沈阳市机动车大气污染物排放清单的研究

基于机动车主要污染物排放量计算方法,对主要污染物排放因子进行识别与修正,建立沈阳市机动车污染物排放清单。结果表明:沈阳市机动车污染物的排放总量为206 804. 3 t,CO、NOx、HC和PM10的排放量分别为128 500. 4 t、44 206. 3 t、32 104. 8 t和1 992. 8 t;机动车排放的各污染物二环以内的排放量占总量70. 0%以上,和平区、沈河区和铁西区是该市机动车污染物高排放区域;小型客车和出租车对CO、HC的排放分担率较高,重型货车和轻型货车是NOx、PM10的主要排放源;沈阳市机动车污染物主要来自汽油车和柴油车,新能源机动车排放量较低。     

南京市机动车排气监测与评价

通过对南京市机动车排气污染物的年检监测,表明南京市的汽油车、柴油车、摩托车排气合格率总体呈上升趋势,2002年全市机动车排气监测总合格率为99.9%,比1993年上升了8.6个百分点;汽车尾气达标率也呈上升趋势,2002年达83.8%,比1993年上升了2.6个百分点。对机动车排气路检结果表明,CO超标的车辆占84.4%,CO、HC两项指标都超标的车辆占31.1%。对各类汽油助力车排气监测结果表明,二冲程汽油助力车尾气中CO、HC排放量要高于四冲程汽油助力车的排放量。对各类正三轮摩托车排气抽检结果表明,大部分四冲程正三轮摩托车尾气排放污染物能达标,且排气管无碳烟;二冲程正三轮摩托车尾气中HC值偏高,排气管碳烟明显。     

南京市机动车排气污染现状分析

阐述了南京市机动车发展现状、道路交通现状和机动车污染监测情况，对机动车排放因子、机动车污染、交通干线的污染物日排放特征、机动车源排放污染物的分担率以及机动车尾气污染物排放进行了分析和预测。指出南京市机动车污染状况必须采取有效措施加以控制，并提出了贯彻机动车尾气控制标准，完善污染控制管理机制；重点控制公交、出租和专业物流的机动车污染；严格控制车用油品质量；建立车辆污染数据库；加快道路建设，运用交通综合管理制度削减污染；实施保护区和控制区管理以及实施机动车标志管理等合理化建议。     

北京市公交车尾气污染物检测结果浅析

根据北京市公交车的BASM检测结果,分析了汽油、LPG和CNG 燃料车尾气中CO、HC、NO的排放水平.为此建议大力推广清洁燃料代替汽油.机动车污染物浓度随使用年限增加而增加,应加速淘汰化油器公交车.应对在用公交车实施严格的I/M制度.     

汽油车BASM排放检测方法关联规则研究

应用数据挖掘法对3720台次汽油车的BASM排放检测数据进行关联性分析，对汽车BASM排放检测方法中检测工况及排放污染物检测项目CO、HC、NOx间关联性进行研究，得出在BASM 5024工况下没有通过检测的车辆在BASM 2540工况检测的通过率只有5．7％，CO检测合格对HC的检测合格有76．5％的支持度，HC检测合格对NOx检测合格的支持度为58．9％，说明BASM 5024与BASM 2540检测工况具有较高的关联性，HC与CO存在较高的关联度，而HC与NOx的关联度不高。     

南京市机动车排气污染控制和管理对策

简述了南京市机动车排气污染控制和管理对策。对新机动车排气控制实施了新车上牌的环保注册登记目录制，鼓励生产厂家采用先进的排放控制技术，达到国家制定的排放控制目标和排放标准；对在用机动车排气控制实施检测／维护(I／M)制度，对尾气排放不达标车辆进行正常的维修和保养，保证其发动机处于正常技术状况；对高排放污染机动车辆，安装尾气净化装置，以改善机动车排放水平。定期检测中各类型车辆维护前后排气污染物削减结果表明，85％的高排放污染车辆能达标，且CO的削减率最高，达50％左右；定期检测中各类型车辆安装机内净化器前后排气污染物削减结果表明，二次补气机内净化器对CO的净化率为22．5％～30．0％，对HC的净化率为9．7％～30．0％；高能电子点火机内净化器对CO的净化率为5．4％～22．2％，对HC的净化率为17．2％～30．8％。不定期检测中，一些高排放污染车辆安装三元催化反应器后，其净化率可达80％～90％。     

杭州市大气污染物排放清单及特征

以杭州市区为研究区域,通过调查整合多套污染源数据库及其他统计资料,研究文献报道及模型计算的各种污染源排放因子,获得杭州市区各行业PM10、PM2.5、SO2、NOx、CO、VOCs、NH3等污染物的排放量,建立了杭州市区2010年1 km×1 km大气污染物排放清单。结果表明,2010年杭州市区PM10、PM2.5、SO2、NOx、CO、VOCs和NH3的排放总量分别为7.96×104、4.02×104、7.23×104、8.98×104、73.90×104、39.56×104、3.32×104t。从排放源的行业分布来看,机动车尾气排放是杭州市区大气污染物最重要排放源之一,对PM10、PM2.5、NOx、CO和VOCs的贡献分别达到14.4%、27.1%、40.3%、21.4%、31.1%。道路扬尘、电厂锅炉、工业炉窑、植被、畜禽养殖对不同污染物分别有着重要贡献,道路扬尘对PM10和PM2.5的贡献分别为44.6%和20.0%、电厂锅炉对SO2和NOx的贡献分别为37.0%和25.7%、工业炉窑对CO的贡献为41.5%、植被排放对VOCs的贡献为27.1%、畜禽养殖对NH3的贡献为76.5%。从空间分布来看,萧山区和余杭区对SO2、NH3和植被排放BVOC的贡献要显著高于主城区;而主城区机动车对PM2.5、NOx和VOCs的贡献分别达到36.3%、56.0%和47.4%,较市区范围内显著增加,表明机动车尾气排放已成为杭州主城区大气污染最重要的来源之一。     

南京市街道峡谷机动车尾气污染特点和环境容量分析

通过对具有街道峡谷特征的南京市中山路机动车的车流量污染物质量浓度和气象要素的调查与监测，了解到中山路机动车尾气污染物中CO，NO x的质量浓度与车流量有关，成正比关系，日车流量高峰时间分别在10：00，14：00和18：00。中山路环境容量分析是通过污染物扩散模型对CO，NOx污染物质量浓度模拟，其模拟结果和实测结果相近：CO质量浓度的模拟和实测结果比值在[0.5,2]区间的比例为96％，NOx质量浓度的模拟和实测结果比值在[0.5,2]区间的比例为80％，表明模拟结果有效。     

乌鲁木齐市汽车尾气污染状况调查

对乌鲁木齐市主要街道受汽车尾气污染的调查和综合分析得到CO、NOx、HC的污染规律,主要街道路中心空气中CO、NOx日均值已超出国家大气环境质量二级标准,市区主要街道的人行道空气中NOx含量已超出二级标准,Ⅱ、Ⅲ类道路人行道空气中CO含量已超标;在三类街道中,Ⅰ类街道车流量最大,Ⅱ类次之,Ⅲ类最少,而汽车排放尾气对街道空气污染状况为Ⅲ类最重、Ⅱ类次之、Ⅰ类最轻。     

机动车排气污染对城市道路空气质量的影响

通过对南京市珠江路道路空气质量的监测，掌握了机动车排气污染对街道空气质量的影响，分析了道路中NOx、NO2、CO的变化规律，以及污染物与车流量和大气扩散条件的关系．并通过与城市大气自动监测国控点监测数据的比较，得出国控点NOx、NO2浓度和道路中NOx、NO2浓度变化趋势一致．     

2020年江苏省机动车排放污染分布特征及与大气质量耦合性研究

依据生态环境部2021年6月发布的《排放源统计调查产排污核算方法和系数手册》,结合本地实测数据,在对汽油车颗粒物(PM)排放系数进行测算的基础上,核算了2020年江苏省机动车PM、氮氧化物(NO_(X))、挥发性有机物(VOC_(S))的排放总量,分析了机动车排放污染分布特征及与大气质量的耦合关系。结果表明:2020年江苏省机动车PM、NO_(X)、VOC_(S)排放量分别为0.5×10^(4),3.71×10^(5),1.17×10^(5) t。从区域分布来看,苏州、南京、无锡3市的3项污染物排放总量及NO_(X)、VOC_(S)排放量均位列前3位,PM排放量位列前3位的是苏州、徐州、无锡。从车型、燃料类型和排放阶段来看,国Ⅳ及以下排放标准的汽油小型客车是机动车VOC_(S)排放控制的重点,国Ⅲ排放标准的重型柴油货车是机动车PM和NO_(X)排放控制的重点。分析区域机动车PM排放量与大气中PM_(2.5)来源解析结果的耦合关系,其间存在不同程度的正相关性,控制机动车污染对改善大气环境会产生积极成效,南京、徐州和盐城3市的成效会尤为明显。     

南京市黄标车污染现状与管理对策

以南京市为例,依托机动车环保监管数据库,根据国家机动车排放模型CVEM计算出黄标车主要污染物一氧化碳、碳氢化合物、氮氧化物及颗粒物的年排放量,并系统回顾了近年来为控制黄标车污染所采取的区域限行、淘汰奖补和治理改造等针对性管理措施,分析了政策实施的进展及成效,进一步明确了黄标车治理的必要性。     

上海市汽车更新淘汰减排效果初步评估

选取2009年6月—2010年1月上海市汽车动态数据,讨论汽车污染物排放状况,分析汽车更新淘汰对大气环境的排放贡献影响。结果表明,上海市现行老旧车辆更新淘汰政策可以减少CO、HC、NOx、PM等污染物排放量43 565 t/a。鼓励老旧汽车淘汰更新政策对推进减排工作、改善城市大气环境有重要意义。     

Assessment of New Vehicles Emissions Certification Standards in the Metropolitan Area of Mexico City

Light duty gasoline vehicles account for most of CO hydrocarbons and NOx emissions at the Metropolitan Area of Mexico City (MAMC). In order to ameliorate air pollution from the beginning of 2001, Tier 1 emission standards became mandatory for all new model year sold in the country. Car manufacturers in Mexico do not guarantee the performance of their exhaust emissions systems for a given mileage. The purpose of this study was to assess whether the Tier 1 vehicles will stand the certification values for at least 162000 km with the regular fuel available at the MAMC. Mileage accumulation and deterioration show that certified carbon monoxide emissions will stand for the useful life of the vehicles but in the case of non-methane hydrocarbons will be shorter by 40%, and nitrogen oxides emissions above the standard will be reached at one third of the accumulated kilometers. The effect of gasoline sulfur content, on the current in use Tier 1 vehicles of the MAMC and the impact on the emissions inventory in year 2010 showed that 31000 extra tons of NOx could be added to the inventory caused by the failure of the vehicles to control this pollutant at the useful life of vehicles.     

An evaluation of improvements in the air quality of Beijing arising from the use of new vehicle emission standards

An innovative approach of mean emission by vehicle type was used in this paper to assess the impact of new vehicle emission standards in Beijing, China during the period of 2000–2005. It was found that CO and NO_x emissions decreased by 48% and 23%, respectively, from Type O (before 2000) to Type I (year 2000) vehicles. The reductions from Type O to Type II (year 2002) vehicles were 85% and 73% for CO and NO_x, respectively. When all three types of vehicles (Types O, I and II) are combined, the annual per vehicle CO emissions decreased from 586 kg per vehicle per year in 2000 to 324 kg per vehicle per year in 2005, while that of NO_x decreased from 66.9 to 43.4 kg per vehicle per year, which was mainly resulted from the impact of stringent new vehicle emission standards implemented in years 2000 and 2002. However, the vehicle population increased by 70% during the same time period, which offset the impact of cleaner vehicles. Thus, the total vehicle emission decreased little for CO (885,000 tons in 2000, 837,000 tons in 2005) and even increased slightly for NO_x (101,000 and 112,000 tons in 2000 and 2005, respectively). The ambient concentrations of CO decreased significantly throughout 2000–2005, the same trend was not observed for NO₂. Correlation analysis (grey correlation and Pearson correlation) between the annual vehicle emissions and annual concentrations of CO, the annual NO_x emission and annual NO₂ concentration indicated that the implementation of new vehicle emission standards was associated with the abatement of ambient CO and NO₂ concentrations in Beijing.     

New research assessing the effect of engine operating conditions on regulated emissions of a 4-stroke motorcycle by test bench measurements

In the latest years the effect of powered two-wheelers on air polluting emissions is generally noteworthy all over the world, notwithstanding advances in internal combustion engines allowed to reduce considerably both fuel consumption and exhaust emissions of SI engines. Nowadays, in fact, these vehicles represent common means of quotidian moving, serving to meet daily urban transport necessities with a significant environmental impact on air quality. Besides, the emissive behavior of the two-wheelers measured under fixed legislative driving standards (and not on the local driving conditions) might not be sufficiently representative of real world motorcycle riding.The purpose of this investigation is a deeper research on emissive levels of in-use motorcycles equipped with last generation SI engines under real world driving behavior. In order to analyze the effect of vehicle instantaneous speed and acceleration on emissive behavior, instantaneous emissions of CO, HC and NO_X were measured in the exhaust of a four-stroke motorcycle, equipped with a three-way catalyst and belonging to the Euro-3 legislative category. Experimental tests were executed on a chassis dynamometer bench in the laboratories of the National Research Council (Italy), during the Type Approval test cycle, at constant speed and under real-world driving cycles. This analytical-experimental investigation was executed with a methodology that improves vehicles emission assessment in comparison with the modeling approaches that are based on fixed legislative driving standards. The statistical processing results so obtained are very useful also in order to improve the database of emission models commonly used for estimating emissions from road transport sector, then they can be used to evaluate the environmental impact of last generation medium-size motorcycles under real driving behaviors.     

南京市机动车尾气检测监管系统的应用

通过研究建立南京市机动车尾气检测监管系统，在线实时监控检测全过程，确保检测行为的规范性和检测数据的真实性，从而强化了尾气定期检测的把关作用，促进在用车排放稳定达标。     

佛山市交通CO2排放及低碳出行对策

以佛山市2012年数据为基础,结合COPERT模型,分析了车型种类、排气量、燃油类型、排放水平等对CO2排放因子的影响规律,探讨了不同车型组成与排放水平下的CO2排放分担率,讨论并评估了佛山市的低碳交通出行对策。结果表明:排放水平对CO2排放因子的影响不明显,除重型客车与公交车,燃油类型对CO2排放因子的影响亦不明显,各车型的CO2排放因子随着排气量的增加而增加;当佛山市机动车平均行驶速度提高至55 km/h时,每辆车CO2综合排放因子可达最小值125.73 g/km;轻型客车和摩托车的CO2排放量最大,分别为1469 493 t/a和394 174.3 t/a,分担率分别为52.1%和14.0%;不同排放水平的载客车CO2排放分担率从大到小排序依次为:国I国0国Ⅱ国Ⅲ国Ⅳ,分别为34.7%、22.0%、21.2%、17.5%及4.6%。     

CO and NO2 pollution in a long two-way traffic road tunnel: investigation of NO2/NOx ratio and modelling of NO2 concentration

The CO, NO and NO2 concentrations, visibility and air flow velocity were measured using continuous analysers in a long Norwegian road tunnel (7.5 km) with traffic in both directions in April 1994 and 1995. The traffic density was monitored at the same time. The NO2 concentration exceeded Norwegian air quality limits for road tunnels 17% of the time in 1994. The traffic through the tunnel decreased from 1994 to 1995, and the mean NO2 concentration was reduced from 0.73 to 0.22 ppm. The ventilation fan control, based on the CO concentration only, was unsatisfactory and the air flow was sometimes low for hours. Models for NO2 concentration based on CO concentration and absolute air flow velocity were developed and tested. The NO2/NOx ratio showed an increase for NOx levels above 2 ppm; a likely explanation for this phenomenon is NO oxidation by O2. Exposure to high NO2 concentrations may represent a health risk for people with respiratory and cardiac diseases. In long road tunnels with two-way traffic, this study indicates that ventilation fan control based on CO concentration should be adjusted for changes in vehicle CO emission and should be supplemented by air flow monitoring to limit the NO2 concentration.