化工废水处理中关键有毒物质追踪

江苏省某化工厂废水设施的进、出水经Daphnia magna急性毒性试验，结果表明该废水在处理前、后均显示毒性。采用毒性鉴别评价(TIE，toxicity identification evaluation)的试验程序，对处理系统的进、出水进行了关键毒物的鉴别和评价。发现进水中存在的关键毒物为金属铜离子，而出水中存在的关键毒物为氨。该厂原废水毒性已基本被去除，毒性去除率为99．93％。因此，在该厂废水处理过程中金属离子尤其是铜离子已基本被去除，而氨在废水处理中的去除并不明显。     

三种安全评价方法在苏丹化工项目的应用比较分析与实践

为解决海外炼化项目存在的资源短缺、员工技能不足和管理文化冲突等问题,提高海外炼化项目安全管理水平,本文通过对比苏丹化工项目所采用的3种不同安全评价方法,分析出不同方法的优缺点和适用性。基于此,苏丹化工项目采用这3种评价方法,很好地弥补了单一评价方法的不足,查找出了主要的安全管理漏洞,识别出重大隐患所在,有效防范了各类安全风险,项目的安全管理水平得到了显著提高。     

气象条件对河北廊坊城市空气质量的影响

气象条件是影响大气污染的重要因子.利用2013年3月—2014年2月廊坊颗粒物质量浓度监测资料、自动气象站观测资料和欧洲中期天气预报中心再分析资料,采用多种统计方法分析气象与污染的关系,量化天气形势和局地气象条件对城市颗粒物质量浓度变化的贡献.结果表明:天气形势是决定局地气象要素和城市空气质量的重要因子.当廊坊位于高压中心或高压后部时,大气层结稳定,易造成重污染;当廊坊位于高压前部(气压梯度较大)时,大气层结不稳定,易于污染物输送和扩散.利用客观天气分型结合污染物质量浓度统计分析方法,可以量化天气形势对城市空气质量的影响.在局地气象要素中,能见度与ρ(PM_2.5)、ρ(PM₁₀)相关性最高(相关系数分别为-0.75和-0.53,下同),其次依次为风速(-0.45和-0.31)、相对湿度(0.41和0.25)和温度(-0.15和-0.06).通过污染物浓度与局地风场关系分析发现,廊坊颗粒物质量浓度受天津市、河北省南部区域输送的影响明显,受北京区域输送的影响相对较弱.研究显示,气象条件可以解释廊坊ρ(PM_2.5)和ρ(PM₁₀)日均值变化的56%和49%,其在冬季对颗粒物质量浓度影响最为显著,春秋季次之,夏季影响最小.      

廊坊市区主要大气污染源排放清单的建立

通过调研、统计廊坊市区工业、城中村及机动车等资料,结合以往清单文献研究结果及清单编制指南中的排放因子,计算了廊坊市区主要大气污染物的排放量,得到廊坊市区2014年主要大气污染源排放清单.结果显示,2014年廊坊市区工业源(固定燃烧)NO_x、SO_2、NMVOC、CO、PM_(10)、PM_(2.5)排放总量分别为6.4×10~3、1.2×10~4、31、1.0×10~4、7.3×10~2、4.4×10~2t,其中热电行业排污贡献率最高,分别占NO_x、SO_2、CO、PM_(10)、PM_(2.5)工业源(固定燃烧)年排放总量的55%、48%、67%、63%、69%;安次区工业企业对气态污染物贡献较高,广阳区及开发区工业企业对颗粒物排污贡献较大.低矮面源(城中村)NO_x、SO_2、NMVOC、CO、PM10、PM_(2.5)年排放总量分别为1.8×10~2、3.6×10~3、3.0、4.9×10~3、1.5×10~2、72 t.道路移动源CO、HC、NO_x、PM_(2.5)年排放总量分别为2.4×10~4、1.9×10~3、2.2×10~3、44 t,其中小型客车对HC和CO贡献率较高,分别为53%和61%;NO_x年排放总量中26%由重型货车贡献;PM_(2.5)则主要由轻型货车和重型货车贡献,占比分别为39%和21%.     

基于PHA-LEC法金属矿山盲竖井工程安全分析研究

针对盲竖井工程的危险、有害因素的危害程度及特殊工艺,将盲竖井施工系统分为卷扬机硐室开凿、盲竖井掘进、爆破、吊桶提升、出碴、竖井提升装置安装、施工通风7个主要子系统,在对矿山的盲竖井施工事故数据充分调查和分析的基础上,运用预先危险性分析法(PHA)对盲竖井施工的危险、危害因素进行辨识和定性分析,结合生产作业条件安全评价方法(LEC)对盲竖井系统中各子系统进行危险性评价,定量分析计算PHA的危险等级,提出科学预防措施。PHA-LEC法为盲竖井施工安全分析提供了新的模式,为制定防范措施和管理决策提供科学依据,具有一定的实际指导意义。     

Advanced treatment of biologically pretreated coal gasification wastewater by a novel heterogeneous Fenton oxidation process

Sewage sludge from a biological wastewater treatment plant was converted into sewage sludge based activated carbon(SBAC) with Zn Cl2 as activation agent, which was used as a support for ferric oxides to form a catalyst(Fe Ox/SBAC) by a simple impregnation method.The new material was then used to improve the performance of Fenton oxidation of real biologically pretreated coal gasification wastewater(CGW). The results indicated that the prepared Fe Ox/SBAC significantly enhanced the pollutant removal performance in the Fenton process, so that the treated wastewater was more biodegradable and less toxic. The best performance was obtained over a wide p H range from 2 to 7, temperature 30°C, 15 mg/L of H2O2 and 1 g/L of catalyst, and the treated effluent concentrations of COD, total phenols,BOD5 and TOC all met the discharge limits in China. Meanwhile, on the basis of significant inhibition by a radical scavenger in the heterogeneous Fenton process as well as the evolution of FT-IR spectra of pollutant-saturated Fe Ox/BAC with and without H2O2, it was deduced that the catalytic activity was responsible for generating hydroxyl radicals, and a possible reaction pathway and interface mechanism were proposed. Moreover, Fe Ox/SBAC showed superior stability over five successive oxidation runs. Thus, heterogeneous Fenton oxidation of biologically pretreated CGW by Fe Ox/SBAC, with the advantages of being economical, efficient and sustainable, holds promise for engineering application.     

Nitrogen removal from coal gasification wastewater by activated carbon technologies combined with short-cut nitrogen removal process

A system combining granular activated carbon and powdered activated carbon technologies along with shortcut biological nitrogen removal （GAC-PACT-SBNR） was developed to enhance total nitrogen （TN） removal for anaerobically treated coal gasification wastewater with less need for external carbon resources. The TN removal efficiency in SBNR was significantly improved by introducing the effluent from the GAC process into SBNR during the anoxic stage, with removal percentage increasing from 43.8%49.6% to 68.8%-75.8%. However, the TN removal rate decreased with the progressive deterioration of GAC adsorption. After adding activated sludge to the GAG compartment, the granular carbon had a longer service-life and the demand for external carbon resources became lower. Eventually, the TN removal rate in SBNR was almost constant at approx. 43.3%, as compared to approx. 20.0% before seeding with sludge. In addition, the production of some alkalinity during the denitrification resulted in a net savings in alkalinity requirements for the nitrification reaction and refractory chemical oxygen demand （COD） degradation by autotrophic bacteria in SBNR under oxic conditions. PACT showed excellent resilience to increasing organic loadings. The microbial community analysis revealed that the PACT had a greater variety of bacterial taxons and the dominant species associated with the three compartments were in good agreement with the removal of typical pollutants. The study demonstrated that pre-adsorption by the GAC-sludge process could be a technically and economically feasible method to enhance TN removal in coal gasification wastewater （CGW）.     

Effect of alkalinity on nitrite accumulation in treatment of coal chemical industry wastewater using moving bed biofilm reactor

Nitrogen removal via nitrite （the nitrite pathway） is more suitable for carbon-limited industrial wastewater. Partial nitrification to nitrite is the primary step to achieve nitrogen removal via nitrite. The effect of alkalinity on nitrite accumulation in a continuous process was investigated by progressively increasing the alkalinity dosage ratio （amount of alkalinity to ammonia ratio, mol/mol）. There is a close relationship among alkalinity, pH and the state of matter present in aqueous solution. When alkalinity was insufficient （compared to the theoretical alkalinity amount）, ammonia removal efficiency increased first and then decreased at each alkalinity dosage ratio, with an abrupt removal efficiency peak. Generally, ammonia removal efficiency rose with increasing alkalinity dosage ratio. Ammonia removal efficiency reached to 88% from 23% when alkalinity addition was sufficient. Nitrite accumulation could be achieved by inhibiting nitrite oxidizing bacteria （NOB） by free ammonia （FA） in the early period and free nitrous acid in the later period of nitrification when alkalinity was not adequate. Only FA worked to inhibit the activity of NOB when alkalinity addition was sufficient.     

两种生物农药对土壤蔗糖酶活性的影响

采集海南省儋州市国家热带农业高新技术示范园土样中农田土样,在分析土壤基本理化性质的基础上,用3,5-二硝基水杨酸比色法测定法.研究了不同模拟条件下苏云金杆菌、井冈霉素A对土壤蔗糖酶活性的影响.结果表明:不同浓度、pH条件下这两种生物农药对土壤蔗糖酶表现出不同程度的激活作用.在30 d的培养时间内,苏云金杆菌(bacillus thuringiensis)对土壤蔗糖酶活性影响的趋势是激活→抑制→恢复,而且波动范围较大;井岗霉素A(jinggangmycin A)对土壤蔗糖酶活性影响程度相对较小,总的趋势是激活→抑制.总体来看,施用这两种生物农药有利于提高土壤蔗糖酶的活性.