长江干线船舶废气排放核算模型
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摘要
为加快推进长江航运废气排放控制工作,在充分借鉴国内外船舶排放清单有关研究的基础上,建立自下而上基于船舶引擎功率排放因子法的长江干线废气排放核算模型。运用长江干线船舶的船舶自动识别系统(Automatic Identification System, AIS)静态数据对船舶功率数据分船型及区段进行处理,确定长江干线不同船型和各船长区段船舶的代表功率,结合长江干线船舶航行分布特征引入断面积分方式对断面区间船舶废气排放进行核算。以长江干线某区段为例,根据该区段船舶流量统计数据及船舶AIS数据核算得到区段船舶废气排放清单,并对核算区段进行废气排放时空分布特征研究,结果表明:模型计算研究区段2015年度船舶各类废气的排放量,普通货船废气排放量约占研究区段各类排放量的80%,排放量相对较高的区段主要分布在港区河段。
The section integration method is introduced to establish a model to estimate the exhaust emissions from the ships on the Yangtze River. The emissions from one single ship are estimated according to its engine power and corresponding emission factor, which is ship type dependent and is determined based on reported statistics data. The emissions in a section of the river are calculated according to the traffic flow data and the ship type data from AIS(Automatic Identification System). The temporal and spatial distributions of the emissions are calculated. The emissions of a typical section in 2015 are calculated, showing that the emissions from general cargo ships account for about 80% of the total emissions, and the relatively high emission areas are mainly at the port areas.
The section integration method is introduced to establish a model to estimate the exhaust emissions from the ships on the Yangtze River. The emissions from one single ship are estimated according to its engine power and corresponding emission factor, which is ship type dependent and is determined based on reported statistics data. The emissions in a section of the river are calculated according to the traffic flow data and the ship type data from AIS(Automatic Identification System). The temporal and spatial distributions of the emissions are calculated. The emissions of a typical section in 2015 are calculated, showing that the emissions from general cargo ships account for about 80% of the total emissions, and the relatively high emission areas are mainly at the port areas.
引文
[1] 中华人民共和国国务院.“十三五”控制温室气体排放工作方案:国发[2016]61号[S].北京:中华人民共和国国务院,2016.
[2] 邢辉,段树林,梁炳南,等.基于船舶营运数据的海运废气排放量测算[J].中国航海,2016,39(3):93-98.
[3] 叶斯琪,郑君瑜,潘月云,等.广东省船舶排放源清单及时空分布特征研究[J].环境科学学报,2014,34(3):537-547.
[4] 刘静,王静,宋传真,等.青岛市港口船舶大气污染排放清单的建立及应用[J].中国环境监测,2011,27(3):50-53.
[5] 杨静,尹佩玲,叶斯琪,等.深圳市船舶排放清单与时空特征研究[J].环境科学,2015,36(4):1217-1226.
[6] 王征,张卫,耿雄飞,等.典型航线船舶排放清单及排放特征研究[J].港航节能,2015(4):44-49.
[7] KEUKEN M P,MOERMAN M,JONKERS J,et al.Impact of Inland Shipping Emissions on Elemental Carbon Concentrations Near Waterways in The Netherlands[J].Atmospheric Environment,2014,95:1-9.
[8] 文元桥,耿晓巧,吴定能,等.基于AIS信息的船舶废气排放测度模型[J].中国航海,2015,38(4):96-101.
[9] 伏晴艳,沈寅,张健.上海港船舶大气污染物排放清单研究[J].安全与环境学报,2012,12(5):57-64.
[10] 邢辉,段树林,黄连忠,等.中国水路运输业能源消耗与废气排放测算[J].中国环境科学,2016,36(6):1913-1920.
[11] IMO.Third IMO Greenhouse Gas Study 2014[R].London:International Maritime Organization,2014.
[12] 邢辉,段树林,黄连忠,等.基于台架测试的我国船用柴油机废气排放因子[J].环境科学,2016,37(10):3750-3757.
[2] 邢辉,段树林,梁炳南,等.基于船舶营运数据的海运废气排放量测算[J].中国航海,2016,39(3):93-98.
[3] 叶斯琪,郑君瑜,潘月云,等.广东省船舶排放源清单及时空分布特征研究[J].环境科学学报,2014,34(3):537-547.
[4] 刘静,王静,宋传真,等.青岛市港口船舶大气污染排放清单的建立及应用[J].中国环境监测,2011,27(3):50-53.
[5] 杨静,尹佩玲,叶斯琪,等.深圳市船舶排放清单与时空特征研究[J].环境科学,2015,36(4):1217-1226.
[6] 王征,张卫,耿雄飞,等.典型航线船舶排放清单及排放特征研究[J].港航节能,2015(4):44-49.
[7] KEUKEN M P,MOERMAN M,JONKERS J,et al.Impact of Inland Shipping Emissions on Elemental Carbon Concentrations Near Waterways in The Netherlands[J].Atmospheric Environment,2014,95:1-9.
[8] 文元桥,耿晓巧,吴定能,等.基于AIS信息的船舶废气排放测度模型[J].中国航海,2015,38(4):96-101.
[9] 伏晴艳,沈寅,张健.上海港船舶大气污染物排放清单研究[J].安全与环境学报,2012,12(5):57-64.
[10] 邢辉,段树林,黄连忠,等.中国水路运输业能源消耗与废气排放测算[J].中国环境科学,2016,36(6):1913-1920.
[11] IMO.Third IMO Greenhouse Gas Study 2014[R].London:International Maritime Organization,2014.
[12] 邢辉,段树林,黄连忠,等.基于台架测试的我国船用柴油机废气排放因子[J].环境科学,2016,37(10):3750-3757.
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