This paper presents a method for investigating ship emissions, the plume capture and analysis system (PCAS), and its application in measuring airborne pollutant emission factors (EFs) and particle size distributions. The current investigation was conducted in situ, aboard two dredgers (Amity: a cutter suction dredger and Brisbane: a hopper suction dredger) but the PCAS is also capable of performing such measurements remotely at a distant point within the plume. EFs were measured relative to the fuel consumption using the fuel combustion derived plume CO2. All plume measurements were corrected by subtracting background concentrations sampled regularly from upwind of the stacks. Each measurement typically took 6 minutes to complete and during one day, 40 to 50 measurements were possible.ududThe relationship between the EFs and plume sample dilution was examined to determine the plume dilution range over which the technique could deliver consistent results when measuring EFs for particle number (PN), NOx, SO2, and PM2.5 within a targeted dilution factor range of 50-1000 suitable for remote sampling. The EFs for NOx, SO2, and PM2.5 were found to be independent of dilution, for dilution factors within that range. The EF measurement for PN was corrected for coagulation losses by applying a time dependant particle loss correction to the particle number concentration data. ududFor the Amity, the EF ranges were PN: 2.2 - 9.6 × 1015 (kg-fuel)-1; NOx: 35-72 g(NO2).(kg-fuel)-1, SO2 0.6 - 1.1 g(SO2).(kg-fuel)-1and PM2.5: 0.7 – 6.1 g(PM2.5).(kg-fuel)-1. For the Brisbane they were PN: 1.0 – 1.5 x 1016 (kg-fuel)-1, NOx: 3.4 – 8.0 g(NO2).(kg-fuel)-1, SO2: 1.3 – 1.7 g(SO2).(kg-fuel)-1 and PM2.5: 1.2 – 5.6 g(PM2.5).(kg-fuel)-1. The results are discussed in terms of the operating conditions of the vessels’ engines.ududParticle number emission factors as a function of size as well as the count median diameter (CMD), and geometric standard deviation of the size distributions are provided. The size distributions were found to be consistently uni-modal in the range below 500 nm, and this mode was within the accumulation mode range for both vessels. The representative CMDs for the various activities performed by the dredgers ranged from 94-131 nm in the case of the Amity, and 58-80 nm for the Brisbane. A strong inverse relationship between CMD and EF(PN) was observed.
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机译:本文提出了一种研究船舶排放的方法,羽流捕获和分析系统(PCAS),及其在测量航空污染物排放因子(EFs)和粒径分布中的应用。当前的调查是在两个挖泥船(Amity:绞吸式挖泥船和Brisbane:漏斗式挖泥船)上进行的,但PCAS还能够在烟羽内的远处进行远程测量。使用燃料燃烧产生的烟羽CO2测量相对于燃料消耗的EF。所有烟羽测量值均通过从烟囱上风处定期采样的背景浓度中减去而得到校正。每次测量通常需要6分钟才能完成,并且一天中可能要进行40到50次测量。 ud ud检查EF与羽流样品稀释度之间的关系,以确定羽流稀释度范围,在该范围内,该技术可以在测量时提供一致的结果在50-1000的目标稀释因子范围内,适用于颗粒数(PN),NOx,SO2和PM2.5的EF,适用于远程采样。对于该范围内的稀释因子,发现NOx,SO2和PM2.5的EF与稀释无关。通过对颗粒数浓度数据应用随时间变化的颗粒损失校正,可以校正PN的EF测量的凝结损失。 ud ud对于Amity,EF范围为PN:2.2-9.6×1015(千克燃料)-1; NOx:35-72 g(NO2)。(千克燃料)-1,SO2 0.6-1.1 g(SO2)。(千克燃料)-1和PM2.5:0.7 – 6.1 g(PM2.5)。(千克-燃料)-1。布里斯班的PN:1.0 – 1.5 x 1016(kg-燃料)-1,NOx:3.4 – 8.0 g(NO2)。(kg-燃料)-1,SO2:1.3 – 1.7 g(SO2)。(kg -燃料)-1和PM2.5:1.2 – 5.6克(PM2.5)。(千克燃料)-1。根据船舶发动机的工作条件讨论了结果。 ud ud颗粒数排放因子与尺寸以及计数中值直径(CMD)有关,并提供了尺寸分布的几何标准偏差。发现尺寸分布在低于500nm的范围内始终是单峰的,并且该模式在两个容器的累积模式范围内。挖泥船进行的各种活动的代表性CMD在Amity情况下为94-131 nm,在布里斯班为58-80 nm。观察到CMD与EF(PN)之间的强烈反比关系。
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