截齿截割煤体变形破坏过程数值模拟研究

采用应变软化的模型,使用连续介质快速拉格朗日分析法(FLAC,FastLagrangianAnaly-sisofContinue)进行数值模拟计算;研究截齿截割作用下煤体变形破坏过程;分析各种工况下不同参数对煤体塑性区、最大位移、最大主应力、最大剪应力的影响。研究表明:截割力与塑性区大小成正比,位移、剪应力、主应力随截割力增大而增大;截深与塑性区大小成反比;截割角度与塑性区面积关系密切,试验用煤体最佳截割角度为5°左右;截割速度增加,塑性区面积减小;通过分析截割动态过程,得到位移矢量图及剪应变等值线图,发现截割过程中煤体的破坏是拉、剪联合作用的结果,以剪破坏为主。     

华南沿海某大气背景点黑碳气溶胶污染特征

黑碳气溶胶(BC)因其显著的气候效应和对人类健康的危害而成为研究的热点。研究背景点位BC的浓度水平和来源特征有助于掌握BC在区域尺度上的辐射强迫特性和环境影响。2009年秋季在华南沿海某区域大气背景点进行了为期约40 d的BC在线观测。观测期间BC的平均浓度为(2.34±1.33)μg/m3,与其它区域背景点相比处于较高水平。利用中尺度天气研究和预报系统WRF模拟的高分辨率三维气象场数据驱动HYSPLIT-4反向轨迹模式,模拟观测期间每小时的气团轨迹,将所有轨迹分为来源特征明显的东北沿海、北方内陆、香港方向和东南海面方向四类。当受到东北沿海来源气团影响时,BC的浓度为平均水平的1.4倍,BC和CO有较好的线性相关关系,而其它三类气团影响时的BC浓度都低于平均浓度,且BC和CO的相关关系很差,说明来自东北沿海地区的较近距离区域传输是影响该背景点大气BC的主要源区。     

Validation of a Lagrangian dispersion model implementing different kernel methods for density reconstruction

In this paper the inert version of a Lagrangian particle model named photochemical Lagrangian particle model (PLPM) is described and validated. PLPM implements four density reconstruction algorithms based on the kernel density estimator. All these methods are fully grid-free but they differ each other in considering local or global features of the particles distribution, in treating the Cartesian directions separately or together and in being based on receptors or particles positions in space. Each kernel has been shown to have both advantages and disadvantages, but the overall good performances of the model when compared with the well known Copenhagen and Kincaid data sets are very encouraging in view of its extension to fully chemically active simulations, currently under development.     

洛阳市大气细颗粒物化学组分特征及溯源分析

为研究洛阳市大气细颗粒物(PM2.5)的化学组分及来源的时空分布特征,对汾渭平原地区较为欠缺的PM2.5相关研究进行补充,在2018年4月至2019年1月在洛阳市高新和林校2个点位进行了样品采集,对P(PM2.5)、化学组分(水溶性离子、碳质组分、元素)和来源进行分析.2个点位的年均ρ(PM2.5)分别为(76.6±37.9)μg-m-3和(83.2±38.9)μg·m-3,季节变化由高到低均为:冬季、春季、秋季和夏季.高新和林校的9种水溶性离子浓度分别占PM2.5的 55.1％和54.2％,林校的二次离子(NO3-、SO42-和NH4+)年均浓度之和高于高新.高新和林校的ρ[有机碳(OC)]、P[元素碳(EC)]分别为(12.4±7.7)μg·m-3、(1.2±0.5)μg·m-3和(13.4±7.7)μg·m-3、(1.3±0.5)μg·m-3,林校的含碳组分在各季节均高于高新;高新和林校冬季的二次有机碳(SOC)在OC中质量分数分别为67.8％和77.3％,远高于其他季节.化学质量平衡结果表明,高新和林校的主要贡献源均为二次硝酸盐(26.9％和27.1％)、二次硫酸盐(14.5％和14.8％)、燃煤(12.6％和11.6％)、SOA(10.8％和12.2％),高新的生物质源贡献较高,而林校的扬尘源和机动车源贡献较高.后向轨迹和潜在源贡献因子分析表明,洛阳市春季不仅受到来自西北方向的传输,来自西南地区的污染传输也不能忽略;夏季既受到正东方向的季风影响,又有来自正南方向的潜在污染;秋季污染物主要来自东南方向,同时也存在西北方向的潜在来源;冬季受到的传输影响则主要来自周边区域,污染来源较为集中.     

Testing the importance of accurate meteorological input fields and parameterizations in atmospheric transport modelling using dream - validation against ETEX-1

A tracer model, the DREAM, which is based on a combination of a near-range Lagrangian model and a long-range Eulerian model, has been developed. The meteorological meso-scale model, MM5V1, is implemented as a meteorological driver for the tracer model. The model system is used for studying transport and dispersion of air pollutants caused by a single but strong source as, e.g. an accidental release from a nuclear power plant. The model system including the coupling of the Lagrangian model with the Eulerian model are described. Various simple and comprehensive parameterizations of the mixing height, the vertical dispersion, and different meterological input data have been implemented in the combined tracer model, and the model results have been validated against measurements from the ETEX-1 release. Several different statistical parameters have been used to estimate the differences between the parameterizations and meterological input data in order to find the best performing solution.     

广州市臭氧污染溯源:基于拉格朗日光化学轨迹模型的案例分析

分析了2018年10月初广州市一次为期6 d的臭氧污染事件,利用拉格朗日光化学轨迹模型对广州市的臭氧污染进行了溯源分析,量化了不同区域对臭氧污染的贡献,评估了重点排放区域不同行业和不同前体物减排对臭氧污染控制的效果.结果表明,本次污染事件期间,日最大8 h臭氧均值均超过160 μg·m^-3,最高达271 μg·m^-3,氮氧化物（NO_x）和挥发性有机物（VOCs）的平均浓度为（77.7±42.8）μg·m^-3和（71.9±56.2）μg·m^-3.芳香烃和烯烃是主要的VOCs反应活性物种,分别贡献了38%和30%的·OH反应活性以及51%和16%的臭氧生成潜势.本次臭氧污染事件主要受3类气团输送影响,3类气团中的高排放区域分别为广东省外、广东省内和广州市本地,在高排放区域中臭氧生成均受VOCs控制.途经区域前体物减排的敏感性分析表明,减排VOCs对于降低臭氧浓度的效果优于减排NO_x.在100%减排情况下控制高排放区域的交通源排放对广州市臭氧控制的效果（臭氧降低14.6%~21.0%）高于控制工业（8.4%~15.3%）、电厂（0.9%~6.2%）和民用源（2.3%~4.7%）的排放,但单独控制交通源在小于90%减排比例下对臭氧污染控制的效果并不显著（<10%）.此外,珠江三角洲地区的生物源排放也对臭氧生成有重要贡献,在模型中关闭生物源排放后,广州市臭氧浓度降低6%~19%.本研究证实了拉格朗日光化学轨迹模型在区域臭氧污染溯源的应用效果,并为广州市臭氧污染的区域协同控制提供了对策建议.     

石家庄市大气污染物的季节性时空特征及潜在源区

为系统研究石家庄市季节性典型污染物的重污染传输特征,基于2018年12月~2019年11月46个环境监测站（PM_2.5、PM₁₀、O₃、NO₂、SO₂和CO）及17个气象站（温度、湿度和风速）的小时监测数据,利用插值（IDW）和相关方法,分析污染物的季节性时空特征;并结合GDAS数据,采用后向轨迹方法,研究污染物的季度传输格局和潜在源区.结果表明：①不同季节具有典型的污染物,季节性典型污染物和污染率依次为：春季（PM₁₀,48.91%）、夏季（O₃,81.97%）、秋季（PM₁₀和PM_2.5,47.54%和32.79%）和冬季（PM_2.5,74.44%）,其与气象条件变化有显著联系;②春季PM₁₀与风速呈负相关,呈西北高、东南低的空间格局,主要传输方向为南向（53.32%）,潜在源区（WPCWT_ij≥160 μg ·m^-3）为河北（冀）中南、河南（豫）中北及山西（晋）中部,且山东（鲁）西和陕西（陕）西北部的传输也会贡献（WPSCF_ij≥0.3）市域的PM₁₀浓度;③夏季O₃与温度呈正相关,与湿度呈负相关,传输通道方向为东南-南向（54.24%）,其潜在源区呈以石家庄市为中心,沧州和菏泽为两翼的新月形区域;④秋季和冬季PM_2.5与湿度呈正相关,冬季呈西低、东高态势分布,输送方向为：秋季（东北-东南,74.75%）,冬季（西北,55.47%）,主要污染源区（WPCWT_ij≥180 μg ·m^-3）集中在冀中南、豫北和晋中西部.     

Simulation analysis of environmental risk accident and management of high-sulfur gas field development in complex terrain

Environmental risk of high sulfur gas field exploitation has become one of the hot spots of environmental management studies. Severe gas H₂S blowout accidents in recent years have shown that poor understanding and estimates of the poisonous gas movement could lead to dangerous evacuation delays. It is important to evaluate the real concentration of H₂S, especially in complex terrain. Traditional experiential models are not valid in the case of rough terrain, especially in low-lying areas where the gas accumulates. This study, using high sulfur content gas field of Sichuan “Pu Guang gas field” as study object and adopting objective diagnosis of wind field of land following coordinate three dimensions, applied Lagrangian Puff Model and breaking up technique of puffs to simulate the H₂S diffusion condition of blowout accidents produced in the high sulfur content gas field of complex terrain area. The results showed that the H₂S distribution did not occur mainly in low wind direction, and due to the obstruction of the mountain’s body, it accumulated in front of mountain on produced turn over, flowed around submitted jumping type distribution. The mountain waist near the hilltop and low hollow river valley site rapture points simulating contrast showed that the higher the rapture point, the better the diffusing condition of pollutant, the distribution of risk sensitive point decided piping rupture environmental risk size combining the H₂S diffusion result and residential area dispersing in the study area, synthetic judge located in the high rapture point environmental risk was smaller than the low hollow point, thus it was suggested to carryout laying of lining build of equal high line of higher terrain. According to simulation results, the environmental risk management measures aimed at putting down adverse effects were worked out.     

Simulating mesoscale transport and diffusion of radioactive noble gases using the Lagrangian particle dispersion model

In order to simulate the impact of mesoscale wind fields and to assess potential capability of atmospheric Lagrangian particle dispersion model (LPDM) as an emergency response model for the decision supports, two different simulations of LPDM with the mesoscale prognostic model MM5 (Mesoscale Model ver. 5) were driven. The first simulation of radioactive noble gas ((85)Kr exponent) emitted during JCO accident occurred from 30 September to 3 October 1999 at Tokai, Japan showed that the first arriving short pulse was found in Tsukuba located at 60km away from the accidental area. However, the released radioactive noble gas was transported back to the origin site about 2 days later due to the mesoscale meteorological wind circulation, enhancing the levels of (85)Kr with the secondary peak in Tsukuba. The second simulation of atmospheric dilution factors (the ratio of concentration to the emission rate, chi/Q), during the underground nuclear test (UNT) performed by North Korea showed that high chi/Q moved to the eastward and extended toward southward in accordance with the mesoscale atmospheric circulations generated by mesoscale prognostic model MM5. In comparison with the measurements, the simulated horizontal distribution patterns of (85)Kr during the JCO are well accord with that of observation in Tsukuba such as the existence of secondary peak which is associated with the mesoscale circulations. However, the simulated level of (85)Kr anomaly was found to be significantly lower than the observations, and some interpretations on these discrepancies were described. Applications of LPDM to two mesoscale emergency response dispersion cases suggest the potential capability of LPDM to be used as a decision support model provided accurate emission rate of accident in case of a large accident.     

晋中盆地主要城市冬季PM2.5传输特征分析

对2017～2019年晋中盆地主要城市PM₁₀和PM_2.5逐时浓度资料进行了分析,给出了晋中市和太原市颗粒物浓度主要分布特征;此外利用PM_2.5逐时浓度资料,结合HYSPLIT后向轨迹模型,通过轨迹密度分析（TDA）、轨迹停留时间分析（RTA）和潜在源贡献因子分析（PSCF）,并对PM_2.5逐时浓度资料和对应时刻风向数据进行分析,探讨了晋中盆地主要城市冬季PM_2.5传输特征.结果表明,太原市颗粒物浓度整体水平高于晋中市,月、季变化特征类似,均呈现冬季高,夏季低的特征,最高值出现在1月.晋中市受静稳型天气形势引起的颗粒物污染较受沙尘型天气形势导致的颗粒物污染相较太原市更普遍一些;颗粒物的分布呈现出晋中市中间值较多,太原市高值偏多、低值偏少的特点,冬季为晋中盆地PM_2.5污染高发季节.晋中盆地主要城市冬季PM_2.5传输通道均可分为4类：第一类通道沿太行山横谷传输,第二类通道为偏东南方向传输通道,第一、二类均为近距离传输通道,气团会携带较多...