近25年雅鲁藏布江中游蒸发皿蒸发量及其影响因素的变化

采用气候倾向率方法,对西藏雅鲁藏布江(下称"雅江")中游1981~2005年14个气象站年、季小型蒸发皿蒸发量及其影响气候因子的变化趋势进行了分析。结果表明:近25年西藏雅江中游年蒸发皿蒸发量在流域绝大部分站点均呈现显著的减少趋势,平均减幅为109.92mm,以夏季减少趋势最明显。影响蒸发皿蒸发量的主要气候因子日照时数、平均风速呈现显著下降趋势,平均相对湿度、降水量表现为显著增加,平均气温显著升高,平均最低气温的升温速率(0.52℃/10a)明显比平均最高气温的升温速率(0.23℃/10a)大,导致气温日较差减少(-0.29℃/10a)。因此,雅江中游年日照时数和平均风速的显著下降,以及年平均相对湿度的明显增加可能是年蒸发皿蒸发量显著下降的主要原因,平均气温日较差的显著减小和降水量的增加在蒸发量减少趋势中的作用也不可忽视。     

Influence of environmental temperature and relative humidity on photocatalytic oxidation of toluene on activated carbon fibers coated TiO2

TiO₂ supported on active carbon fiber (TiO₂/ACF), an absorbable photocatalyst, is a new kind of material applied in air purification. In this paper, the influence of environmental temperature (T) and relative humidity (RH) on the gas-solid adsorption of toluene and the photocatalytic oxidation (PCO) efficiency of adsorbed toluene on TiO₂/ACF were studied, and then, the purification capability of TiO₂/ACF was estimated. PCO results showed that although the PCO efficiency increased under high RH and T levels, the amount of adsorption of toluene decreased. Moreover, quantitative analysis results of intermediates indicated that more environmental risk emerged when PCO of toluene was carried out at higher environmental T and RH levels because more toxic intermediates would be accumulated on the TiO₂/ACF. So, it is significant to control the environmental T and RH conditions in the application of the PCO technique. T = 25°C and RH530% is the optimal condition for purifying toluene in our experimental system. __________ Translated from Urban Environment & Urban Ecology, 2007, 20(5): 10–13 [译自: 城市环境与城市生态]     

Industrial layout reconstruction,the role of local government and variation of pollution distribution in China

ABSTRACT

In recent years, high-polluting industries have been gradually shifted from the eastern developed regions to the central and western underdeveloped regions in China. Certain environmental regulations have been in place accordingly in various regions, but the pollution in the central and western regions has risen sharply. Based on the data of interprovincial panel in China from 2006 to 2015, this paper calculates high-pollution industry dynamic agglomeration index, environmental pollution agglomeration index and relative environmental regulation intensity index, and uses Generalized Method of Moments to carry out the regression analyses of the whole samples, regional heterogeneity and temporal heterogeneity. The results show that there is an inverted U-shaped relationship between relative environmental regulation and environmental pollution concentration in China. The concentration degrees of industrial wastewater pollution and industrial waste gas pollution are deepened, which are mainly caused by the transfer of highly polluting industries. However, the concentration of industrial solid waste pollution caused by the transfer is not obvious. Furthermore, the deepening of industrialization intensifies the concentration of regional environmental pollution. Environmental Kuznets Curve does exist in China, but it is not significant. The increase of labor cost and quality will reduce the concentration of environmental pollution.     

新乡市夏冬季节PM2.5稳定碳同位素特征分析

为了探究新乡市PM_(2.5)中δ~(13)C比值的季节性变化特征及其对污染来源的指示作用,于2017年夏冬季节采集PM_(2.5)有效样品91个,并测定了样品中的总碳、水溶性离子和稳定碳同位素比值(δ~(13)C).夏季和冬季的TC浓度平均值分别为11.78μg·m~(-3)和26.6μg·m~(-3).夏季δ~(13)C比值为-27.70‰～-25.22‰其中前14 d的δ~(13)C比值波动较大平均值为-26.96‰,而后16d的δ~(13)C比值相对稳定,平均值为-25.69‰,而且前半月和后半月火点数具有较大差异同时K_(nss)~+浓度与TC质量浓度显著相关(R~2=0.62,P0.01)这说明夏收季节生物质燃烧可能对δ~(13)C比值有显著影响.新乡地区冬季RH与TC/PM_(25)质量比值的显著负相关(R~2=0.68,P0.01),揭示了在霾增长初期以SOA增长为主,而污染期以SIA贡献为主.冬季采样期δ~(13)C比值为-26.72‰～-23.49‰,对霾发展过程中稳定同位素组成的研究发现在霾增长过程中δ~(13)C比值以富集为主,而在霾清除阶段δ~(13)C比值以贫化为主.     

利用多元线性回归方法评估气象条件和控制措施对APEC期间北京空气质量的影响

气象条件对大气污染物的扩散和传输有重要影响,准确分离和定量气象因素对空气质量的影响是评估大气污染控制政策有效性的前提.本研究利用APEC会议期间及前后(2014-10-15～2014-11-30)北京城区朝阳观测站点SO_2、NO、NO_2、NO_x、CO、PM_(2.5)、PM_1和PM_(10)以及气象因素的观测数据,采用多元线性回归分析方法,定量评估了气象条件和空气污染控制措施对APEC期间北京空气质量的影响.在假定排放条件不变的情况下,基于气象因素参数建立的预测污染物浓度的多元线性回归模型模拟效果较为理想,决定系数R~2在0. 494～0. 783之间.控制措施使得APEC控制期SO_2、NO、NO_2、NO_x、CO、PM_(2.5)、PM_1和PM_(10)浓度分别降低48. 3%、53. 5%、18. 7%、40. 6%、3. 6%、34. 8%、28. 8%和40. 6%,气象因素使得APEC控制期SO_2、NO、NO_2、NO_x、CO、PM_(2.5)、PM_1和PM_(10)浓度分别降低1. 7%、-2. 8%、18. 7%、4. 5%、18. 6%、27. 5%、30. 6%和35. 6%.气象因素和控制措施共同作用使得APEC控制期北京空气质量得到了明显改善.控制措施对SO_2和氮氧化物浓度的下降起主导作用,气象因素对CO浓度的下降起主导作用,气象因素和控制措施对颗粒物浓度降低的贡献相当.本研究还利用相对权重方法研究了气象因素对污染物浓度影响的贡献,结果表明影响不同污染物浓度的决定性气象因素不同.     

成都地区气溶胶散射吸湿增长因子双变量模型

基于成都市2017年10～12月逐时的“干”气溶胶散射系数和吸收系数观测数据,结合该时段同时次的能见度（V）、相对湿度（RH）以及二氧化氮（NO₂）监测资料,利用“光学综合法”计算气溶胶散射吸湿增长因子,并探究了气溶胶散射吸湿增长因子单变量f（RH）模型的适用性及其改进方案.结果表明：幂函数、二次多项式、幂指函数形式的f（RH）模型在低RH条件下（RH<85%）均能很好地模拟气溶胶散射吸湿增长因子随RH的变化特征,但在高RH条件下（RH>85%）的模拟值会出现较大的偏差.黑碳质量浓度（C_BC）是影响气溶胶散射吸湿增长因子的另一关键变量,二者之间满足非线性关系.以RH和C_BC为自变量构建了气溶胶散射吸湿增长因子双变量f（RH,C_BC）模型,模型计算值和实测值之间的决定系数R²为0.763,平均相对误差MRE为14.28%.双变量模型f（RH,C_BC）的应用显著改善了气溶胶散射消光系数的模拟效果.     

大气颗粒物“二重源解析”技术的误差分析

"二重源解析"模型计算结果的误差是采样误差、样品处理误差、化学组分分析误差、数据处理误差以及数学模型误差等所有误差的积累。提出了"二重源解析"解析结果的相对误差和标准偏差表达式,并用之计算了某市利用"二重源解析"模型计算的源贡献值的相对误差和标准偏差,还针对从源排放出来的初始态颗粒物在传输过程中发生的扬尘态变化提出了扬尘转化率的概念和计算方法。     

Muhlbauer风险分析法在管道风险评价中的应用

将管道统计数据和专家意见相结合,以靖边-银川天然气输送管道工程为实例,进行管道安全模拟计算,定量分析输油、气管道的相对风险数,寻求提高管道运行安全性的途径.结果表明:该管道的两段管道,即靖边-盐池清、盐池清-银川的相对风险数分别为67.1和68.3,存在一定的风险,相对风险数中可变因素所占比例分别为63%和62%;可通过加强管理等措施,提高可变因素的指数分值从而提高管道的相对风险数,使管道安全性在原基础上提高19%左右.      

湿式石灰石-石膏烟气脱硫系统的工艺控制

通过实践提出湿法脱硫系统运行时工艺参数的优化值,重点讨论了浆液pH、石膏相对过饱和度的控制,以实例说明烟气负荷变化时设备运行方式的改变和参数的调整手段。     

Emissions of SO2, NO and N2O in a circulating fluidized bed combustor during co-firing coal and biomass

This paper presents the experimental investigations of the emissions of SO2, NO and N2O in a bench scale circulating fluidized bed combustor for coal combustion and co-firing coal and biomass. The thermal capacity of the combustor is 30 kW. The setup is electrically heated during startup. The influence of the excess air, the degree of the air staging, the biomass share and the feeding position of the fuels on the emissions of SO2, NO and N2O were studied. The results showed that an increase in the biomass shares resulted in an increase of the CO concentration in the flue gas, probably due to the high volatile content of the biomass. In co-firing, the emission of SO2 increased with increasing biomass share slightly, however, non-linear increase relationship between SO2 emission and fuel sulfur content was observed. Air staging significantly decreased the NO emission without raising the SO2 level. Although the change of the fuel feeding position from riser to downer resulted in a decrease in the NO emission level, no obvious change was observed for the SO2 level. Taking the coal feeding position R as a reference, the relative NO emission could significantly decrease during co-firing coal and biomass when feeding fuel at position D and keeping the first stage stoichiometry greater than 0.95. The possible mechanisms of the sulfur and nitrogen chemistry at these conditions were discussed and the ways of simultaneous reduction of SO2, NO and N2O were proposed.