面向上海国际航运中心的洋山综合信息服务平台

介绍了洋山深水港面向国际航运中心,建设洋山综合信息服务平台的现实要求和建设基础,并详尽地叙述了洋山综合信息服务平台的主要功能和建设内容,以及洋山综合信息服务平台的积极意义和重要作用。     

船长文献——澳大利亚Cape Flattery港进港指南与靠泊操作要点

澳大利亚Cape Flattery港情况特殊,无拖船协助,给靠、离泊带来许多困难。总结了长期航行于此港至东亚航线的经验和体会,供航海人员参考。     

把南通港建成长三角最具活力的亿吨强港

介绍了南通港口2006年货物吞吐量突破亿吨所取得的成绩,并从“沿江开发、江海联动”的发展战略着眼,提出了从“亿吨大港”,向“亿吨强港”进取,切实需着重抓好的几个方面的工作。     

港口腹地划分的两种新方法探讨--以大连国际航运中心为例

引入经济地理学的新理论成果———圈层结构法和点轴法,提出了圈层结构划分法和点轴结构划分法两种新的港口腹地划分方法,并应用这两种新方法对大连国际航运中心港口腹地范围的界定与划分进行实例分析。与以往的行政区划法、经济区域法等港口腹地划分方法相比,这两种方法更加注重对港口原有腹地的细分,更接近于港口腹地的实际状况,进而有利于港口企业的经营发展。     

石垣港换单简介及操船

由于中、日、韩航线及海峡两岸的航运市场不断发展,为了船舶的安全及经济效益,到我国台湾地区的船舶缩短在石垣港的换单时间及操船,关系到船舶的安全营运,抓好这一环节十分重要。     

天津港突堤转角处高桩码头后承台构件相对错位破损原因

近几年天津港多个突堤转角处的高桩码头岸坡变形比较明显,导致码头后方承台结构构件出现明显的相对错位、变形等破损情况,严重影响了码头结构物安全。通过对破损状况的调查统计,总结出了破损的特点,对破损的原因进行了理论分析,并用原型观测和数模计算结果进行了验证。原型观测结果表明:码头岸坡内的淤泥质粘土层为水平位移最明显土层,靠近挡土墙的大部分桩顶都出现了不同程度的向陆侧倾斜,这与实际见到的桩端倾斜状况完全相符。数模计算结果除验证了原型观测的结果以外,还发现仅在后方堆场堆载工况为最危险情况,是造成岸坡变形和后方承台构件相对错位的主要原因。     

铁路参与铁水联运无水港建设的思考

在阐述铁水联运集疏运系统的构成和建立条件的基础上,分析了铁路参与无水港建设的可行性和模式。铁路应通过全面参与无水港建设,加快融入综合运输体系的步伐,可采取改造现有场站设备与设施和新建物流中心两种方式参与无水港建设,同时应注意以下4个问题:采取多种途径解决资金问题;重视信息管理系统建设;提供优质运输服务;注重开发主业副产品。     

汽车发动机气道内的流动模拟计算

本文介绍了汽车发动机气道内三维定常可压缩流动数值模拟的模型、算法及算例。为达到能定量分析并应用于实际设计的目的,提出了一种新的计算网格划分法,并开发了计算软件,对提高计算精度、加速收敛等关键问题进行了探索。     

Greenhouse gas emissions from ships in ports – Case studies in four continents

Emissions of GHG from the transport sector and how to reduce them are major challenges for policy makers. The purpose of this paper is to analyse the level of greenhouse gas (GHG) emissions from ships while in port based on annual data from Port of Gothenburg, Port of Long Beach, Port of Osaka and Sydney Ports. Port call statistics including IMO number, ship name, berth number and time spent at berth for each ship call, were provided by each participating port. The IMO numbers were used to match each port call to ship specifications from the IHS database Sea-web. All data were analysed with a model developed by the IVL Swedish Environmental Research Institute for the purpose of quantifying GHG emissions (as CO₂-equivalent) from ships in the port area. Emissions from five operational modes are summed in order to account for ship operations in the different traffic areas. The model estimates total GHG emissions of 150,000, 240,000, 97,000, and 95,000 tonnes CO₂ equivalents per year for Gothenburg, Long Beach, Osaka, and Sydney, respectively. Four important emission-reduction measures are discussed: reduced speed in fairway channels, on-shore power supply, reduced turnaround time at berth and alternative fuels. It is argued that the potential to reduce emissions in a port area depends on how often a ship revisits a port: there it in general is easier to implement measures for high-frequent liners. Ships that call 10 times or less contribute significantly to emissions in all ports.     

Experimental evaluation of Heavy Duty Vehicle speed patterns in urban and port areas and estimation of their fuel consumption and exhaust emissions

Exhaust emissions and fuel consumption of Heavy Duty Vehicles (HDVs) in urban and port areas were evaluated through a dedicated investigation. The HDV fleet composition and traffic driving from highways to the maritime port of Genoa and crossing the city were analysed. Typical urban trips linking highway exits to port gates and HDV mission profiles within the port area were defined. A validation was performed through on-board instrumentation to record HDV instantaneous speeds in urban and port zones. A statistical procedure enabled the building-up of representative speed patterns. High contrasts and specific driving conditions were observed in the port area. Representative speed profiles were then used to simulate fuel consumption and emissions for HDVs, using the Passenger car and Heavy duty Emission Model (PHEM). Complementary estimations were derived from Copert and HBEFA methodologies, allowing the comparison of different calculation approaches and scales. Finally, PHEM was implemented to assess the performances of EGR or SCR systems for NO_X reduction in urban driving and at very low speeds.The method and results of the investigation are presented. Fuel consumption and pollutant emission estimation through different methodologies are discussed, as well as the necessity of characterizing very local driving conditions for appropriate assessment.