海上溢油油膜厚度实验室模拟和理论模型对比研究

溢油量是衡量溢油规模的关键指标,是处理溢油事故的重要依据。油膜厚度是确定溢油量的基本前提,是一个尚未解决的国际难题。实验室中模拟了不同阶段和不同环境条件下扩展油膜的厚度变化特征。结果表明,实验室模拟与理论模型分析具有基本一致的变化趋势,扩展速度与扩展时间成反比;温度是影响油膜厚度的重要因素,相同条件下,温度越高,油膜厚度越小;海水盐度会影响溢油扩展,但这种影响并未延伸到对油膜厚度的控制上。由于实验室模拟限定在平静海面条件下,并未考虑风和海流等扩展中不容忽视的因素,故与理论构建模型相比系数相差较大。通过对比分析,前期构建的理论模型更能准确地反映海洋溢油的实际情况,加之在实例验证中的较高准确性,该模型具有业务化实施和广泛推广的潜力。     

海上溢油量获取的技术方法

海上溢油近年来已成为恶化海洋生态环境、导致重大海洋资源损失的一种重要海洋灾害.海面溢油量是评价海上溢油事故威胁程度和确定溢油事故等级的重要指标,而溢油面积和油膜厚度的准确获得是评估溢油量的基础.文中系统总结了当今国内外海洋溢油面积和油膜厚度的监测方法,认为航空遥感和卫星遥感技术是获取海上油膜面积的有效手段,基于光学遥感和超声波原理的激光声学遥感器是最具发展潜力的油膜厚度测量技术.此外,通过构建油膜扩展模型来估算油膜厚度也不失为一种简单而有效的方法,其最大特点是应用范围广,不受时空、气候条件影响,实例分析验证结果有很高的准确性(高达96％),这种方法将有望于业务化监测运行来获取油膜厚度,从而比较准确地获得溢油量.     

海面溢油无人机高光谱遥感检测与厚度估算方法

海上溢油是海洋国家所面临的共同问题,但至今仍没有一种可靠实用的海上溢油准确识别和油量遥感监测方法。为此,本文以无人机高光谱遥感为手段,开展了海面溢油检测与厚度估算方法研究。实验中,通过搭建室外大型水槽溢油实验装置,获取了模拟真实海洋环境条件下不同溢油量的遥感和现场光谱数据,在此基础上,分析并提取了海上溢油特征光谱波段,给出了海上溢油高光谱检测模型;针对现场实验条件下水面油膜厚度难以测定的问题,设计了3种利用总体溢油量的油膜厚度估算模型。得到如下主要结论:（1）675 nm和699 nm是海上溢油检测的有效特征波段,但对极薄的油膜没有检测能力;（2）提出了归一化溢油指数模型、反比例模型和吸收基线模型等3种海上溢油油膜厚度估算模型,其中对于薄油膜（厚度≤ 5 μm）和厚油膜（厚度>50 μm）,反比例模型是溢油厚度反演的首选也是唯一选择。对于中厚度油膜,晴朗天气条件下,归一化溢油指数模型是油膜厚度反演的首选,同时反比例模型和溢油吸收基线模型也都有较好的反演能力,而在多云天气条件下,反比例模型效果最佳。     

基于自扩展深度置信网络的原油油膜绝对厚度反演研究

海上溢油事故危害海洋生态安全、人类健康与经济发展.开展基于遥感技术的海面溢油量的估算研究,对于保护海洋生态环境具有重要意义,而油膜厚度反演是溢油量估算的核心环节.本文通过搭建室外实验场景,模拟真实海面溢油环境,基于现场实测高光谱遥感数据,开展海面溢油厚度反演研究.本文将深度学习与遥感技术融合,提出了基于自扩展深度置信网...     

基于GF-1卫星的海上溢油定量监测——以青岛溢油事故为例

基于GF-1卫星数据对2013年11月22日青岛黄潍输油管道爆炸造成的海面溢油进行定量监测。研究首先采用2013年11月26日GF-1卫星数据对海面溢油进行提取,其统计面积为0.67 km2;其次,结合肖剑伟提出的油膜厚度单波段反演模型估算油膜厚度,最终计算得到溢油量为0.28 t;最后,对Band 1反射率与油膜厚度结果进行灰度分割,将溢油污染程度分为6级,对比发现两者分级结果较为一致。由此得出,通过反射率直接进行灰度分割可以对溢油污染进行有效的等级评定。     

海面水包油乳化液溢油量等效估算方法研究

激光诱导荧光(LIF)是一种主动光学探测技术,该技术已在海面未乳化溢油油种鉴别及油膜厚度评估方面取得了一定的研究成果,但乳化溢油的监测理论基础和探测方法尚未成熟。溢油乳化物的量化会直接影响溢油污染的应急处理和灾害评估,但目前对溢油乳化液溢油量的计算尚未有研究报道。本文以水包油乳化液为研究对象,基于等效思想,根据油量相等建立了水包油乳化液与油膜的荧光检测等效模型,并依据光的辐射传输机理推导出等效油膜厚度的估算公式,最后采用仿真实例对估算方法的适用性和有效性进行了验证。实验结果表明,当水包油乳化液含油率小于12×10^-6,厚度小于5.98 cm时,利用所提出的等效方法能有效计算出水包油实际溢油厚度。该方法可为海面乳化溢油量的估算提供一种创新性的方法,具有良好的借鉴意义和实际应用价值。     

一定厚度的油膜对海浪的抑制模型研究

本文结合海浪谱的作用量平衡方程,给出了一定厚度油膜对海浪的抑制模型,该模型不仅与油膜的物理参数有关,而且与环境参数有关。文中开展了抑制比对这些参数的敏感性分析,数值模拟结果表明:动力学粘性,表面/界面弹性、油膜厚度、油膜覆盖率等参数对抑制比的影响较大,但油膜的其他物理学参数如:密度、表面/界面张力,表面/界面粘度几乎对抑制比不产生影响;而且,文中还发现风速和风向对抑制比的影响较大。一般情况下,油膜对雷达回波信号的抑制,只需考虑油膜对海浪的抑制作用;但对厚乳化溢油而言,还应考虑到介电常数的减小对雷达回波信号的抑制。将本文建立的抑制比模型所得结果与墨西哥湾溢油事故期间的15景ENVISAR ASAR影像所得抑制比结果进行了比较。     

海上溢油油膜运动不同数值模拟方法的比较研究

为能够迅速响应突发的海上溢油事故,本文利用油粒子法建立了溢油应急模型,以预测油膜漂移轨迹和形状。为弥补油粒子法无法模拟溢油初期油膜扩展过程和无法响应溢油量变化的缺陷,本文设计实验,使用将油膜扩展与油粒子法结合的两阶段法,发现能够较好地模拟溢油扩展过程;并用分数布朗运动代替传统布朗运动模拟油粒子扩散过程,模拟结果能够响应溢油量变化,更好地模拟油膜分散破碎的过程。模型中还考虑了蒸发过程使油粒子数量减少。     

长江口宝钢码头溢油事故油膜漂移扩散数值模拟

溢油事故发生后, 油膜的漂移扩散会对周围水域和环境敏感目标造成污染。研究溢油事故后油膜漂移扩散, 可为溢油事故的处理提供理论指导。本文应用河口海岸三维水动力模式ECOM-si(semi-implicit estuarine, costal and ocean model), 耦合溢油漂移扩散模块, 模拟和分析长江口宝钢码头发生溢油事故后油膜的漂移扩散, 以及对环境敏感保护目标的影响。基于长江口崇明东滩气象站实测风速风向资料, 给出影响溢油漂移的主导风和不利风向。在冬季多年平均1月径流量11700m³·s^-1、主导风、3个不利风和潮汐作用下, 数值模拟并详细给出了宝钢码头溢油事故发生后油膜的平面分布、油膜到达和离开4个水库取水口和饮用水水源保护区以及其他环境敏感保护区的时间、持续影响时间和最大油膜厚度。长江口宝钢码头溢油事故发生后, 油膜随涨落潮流作上下游来回振荡, 径流使油膜向海输运, 风使油膜朝风向方向漂移。在主导风北风5.6m³·s^-1风速下, 油膜沿长江口南岸向下游漂移扩散, 小部分进入北槽南侧。在不利风向东南风4.0m³·s^-1风速下, 油膜西北方向漂移, 聚集于南支北岸, 受径流作用沿南支和北港的中北侧向下游输运。在不利风向西北风4.8m³·s^-1风速下, 西北风减轻了溢油事故点上游和北港、崇明东滩外侧敏感目标的影响, 加重了南港和南槽的环境敏感保护目标的影响。在不利风向西南风3.2m³·s^-1风速下, 大部分油膜在北港中北侧向下游漂移扩散, 小部分油膜聚集在北槽的中北侧。西南风减轻了溢油事故点上游和下游南港、南槽环境敏感目标受到的影响, 加重了对北港和崇明东滩外侧敏感目标的影响。不同风向作用下油膜的分布和对环境敏感保护目标影响显著不同, 风在油膜漂移扩散中起着十分重要的作用。     

基于数值模型和事件树模型的长江中游溢油风险研究

河流溢油事故会严重影响河流生态和供水安全,为了及时应对溢油事故,合理安排应急物资,有必要对溢油影响风险进行定量评估。本研究通过将数值模型和事件树模型相结合构建了河流溢油事故影响风险的评估方法,以长江中游为例,计算了溢油事故后油膜漂移距离的概率分布。结果表明在75%的概率下,事故发生后6 h内的油膜漂移距离小于42.7 km, 24 h内油膜漂移距离小于143.0 km。本研究构建的风险评估方法可为溢油应急方案设计和应急物资储备提供科学指导。     

Modeling of oil spreading in a problem of radar multiangle diagnostics of Sea surface pollutions

The possibilities of a multiangle method of radar diagnostics to determine thickness of an oil film on a sea surface by comparing the radar data with the quantitative modeling results obtained using the model of oil spreading dynamics are analyzed. The experimental results of the remote sensing of the Caspian Sea water area near the Neftyanye Kamni oil field by the Envisat-1 synthetic aperture radar (SAR) and the new Floating Objects Tracking System (FOTS) model of oil spreading are used for the analysis. The model allows to calculate the dynamics and change in the mass and size of an oil slick basing only on the available data of satellite measurements and atmospheric reanalysis.The model takes into account the main processes that influence the slick formation (gravity spreading, advective transport, dispersion, emulsification, turbulent mixing, and evaporation). This model is used to calculate the thickness evolution and dynamics of the displacement of oil slicks in the period between two consecutive radar images of this region (0.5–4 days) and to estimate the volumes of oil spilled in the field. The good consistence of the height of the oil film calculated using radar measurements and the modeling results confirms the method’s reliability.     

福宁湾海域溢油扩散影响的数值模拟研究

应用非结构化网格形式的MIKE 21水动力模型及溢油模块建立福宁湾海域海工工程施工期溢油扩散的数学模型,对在静风、全年主导风及不利风等3种不同风况条件下,一个潮周期内包括涨憩、落急、落憩、涨急等4个典型潮时分别发生100 t燃料油持续泄露30 min的事故溢油工况进行溢油扩散数值模拟.分析显示,事故溢油在福宁湾海域的扩散过程主要受潮流和风的影响.计算结果给出了事故溢油发生后24 h内的影响范围及0. 05 mg/dm3油浓度(一类或二类水质标准)溢油最快到达福宁湾内主要敏感目标的时间,为海洋环境影响评价和溢油事故应急措施的制定提供了科学依据.     

Numerical Study of the Oil Spill Trajectory in Bohai Sea,China

Sixteen numerical experiments are conducted using the General NOAA Operational Modeling Environment (GNOME) to numerically study the oil spill trajectory in the Bohai Sea, China, for the purpose of providing information for the oil cleanup and disaster mitigation. High resolution coastline and topography data investigated by China's 908 Program are used to accurately describe the regional geographic feature of the Bohai Sea. Currents and waves required by GNOME are generated by the Hybrid Coordinate Ocean Model and Simulating Wave Nearshore, respectively. Experimental results show that oil spilled in different seasons and at different locations will result in completely different spilling trajectories, traveling distances, and polluting areas. Knowing that information comprehensively is vital to pollution control. Another important goal of this work is to provide users with simulated oil spill trajectory information through China Digital Ocean Prototype System (CDOPS), a grand marine information platform for managing, displaying, and public sharing of the data investigated by the China 908 Program. Users can obtain the trajectory, spreading, and potential impact area of the spilled oil through the oil spill module in CDOPS.     

厦门港刘五店航道海域溢油扩散数值模拟

利用MIKE 21 HD模块建立了厦门湾二维水动力模型,经2008年最新实测资料,验证了模型的可靠性和适用性,模拟结果为厦门湾刘五店航道二维溢油模型的建立提供水动力基础数据.利用MIKE21 SA模块建立厦门湾刘五店航道二维溢油模型,应用"油粒子"模型模拟输移、风化和热量迁移等过程,对刘五店航道一期工程溢油泄露事故进行...     

Hindcast of the Argo merchant spill using the uri oil spill fates model

A comprehensive oilspill fates model, developed by Cornillon and Spaulding at the University of Rhode Island, has been employed to hindcast the well-studied Argo Merchant spill. Using data collected during the spill to define the environmental conditions and the oil composition, properties and release rates, the oil spill fates model was used to predict the spatial and temporal distribution of spilled oil from December 16 to 31, 1976. Comparison of model predictions to observations for spilled oil mass balance, surface trajectories and oiled surface area was in general quite good. Improved predictions require a better definition of the wind and tidally-forced circulation in the vicinity of the wreck site, a more soundly based theory for oil entrainment or dispersion into the water column and an oil spreading theory which more accurately addresses the complex behaviour of a weathering multicomponent petroleum hydrocarbon.     

“深水地平线”事故深海溢油输移扩散的数值模拟

为深入认识深海溢油输运过程和提高深海溢油事故的应急响应能力,文章以2010年墨西哥湾“深水地平线”事故为例,采用深海溢油输移扩散模型,以三维流场和海面风场为主要环境动力,数值模拟溢油深海泄漏后的浮射扩散、水体中输移扩散以及在风场和流场共同作用下在海面上输移扩散的全过程,同时模拟实施海底消油剂喷注处理措施后溢油输移轨迹和扩散范围的变化。研究结果表明：数值模拟结果与相关报道的悬浮油带实际观测结果以及美国国家海洋与大气管理局的海水异常遥感监测结果总体相符,可为更加全面和精细的深海溢油输移扩散数值模拟研究奠定良好的基础。     

中国海洋溢油污染现状及其生态影响研究

分析了中国近海溢油污染的现状、污染加剧的背景和原因,着重探讨了海洋溢油污染的生态危害,并提出了防治方法与对策.     

Three-dimensional numerical simulation for transport of oil spills in seas

This study extends previous two-dimensional research [Wang, S.D., Shen, Y.M., Zheng, Y.H., 2005. Two-dimensional numerical simulation for transport and fate of oil spills in seas. Ocean Engineering 32, 1556–1571] to three dimensions in order to investigate the vertical dispersion/motion of the spilled oil slick, which is a more realistic model of the motion of the spilled oil. To this end, a three-dimensional (3-D) model, based on the particle approach, is developed for simulating oil spill transport and fate in seas. The amount of oil released at sea is distributed among a large number of particles tracked individually. These particles are driven by a combination of water current, wave- and wind-induced speed and move in a 3-D space. Horizontal and vertical diffusion are taken into account using a random walk technique. The model simulates the most significant processes which affect the motion of oil particles, such as advection, surface spreading, evaporation, dissolution, emulsification, turbulent diffusion, the interaction of the oil particles with the shoreline, sedimentation and the temporal variations of oil viscosity, density and surface tension. In addition, the processes of hydrolysis, photo-oxidation and biodegradation are also considered in this model. The model has been applied to simulate the oil spill accident in the Bohai Sea.     

Underwater spreading and surface drifting of oil spilled from a submarine pipeline under the combined action of wave and current

Tremendous economic loss and environmental damages are caused by oil-spilling accidents in sea. Accurate prediction of the underwater spreading and surface drifting of oil spills is important for the emergency response. In the present study, numerical investigation on the underwater spread and surface drift of oil spilled from a submarine pipeline under the combined action of wave and current was carried out to examine the effects of physical ocean environment, leaking flux and spilled oil density and viscosity. Reynolds-Averaged-Navier-Stokes (RANS) equations, realizable k-ε turbulence model and volume of fluid (VOF) model are employed to describe the multiphase flow, and velocity-boundary wave-making technique combined with the sponge layer damping absorber technique realizes the numerical wave flume. Oil spill experiments were conducted to validate the numerical model. The calculation results indicate that compared with the environmental conditions of still water, only current and only wave, a larger scope of underwater spreading and relatively slower rising rate and relatively faster drifting rate of oil droplets are observed under the combined action of wave and current. The leaking flux affects the floating time and dispersion concentration, while the ocean environment affects the horizontal migration and surface drifting. Under the specific conditions of present work, oil density has obvious effect on the underwater spread but limited effect on the surface drifting, while oil viscosity has little effect on both the two processes.