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我国典型燃煤源和工业过程源排放PM2.5成分谱特征研究
刘亚勇,张文杰,白志鹏,杨文,赵雪艳,韩斌,王歆华,等
作者单位地址
刘亚勇 环境基准与风险评估国家重点实验室 北京市朝阳区安外北苑大羊坊8号
张文杰 环境基准与风险评估国家重点实验室 北京市朝阳区安外北苑大羊坊8号
白志鹏 环境基准与风险评估国家重点实验室 
杨文 环境基准与风险评估国家重点实验室 
赵雪艳 环境基准与风险评估国家重点实验室 
韩斌 环境基准与风险评估国家重点实验室 
王歆华 环境基准与风险评估国家重点实验室 
摘要:
鉴于我国本地化源谱数量不足的现状,采用稀释通道系统对燃煤源和工业过程源进行采样,并建立了4种燃煤锅炉(链条炉、流化床、往复炉和煤粉炉)和6种工业过程源(炼铁、铝焙烧、铝煅烧、砖瓦炉、水泥窑头和窑尾)的PM2.5成分谱,并对源谱特征进行研究。结果表明:①不同源谱组分特征差异明显。水泥窑炉排放的PM2.5中,Ca、Si、OC、SO42-等含量较为丰富,分别为8.51%~14.18%、5.69%~11.80%、3.47%~15.56%、8.67%~16.85%;燃煤锅炉中Al (4.50%~8.67%)、OC(6.44%~15.33%)、SO42- (9.85%~22.87%)等组分贡献较大;炼铁和铝冶炼工艺源谱中主导化学组分分别为Fe (8.57%~9.88%)和Al (11.81%~16.58%);砖瓦炉颗粒物源谱中主要组分为SO42-、NH4+、Si等。②不同污染源PM2.5成分谱的分歧系数结果显示,流化床和煤粉炉、水泥窑头和窑尾源谱较为相似,其分歧系数分别为0.26和0.28,其余源谱间均存在一定差异。进一步计算组分差异权重(R/U)发现,往复炉源谱中组分Zn、Sn与其他三类锅炉有明显不同。流化床/煤粉炉源谱中的Si、Ni,窑头/窑尾源谱中的K、Mn、OC组分差异显著,可以作为区分相似源谱的标识组分。与其他研究建立的源谱相比,燃煤源谱中 w (EC) 和w (SO42-) 偏高。钢铁源谱中 w (EC) 和 w (NH4+) 较其他地区偏高,Pb含量偏低;工业过程源谱中,w (Cl-) 较SPECIATE相关源谱偏低,而V和Cr含量偏高。颗粒物源谱受到不同燃料种类、燃烧方式和烟气控制设施等影响而存在差异,该研究中源成分谱的准确性和代表性还需进一步测试和验证。
关键词:  PM2.5源成分谱  燃煤源  工业过程源
DOI:
分类号:
基金项目:科技基础性工作专项“我国PM2.5主要排放源谱的编研”(2013FY112700);国家科技支撑项目“京津冀区域大气污染联防联控支撑技术研发与应用” (2014BAC23B02)
Characteristics of PM2.5 Chemical source profiles of Coal Combustion and Industrial Process in China
Yayong Liu,Wenjie Zhang,Zhipeng Bai,Wen Yang,Xueyan Zhao,Bin Han,Xinhua Wang,et al
Abstract:
In view of insufficient local source profiles in China, PM2.5 source profiles for coal-fired boilers and industrial processes’ emissions were established. 4 coal burning sources from coal-fired boilers of grate firing, fluidized bed, converters and pulverized coal, and 6 industrial process emissions from metallurgy, steel production and construction materials production were discussed. Results showed that ①The chemical composition shows special characteristics in different source categories. Ca (8.51%~14.18%), Si (5.69%~11.80%), OC (3.47%~15.56%) and SO42- (9.85%~22.87%) were shown to be the major species of PM2.5 from cement kiln; Al, SO42- and OC marked coal-fired boiler, accounted for 4.50%~8.67%, 6.44%~15.33% and 9.85%~22.87%, respectively; Fe (8.57%~9.88%) and Al (11.81%~16.58%) were the most abundant elements in steel production and aluminum metallurgy. The highest abundances of SO42-、NH4+、Si were observed in brick kiln emissions. ②The coefficient of divergence (CD) and the distribution of weighted differences (R/U ratio) were used to compare the similarities and differences of source profiles. Good similarities were observed between fluidized bed and pulverized coal boiler emissions, and between cement kiln head and inlet emissions. Si and Ni were expected to distinguish profiles between fluidized bed and pulverized coal boiler with the R/U>3. K、Mn and OC abundances were significant different between profiles of cement kiln head and inlet. Differences of source profiles from different studies including SPECIATE database were compared. EC and SO42- from coal burning, EC and NH4+ from steel production were higher than those of studies in other regions. Compared with source profiles in SPECIATE v4.5, Cl- abundances in metallurgy, cement and brick kiln were lower, while V and Cr were higher in this research. The discrepancies of chemical species from different source profiles are closely linked to different fuels, combustion modes and control facilities. More tests are needed for further study.
Key words:  PM2.5  source profiles  coal-fired boiler emissions  industrial process sources