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1.
Tetsuo Yanagi 《Journal of Oceanography》1976,32(5):199-208
The tidal residual circulation in a bay was experimentally investigated with use of a hydraulic model. The model basin is a square bay of 5 m sides with a one-sided mouth of 1 m wide. The depth of the basin is 0.1 m. The tide of a six-minute period was provided by a tide generator of plunger type through the mouth. Tidal currents in the bay always flow in one direction though its strengths change according to the tidal phase, that is, a strong tidal residual circulation occurs in the bay. A similar flow pattern was observed to occur in a field with a horizontal boundary geometrically similar to the present model. The vorticity transfer from tidal current to residual flow is balanced with the vorticity advection of residual flow and the dissipation due to the viscosity. 相似文献
2.
Makoto Kashiwai 《Journal of Oceanography》1984,40(6):437-444
The role of the ‘tidal vortex’ in the mechanism of generation of tidal residual circulation is investigated for a bay with
a narrow entrance channel. It is shown that the circulation of residual flow is produced not by the vorticity of the inflowing
sidewall-boundary layer, but by a tidal vortex formed by rolling up of the discontinuity surface released from the flow separation
point at the entrance. This tidal vortex is affected by the circulation of the inflowing water, that is the inflowing tidal
vortex. A returning tidal vortex formed in the bay diminishes the circulation of the tidal vortex of the next generation,
while the inflowing tidal vortex formed in the open sea increases it. These cases correspond to tidal vortex life-histories
of type-II and type-III, respectively (Kashiwai, 1984a). Tidal vortices of each life-history type have different strength
and produce residual circulation of different strength, corresponding to each type. The ratio of kinetic energy of residual
flow to that of the tidal current through the bay entrance, that is to say the energy gain of the residual circulation, is
proportional to the reciprocal of the Strouhal number, and its rate of increase depends on the life-history type of the tidal
vortex. This explains the experimental observation reported by Oonishi (1977) and Yanagi (1978) that the energy ratio of residual
flow to tidal flow increases with the Reynolds number not monotonously but goes through a maximum and a minimum at intermediate
Reynolds number. 相似文献
3.
Two new types of mechanism for the generation of tidal residual flow are revealed with the use of a hydraulic model experiment. A remarkable anticlockwise tidal residual circulation is formed in a model bay due to the presence of a tidal current, the Coriolis force and a horizontal boundary. A similar circulation is also formed due to the presence of a bottom slope, a horizontal boundary and a tidal current which flows normal to the inclination of the bottom slope. The residual circulation in the Sea of Iyo in the Seto Inland Sea is considered to be due to a combination of the effects of the Coriolis force, a bottom slope, a horizontal boundary and the tidal current. We classified some of the generation mechanisms of tidal residual flow which have been described to date into seven types on the basis of vorticity considerations. 相似文献
4.
Tidal residual circulation produced by a tidal vortex 总被引:1,自引:0,他引:1
Makoto Kashiwai 《Journal of Oceanography》1984,40(4):279-294
“TIDAL VORTEX” is a term for a kind of starting vortex formed as a pair of vortices at the head of a tidal jet emanating from
a narrow entrance into a bay. In this study, its formation and movement have been investigated by means of a hydraulic experiment
and an analytical model. A tidal vortex is formed as a result of flow separation at the abrupt widening of a channel entrance
followed by rolling up of the discontinuity surface around its free end. The vortex shows three types of life-history (type
I, II and III), which are characterized by the Strouhal number and the aspect ratio of the horizontal shape of the entrance
channel. In the case of type-I, the tidal vortex proceeds toward the inner region of the bay and there amalgamates with successive
vortex cores into a core of tidal residual circulation. In the case of type-II, the tidal vortex core flows out into the entrance
channel on the ebb but returns back into the bay on the subsequent flood. And, in the case of type-III, the tidal vortex core
which was formed on the bay-side opening of the entrance channel flows out to the open sea and never comes back, whereas the
core which was formed on the open-sea side of the entrance flows into the bay and never flows out. The circulation of a tidal
vortex core is proportional to the reciprocal of the Strouhal number. The movement of the core near the bay entrance is determined
by interaction between the cores and transportation due to the irrotational component of the tidal current. There are three
types of tidal residual circulation, corresponding to three life-history types of tidal vortices. In the case of type-I, a
strong tidal residual circulation is formed, but in type-II a small and weak circulation is formed. While, in type-III, the
circulation having an inverse sense of rotation to that of type-I is formed. 相似文献
5.
Makoto Kashiwai 《Journal of Oceanography》1985,41(1):1-10
A self-excited oscillation of tidal flow occurs in a tidal channel-basin system with a narrow and high speed inflowing tidal jet. The mechanism of this oscillation was examined through hydraulic experiments. Results show that the oscillation is caused by alternation in the strength of asymmetric residual circulation caused by a biased supply of vorticity by asymmetric tidal vortex pairs, and that the mechanism of alternation also depends on negative feed-back between the residual circulation and the vorticity supply.The unstable state of the flow suggested the possibility of controlling the tidal current and tidal exchange in the channel-basin system and this was confirmed experimentally. Under fixed tidal conditions and with fixed basin dimensions, the tidal residual circulation was controlled to form two strong clockwise and anticlockwise circulations or a single circulation by changing the shape of the bay entrance. 相似文献
6.
湄洲湾是福建省中部沿海的港湾,湾内三面为大陆所环抱,湾口朝向东南进入台湾海峡。该湾呈西北向深入内陆约18nmile,湾口有湄洲岛作为屏障和标志,使整个湾口分成文甲口门(北口宽约0.65nmile)和剑屿-鹅尾山口门(南口,宽约5.61nmile)两个口门,距湾口约5nmile的盘屿、大竹等岛屿及距湾口约12nmile的屿、横屿等岛屿为湾内两道屏障,再往内为内沃。屿和横屿间水面宽约0.51nmile,水深约20m,它和北端肖厝-秀屿及南端峰尾-西亭深槽相连接,是该湾的主航道(图1)。该湾航道宽阔水… 相似文献
7.
在胶州湾湾口、西侧、中心、东侧、北侧湾顶五个区域布设测站,利用2018年冬季至2020年秋季潮位、海流等监测数据,基于最小二乘法进行调和分析计算,并结合垂线平均流速流向、可能最大流速、水质点可能最大运移距离等计算模型,研究分析了胶州湾海流特征。结果表明,各区域潮流类型系数均小于0.5,M2分潮椭圆率绝对值均不超过0.1,接近于0,故胶州湾潮流性质为正规半日潮流,潮流运动形式以往复型为主。湾口区域余流、可能最大流速、水质点可能最大运移位移均最大。不同季节余流流速和流向的差异没有明显的规律性,除湾区西侧测站外,其余位置不同季节余流流向整体上有固定朝向:湾口处东偏北、中心站西偏北、东侧站南偏东、北侧湾顶站东偏北。靠近岸边的湾口、东侧和北侧湾顶站余流流向与邻近海岸垂直。在垂直方向上,各测站可能最大流速和水质点可能最大运移距离由表层至底层整体上呈减小趋势,流向基本一致。 相似文献
8.
Hideichi Yasuda 《Journal of Oceanography》1980,35(6):241-252
The tidal residual current is produced by a non-linear effect caused by flow separation of the tidal current due to a complicated coastline. This paper shows that the similar non-linear effect is produced also by the coastal boundary layer with a theoretical model having a simple coastline. It is found that the shear of the tidal oscillatory current produces the non-linear effect and its longitudinal gradient generates the tidal residual current flowing from the bay head to the bay mouth inside the boundary layer or shear region. The velocity of the residual current is proportional to the square of tidal current amplitude. Consideration of the generating mechanism suggests that the tidal residual current is generated by the change in depth of the bay. 相似文献
9.
基于FVCOM的廉州湾及周边海域三维潮汐潮流数值模拟(英文) 总被引:1,自引:0,他引:1
基于采用不规则三角网格和有限体积方法的FVCOM模式,建立廉州湾三维潮流数值模型来重现廉州湾及周边海域的潮位和潮流变化状况。根据模拟结果计算得到了较以往更为精细的廉州湾及周边海域K1、O1和M2分潮的同潮图,并计算了由此三个分潮引起的潮汐不对称的变化情况。K1和O1分潮在廉州湾外主要以驻波的形式存在,进入廉州湾后转化为前进波;M2分潮在廉州湾外主要以前进波的形式存在,进入廉州湾后前进波特征更为明显。K1和O1分潮流在廉州湾外以旋转流为主,在廉州湾内以往复流为主;M2分潮流在整个研究海域以往复流为主。由潮余流场的分布特点可以看出自南向北由外海进入廉州湾的潮余流,在冠头岭处分为两支,一支逆时针转向西,另一支被冠头岭阻挡在其南侧形成顺时针封闭环流。在廉州湾内部同时存在两个环流系统,湾顶的气旋式环流和口门处的反气旋式环流。 相似文献
10.
基于FVCOM的廉州湾及周边海域三维潮汐潮流数值模拟 总被引:1,自引:0,他引:1
基于采用不规则三角网格和有限体积方法的FVCOM模式,建立廉州湾三维潮流数值模型来重现廉州湾及周边海域的潮位和潮流变化状况。根据模拟结果计算得到了较以往更为精细的廉州湾及周边海域K1、O1和M2分潮的同潮图,并计算了由此3个分潮引起的潮汐不对称的变化情况。K1和O1分潮在廉州湾外主要以驻波的形式存在,进入廉州湾后转化为前进波;M2分潮在廉州湾外主要以前进波的形式存在,进入廉州湾后前进波特征更为明显。K1和O1分潮流在廉州湾外以旋转流为主,在廉州湾内以往复流为主;M2分潮流在整个研究海域以往复流为主。由潮余流场的分布特点可以看出自南向北由外海进入廉州湾的潮余流,在冠头岭处分为两支,一支逆时针转向西,另一支被冠头岭阻挡在其南侧形成顺时针封闭环流。在廉州湾内部同时存在2个环流系统,湾顶的气旋式环流和口门处的反气旋式环流。 相似文献
11.
基于MIKE21的HD模型,通过模拟得到胶州湾的潮流场,胶州湾在涨急时最大流速1.04m/s,落急时最大流速约为0.96m/s。胶州湾余流总体较小,平均为0.03m/s左右。并在湾内不同位置释放自由粒子,以MIKE21的Particle tracking模型计算出其在潮流作用下的运移轨迹,结果表明粒子大多数运移到湾内近岸区域,少部分在湾口区域附近;在潮流场基础上计算了欧拉余流场,并和粒子运移结果进行对比,表明欧拉余流场在区域流向比较一致时可以表示粒子运动的趋势,为物质迁移、控制污染等方面提供了一定的参考借鉴意义。 相似文献
12.
为掌握莱州湾潮余流特征和粒子运移特征,文章采取平面二维数值模拟的方法,计算得到莱州湾的潮流场,并分析潮流结构;在潮流场的基础上,计算和分析欧拉余流场;通过在不同位置释放自由运动的粒子,得到潮流作用下自由运动粒子的运移轨迹。研究结果表明:莱州湾涨潮时的最大流速约为2.19 m/s,落潮时的最大流速约为2.66 m/s,且均在湾口处出现最大流速;莱州湾欧拉余流速度较小,且湾口附近较大而湾内较小;莱州湾分布均匀的粒子在自由运移时出现不同程度的聚集,且整体运移趋势是向岸聚集。 相似文献
13.
依据锦州湾12个站点现场实测海流资料(1991年6月和8月二个航次)和潮流场数值模拟结果,获得了该湾潮流和余流的分布规律。并基于41个站点重矿物鉴定资料,给出了重矿物分布规律和矿物类型分区。结果表明,该湾潮流具有潮驻波特征。总的流动趋势为涨潮时从湾口南岸朝西北方向流入湾内,落潮时朝东南向流出湾外,葫芦岛—大酒篓北侧是锦州湾潮流主要通道和强流区,最大涨、落潮流流速在1kn以上。湾内余流随湾形按逆时针方向流动,湾口北部最强余流可达16cm/s。流场的强弱分布与重矿物的类型分区密切相关,经分析研究得出了重矿物与流场之间的定量分配关系。 相似文献
14.
基于2017年春季和冬季的海流资料分析了红海湾海区海流特征、潮流状况、涨落潮流特性、余流特征及表层漂流特征。研究海域共布设3个临时潮位观测站和11个全潮水文观测站。根据流速、流向过程曲线和潮位过程曲线的关系,得出涨(落)潮流速最大的时刻和最小流速发生时刻与潮位关系并非固定在高(低)潮时或半潮面左右,由此看出,研究海域的潮波介于驻波与前进波之间,属于不规则半日潮流主导的海域。研究海域中大部分站位潮流属于往复流,少数站位潮流运动具有一定的旋转性,平均涨潮流速最大为7 cm/s,平均退潮流速最大为14 cm/s。春季大潮期和中潮期各站余流流向整体为偏东向,小潮期,除少数测站余流流向偏向南东向,其余测站余流流向偏西向;冬季大潮期和中潮期各站余流流向整体为偏西向,小潮期,湾西侧余流流向偏西向,湾东侧余流流向偏南东向。垂向上各层余流流速由表至底逐渐减小,流向基本一致。 相似文献
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16.
In order to determine why the sedimentation to supply ratio of nutrients in Tokyo Bay is markedly small, the nitrogen budget was investigated for 1979, when a systematic and continuous observation of flow and salinity was carried out. The data were analyzed by use of a simple advective-diffusive box model and dissolved oxygen balance in the lower layer was also examined. The calculated values of two-layer flow, settling, primary production, mineralization, denitrification, and dissolved oxygen consumption were comparable to those observed.The factors making the sedimentation to supply ratio makedly small were summarized as: 1) a strong and stable two-layer flow generated by a large freshwater supply, 2) further intensification of this two-layer flow by the northern winter monsoon, 3) coincidence of the discharge region with the supply region of nutrients caused by the transverse inclination of the interface, probably due to the earth's rotation. 4) effective discharge of nutrients from the bay due to a strong tidal flow and a possible cyclonic tidal residual circulation in the inner bay mouth, 5) incomplete consumption of nutrient salts by phytoplankton in the upper layer even in the most productive season, and 6) possible denitrification in the anaerobic bottom water in summer and in the bottom sediment itself throughout the year in the inner bay. 相似文献
17.
横向流 (垂直于海湾主轴方向的流动) 对横向动量以及物质分布具有重要影响。已往研究表明,潮汐应变对横向流的垂向空间结构具有重要的调控作用。但这种认识仅局限于强层化海区,弱层化条件下潮汐应变对于横向流空间结构的影响仍未可知。为此,本文以象山港为例,基于实测数据阐释了弱层化条件下潮汐应变对横向流及其余环流垂向空间结构的调控作用。结果显示,象山港内湾横向流的垂向空间结构随大小潮呈现出明显的变化规律。大潮时,潮汐应变现象明显,涨潮时较强的垂向混合使得横向流在高潮阶段呈现出一层结构;落潮时垂向混合较弱,横向流在低潮时呈现两层结构。小潮时,潮汐应变受到抑制,垂向混合在涨落潮时均较弱,因此横向流在高低潮阶段均呈现出两层结构。经过潮时均进一步得到的横向余环流呈现出上层向南、下层向北的两层结构。由于潮汐应变的大小潮变化,横向余环流的反转深度反转点自大潮到小潮呈现出上升的趋势。 相似文献
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利用已经过验证的高分辨率三维海洋动力模型FVCOM,根据1984—2014年内伶仃洋的围填海变化情况,结合情景模拟案例,研究分析围填海对伶仃洋水流动力的影响,探究截流式和顺流式围填海对伶仃洋不同季节的水平余流场、垂向环流结构以及潮汐变化过程的影响。研究结果表明,围填海对伶仃洋的余流流向没有明显影响,但对余流速有较大的影响。在水平方向上,截流式围填海使得周边海域的余流速明显增大,增幅在0.02~0.25 m/s不等,其中口门区域受到的影响最大;相较于底层流场,表层流场受围填海的影响相对更大,围填海以南的较远海域在表层出现一条强度逐渐减弱的流速减小带,减幅在0.02~0.15 m/s不等,且影响范围与流场的分布密切相关,在夏季向南延伸,在冬季向西南延伸。顺流式围填海的影响则主要分布在伶仃洋两侧沿岸,并且不同季节的影响特点有一定区别,在夏季使得内伶仃洋东岸海域流速增大,但在冬季使其流速减小,变化幅度均在0.02 m/s以上。在垂直方向上,围填海使口门区域余流的纵向流速梯度增加,并且改变了伶仃洋余流的垂向分布情况,总体表现为远离围填海的海域表、底层余流的流速减小,中上层余流的流速增大;与此同时,围填海大幅度改变了周边海域的横向流速,并且在伶仃水道、矾石水道等区域产生了新的横向环流。围填海使得河口至围填海的余水位明显上升,使得伶仃洋海域的余水位下降,余水位梯度的增大是围填海周边余流速增大的主要原因。另外,围填海影响了伶仃洋的潮汐变化过程。在大潮期间,围填海改变了伶仃洋海域涨落潮时的潮流流速,使得周边海域落急流速增加,较远海域落急流速减小,而涨急流速都减小;同时,围填海使得海域涨落潮时的潮位受到一定影响。围填海最终使得伶仃洋的潮汐相位提前了20~35 min。 相似文献