基于OPMSE的畜禽养殖行业排放限值仿真

通过对清河流域畜禽养殖行业产生污水的各指标(BOD5,COD,NH_3-N)浓度进行统计,得出了排放污水中各污染物指标的浓度值范围。通过OPMSE的仿真计算,得出了排放污水经过BAT处理后,污染物浓度正态分布均值在90%,95%,99%置信水平下的置信区间。在置信水平为99%时,畜禽养殖行业的COD置信区间为(42.00,48.19),BOD_5置信区间为(7.47,8.74),NH_3-N置信区间为(6.78,7.88)。同时,依据仿真计算结果还得出了处理后污染物浓度的极小值和极大值,畜禽养殖行业的最佳出水COD,BOD_5,NH3_-N指标质量浓度分别为22.0,2.1,3.09 mg/L,最差出水COD,BOD_5,NH_3-N指标质量浓度分别为84.4,14.2,13.29 mg/L。将仿真结果与现有排放标准对比,拟定畜禽养殖行业的COD,BOD_5,NH_3-N直接排放限值分别为50,9,8 mg/L。     

我国钢铁工业一次颗粒物排放量估算

针对我国钢铁工业生产工艺以及颗粒物控制技术的分类,建立了一个细化到排放节点的自下而上的颗粒物排放模型.结合我国钢铁工业各地区活动水平以及颗粒物控制技术分布的历史变化趋势分析,利用此模型计算了2006—2012年我国钢铁工业一次颗粒物的排放系数和排放量.模型计算结果显示,2006年以来,我国钢铁工业颗粒物控制水平不断提高,PM_(2.5)、PM_(2.5)~10和PM10的排放系数分别降低了21.2%、19.3%和19.0%.钢铁工业一次颗粒物排放量在2006—2011年间持续增长,2011年TSP排放量为602×104t,PM10排放量为200×104t,PM_(2.5)排放量为124×104t;2012年排放量出现下降,TSP排放量为561×104t,PM10排放量为187×104t,PM_(2.5)排放量为116×104t.2012年我国钢铁工业一次PM_(2.5)排放量中的有组织排放占39.5%,无组织排放占60.5%;除加严有组织源管控之外,减少颗粒物无组织排放,对于钢铁工业颗粒物排放控制也非常重要.我国钢铁工业颗粒物排放量分布不均衡,河北、山东、江苏、辽宁、山西5个省的排放超过全国总排放的50%.     

化工规划项目的水环境影响评价研究

目前没有针对规划项目的水环境影响评价的技术导则,化工规划项目具有建设内容复杂、建设范围大、建设周期长等特点,且不确定性强,产生污染物种类多、数量大,对周边区域的环境影响复杂.针对化工规划项目的水环境影响评价特点与评价要求,参考国内现有行业标准规范与水评价导则技术要求,文章通过案例应用对化工规划项目的水环境影响评价从规划方案水污染源强分析、水环境影响预测、水环境承载力的测算及环境减缓措施等方面给出具体说明与实施方法,为今后规划环境影响评价工作提供依据和技术参考.     

区域次生环境风险评价方法研究

针对化工园区内各装置次生环境风险进行了系统研究,建立了一套区域次生风险识别方法,并且以成品油储罐区和7万吨苯抽提装置为例对研究区燃爆类风险源和泄漏类风险源分别进行次生环境风险分析,识别化工园区内对环境有潜在威胁的风险源,结果表明：有8个危险源存在次生风险事故,且对可能发生的次生事故类型进行分析,为化工园区的次生环境风险的监控和防范提供了依据。     

火电行业"十三五"主要大气污染物减排潜力情景分析研究

火电行业是总量减排的重点行业,也是主要大气污染物削减量的首要贡献者,其主要大气污染物排放量的削减抵消了其他行业的排放增长,为"十二五"全国减排任务的完成做出了重大贡献.本研究在火电行业主要大气污染物排放控制现状分析的基础上,结合火电行业技术政策措施要求,对火电行业"十三五"新增排放量进行了预测,并设置基于技术可行、排放标准以及超低排放三套减排情景,测算"十三五"减排潜力,评估火电行业"十三五"减排空间,对全国及各省火电行业减排形势提出了相应的意见和建议.     

钢铁行业烧结烟气脱硫技术现状和发展趋势

钢铁行业烧结过程产生的二氧化硫占钢铁企业产生二氧化硫总量的一半以上,理应作为钢铁企业二氧化硫控制的重点。我国已建设多个烧结脱硫示范工程,并取得了良好的脱硫效果。在分析烧结烟气特点前提下,阐述了目前国内采用的几种脱硫工艺的优缺点,比较了密相干塔烟气脱硫、石灰乳脱硫、石灰石-石膏法脱硫、氨法脱硫、循环流化床脱硫、活性炭脱硫、双碱法脱硫等方法的优点与缺点,为烧结烟气脱硫技术选择提供了参考。     

建立优质种苗示范基地，加快发展海南椰子产业

通过对海南椰子生产现状的分析，本文指出了建立优质良种椰子种苗生产示范基地的必要性和重要性，并针对一些需要解决的问题，提出了加快海南椰子产业发展的建议。     

Evaluation of recycling waste materials and by-products in highway construction

SUMMARY

The generation, handling, and safe disposal of waste materials has become a major concern in North America. Approval of facilities for waste processing and proper disposal is becoming more difficult to obtain. Furthermore, there is a growing public awareness of the importance of conserving and preserving our valuable natural resources. This expanding awareness has given rise to the trend towards recycling or reuse of awide variety of solid wastes. Experiences with using waste materials in highway construction can vary considerably, depending on material characteristics, construction processes, and climatic differences. A number of waste materials may be suitable for use in highway construction, but others may not. The objective of this paper is introduced in two tasks. The first is to include a survey of the waste materials and by-products that have been used successfully, or may be used, as materials for highway construction or maintenance work. This also includes determination of the state of practice concerning economic and technical factors for these wastes. The second is to rank these materials based on three criteria: number of uses by State agencies, economic uses and performance aspects.     

Application of digital technologies about water network in steel industry

To improve the efficiency of water use and reuse, a digitalized water network system was implemented in a steel industrial complex. The system consisted of four parts: online instrument and sensing devices, programmable logic controller, data communication network and control center based on expert knowledge. The system achieved real-time monitoring, diagnosis, and early warning of cooling water system using data collected inline, and enabled data connectivity and transmission of self-developed software applications on personal computer. This research used a steel enterprise as a case study. After the analysis of its cooling water system and water-saving potential using water balance test, a digitalized water network was evaluated and implemented, and we believe this network can be suitable for steel industry in general.     

Current EU-27 technical potential of organic waste streams for biogas and energy production

Anaerobic digestion of organic waste generated by households, businesses, agriculture, and industry is an important approach as method of waste treatment – especially with regard to its potential as an alternative energy source and its cost-effectiveness. Separate collection of biowaste from households or vegetal waste from public green spaces is already established in some EU-27 countries. The material recovery in composting plants is common for biowaste and vegetal waste. Brewery waste fractions generated by beer production are often used for animal feeding after a suitable preparation. Waste streams from paper industry generated by pulp and paper production such as black liquor or paper sludge are often highly contaminated with toxic substances. Recovery of chemicals and the use in thermal processes like incineration, pyrolysis, and gasification are typical utilization paths. The current utilization of organic waste from households and institutions (without agricultural waste) was investigated for EU-27 countries with Germany as an in-depth example. Besides of biowaste little is known about the suitability of waste streams from brewery and paper industry for anaerobic digestion. Therefore, an evaluation of the most important biogas process parameters for different substrates was carried out, in order to calculate the biogas utilization potential of these waste quantities. Furthermore, a calculation of biogas energy potentials was carried out for defined waste fractions which are most suitable for anaerobic digestion. Up to 1% of the primary energy demand can be covered by the calculated total biogas energy potential. By using a “best-practice-scenario” for separately collected biowaste, the coverage of primary energy demand may be increased above 2% for several countries. By using sector-specific waste streams, for example the German paper industry could cover up to 4.7% and the German brewery industry up to 71.2% of its total energy demand.