪水槽中进行试验,测试了底部透空不透水直立建筑物不规则波作用,得到了不同水深、相同波浪要素时,该型直立建筑物迎浪面和底面的水平总力最大时各测点正向波压力和负向波压力数据。对比分析了不同水深下底部透空不透水直立建筑物的水平总力及垂直力,总结了波峰和波谷作用下波浪力沿建筑物表面的分布规律,可为海岸工程结构设计提供依据。 相似文献
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为研究不同波浪环境下,水底浮泥层产生泥沙悬扬后其浓度的分布特性,使用浊度计测定浊度的方法确定水体中泥沙的浓度,并在水槽实验中改变水深、浮泥厚度及造波机的频率和振幅,观察水槽中悬浮泥沙浓度的变化情况,获得水深、波浪频率、波幅以及浮泥厚度对底床泥沙悬扬的影响,分析泥沙浓度的垂向分布特征等。实验结果显示,水深对底床泥沙悬扬的影响最为显著,其他实验参数的影响均不十分显著。同时,通过垂向输沙平衡的分析,得到一个可描述泥沙垂向浓度分布的理论公式,并利用水槽实验结果进行验证。对比结果显示,理论公式所得曲线与实验结果曲线变化趋势一致,部分工况下,理论值稍稍偏大。 相似文献
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In this article, tsunamis represented as solitary waves was simulated using the fully nonlinear free surface waves based on Finite Element method developed by Sriram et al. (2006). The split up of solitary wave while it propagates over the uneven bottom topography is successfully established. Wave transmission and reflection over a vertical step introduced in the bottom topography is in good agreement with the experimental results from Seabra-Santos et al. (1987). The wave transformation over a continental shelf with different smooth slopes reveals that the solitary wave reflection increases while the continental slope varies from flat to steep. The interaction of the solitary wave with a vertical wall for different wave steepness has been analysed. The reflected shape of the profile is in good agreement with the observation made by Fenton and Rienecker (1982) and an increase in wave celerity is observed. 相似文献
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From the experimental studies in recent years, it has become known that when a wave breaks directly on a vertical faced coastal structure, high magnitude impact pressures are produced. The theoretical and experimental studies show that the dynamic response of such structures under wave impact loading is closely dependent on the magnitude and duration of the load history. The dynamic analysis and design of a coastal structure can be succeeded provided the design load history for the wave impact is available. Since these types of data are very scarce, it is much more convenient to follow a method which is based on static analysis for the dynamic design procedure. Therefore, to facilitate the dynamic design of a vertical plate that is exposed to breaking wave impact, a multiplication factor called “dynamic magnification factor” is herein presented which is defined as the ratio of the maximum value of the dynamic response to that found by static analysis. The computational results of the present study show that the dynamic magnification factor is a useful ratio to transfer the results of static analysis to the dynamic design of a coastal plate for the maximum impact pressure conditions of pmax/γH0≤18. 相似文献
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通过正向与斜向波浪对半圆型防波堤(不开孔出水堤)的实验研究,给出了其水力特性及单位堤长所受的无因次水平波浪力、竖向波浪力和波浪浮托力随各主要影响因素的变化规律,特别指出了斜向波浪力可大于正向波浪力及水平波浪力中波谷作用大于波峰作用发生的条件。 相似文献
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Regular and irregular wave forces acting on vertical walls are studied by a previously developed numerical model. The computed wave forces are compared with the available experimental data to verify the numerical model, and satisfactory agreements are obtained. The variation of wave forces with incident angles and the shape of simultaneous pressure distribution are investigated, and the comparisons between numerical results and Goda' s predictions are also carried out. It is concluded that the maximum wave forces acting on the unit length of vertical wall is often induced by the obliquely incident waves instead of normally incident waves, while Goda' s formula may be inapplicable for oblique wave incidence. The shape of simultaneous pressure distribution is not significantly influenced by incident angles, and it can be favorably predicted by Goda' s formula. When regular wave heights are taken as the same as irregular wave height H1%, the irregular wave forces Ph. 1% are slightly larger than regular wave forces in most cases. 相似文献
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Kern E. Kenyon 《Journal of Oceanography》2004,60(6):1045-1052
Freely propagating surface gravity waves are observed to slow down and to stop at a beach when the bottom has a relatively gentle upward slope toward the shore and the frequency range of the waves covers the most energetic wind waves (sea and swell). Essentially no wave reflection can be seen and the measured reflected energy is very small compared to that transmitted shoreward. One consequence of this is that the flux of the wave’s linear momentum decreases in the direction of wave propagation, which is equivalent to a time rate of change of the momentum. It takes a force to cause the time rate of change of the momentum. Therefore, the bottom exerts a force on the waves in order to decrease the momentum flux. By Newton’s third law (action equals reaction) the waves then impart an equal but opposite force to the bottom. In shallow (but finite) water depths the wave force per unit bottom area is calculated, for normal angle of incidence to the beach, to be directly proportional to the square of the wave amplitude and to the bottom slope and inversely proportional to the mean depth; it is independent of the wave frequency. Constants of proportionality are: 1/4, the fluid density and the acceleration of gravity. Swell attenuation near coasts and some characteristics of sand movement in the near-shore region are not inconsistent with the algebraic structure of the wave force formula. Since the force has a depth variation which is significantly faster than that of the dimensions of the particle orbits in the vertical direction, the bottom induces a torque on the fluid particles that decreases the angular momentum flux of the waves. By an extension of Newton’s third law, the waves also exert an equal but opposite torque on the bottom. And because the bottom force on the waves exists over a horizontal distance, it does work on the waves and decreases their energy flux. Thus, theoretically, the fluxes of energy, angular and linear momentum are not conserved for shoaling surface gravity waves. Mass flux, associated with the Stokes drift, is assumed to be conserved, and the wave frequency is constant for a steady medium. 相似文献
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Li Chunzhu Shi Hongda Yu Dingyong Wang Aiqun
Professor Engineering College Ocean University of Qingdao Qingdao
Lecturer Engineering College Ocean University of Qingdao Qingdao
Senior Engineer Engineering College Ocean University of Qingdao Qingdao 《中国海洋工程》1997,(1)
Standing waves are formed due to the reflection when waves meet vertical wall,thereforestrong structures are needed to keep the wall stability under the serious wave attack.For the improvementof the working condition and increase of the stability of the wall,the lower reflecting breakwaters have at-tracted close attention Reports mostly from Japanese researchers are often concerned with the wall ofcaisson equipped with open windows.In this paper a kind of hollow-pipe perforated breakwater is exam-ined which waves may partially perforate into the harbour basin.The wave in front of the wall can onlyform partial standing wave and wave force is reduced obviously.And the theoretical calculation of waveforce and analysis of wave force spectrum are all derived.Comparison between the results from theoreticalcalculation and hydraulic modeling shows reasonable agreement. 相似文献