氯化铵盐粒导致的铜初期大气腐蚀行为研究

目的研究在氯化铵存在条件下,铜的大气腐蚀行为。方法采用扫描电子显微镜(SEM)、能谱(EDS)、傅里叶红外光谱(FT-IR)、X射线衍射(XRD)、滴定法和电化学等方法来确定铜的大气腐蚀过程和腐蚀产物。结果随着暴露时间的延长,铜的腐蚀质量损失变大,平均腐蚀速率变小。在氯化铵存在条件下,铜表面生成了Cu_2O、Cu_2(OH)_3Cl和Cu_2(OH)_2CO_3,其中Cu_2O为主要腐蚀产物,其质量占腐蚀产物总质量的97%以上。结论氯化铵的存在会对铜造成很强的腐蚀,随着暴露时间的延长,铜的腐蚀变得严重,但是暴露后期腐蚀速率将会减缓。     

利用含铝废盐酸制备聚合氯化铝

以某医药企业产生的含铝废盐酸为原料制备了液体聚合氯化铝(PAC)。确定了适宜的有机物去除方法和碱化剂,考察了碱化剂投加量、废盐酸铝离子含量等合成条件对PAC产品指标的影响,并比较了自制PAC和市售PAC对该企业污水站二沉池出水的混凝效果。实验结果表明:采用活性炭吸附法去除废盐酸中有机物,选择固体Ca O作为碱化剂,在活性炭投加量1‰(w)、吸附时间1 h、铝离子含量9.5%(w,以Al_2O_3计)、CaO投加量80 g/L、反应时间24 h的条件下,制备的液体PAC达到行业标准HG/T 2677—2017《工业聚氯化铝》中的Ⅲ类标准;自制PAC对废水COD和SS的去除率均优于市售PAC,不仅可替代其使用,还可外售产生经济效益。     

高岭土制备聚合氯化铝新工艺

介绍了以高岭土为原料，经盐酸预处理后，加水聚合、调整反应液pH，制备液体聚合氯化铝净水剂的新工艺。对所得产品的净水性能和技术指标进行了测定，结果表明，采用该工艺制得的聚合氯化铝产品技术指标符合GB1592－95标准。     

Long-term Changes in Environmental Variables of Traunsee,an Oligotrophic Austrian Lake Impacted by the Salt Industry,and Two Reference Sites Hallstättersee and Attersee

Morphometric, hydrological and basic physico-chemicalcharacteristics of three deep Alpine lakes, Traunsee,Hallstättersee and Attersee as well as their long-termbahaviour are presented. The deep Alpine lakesHallstättersee and Traunsee have been influenced by saltmining and the traditional salt industry for over 100 years. Waste products from these activities, entering the lakes, have mainlyaffected the chemistry of these water bodies, especially bysubstantially increasing the chloride concentrations up to 170 mg L^-1. As a consequence of the increased density, mixing conditions of the lakes were altered. The resulting incomplete mixing led to oxygen depletionin deeper layers. In addition, increased nutrientload from the catchment rised the trophic level in the 70s and 80sof the last century in turn, affecting the oxygen content in thehypolimnion. Finally a situation developed where the risk becamehigh for these lakes to become meromictic induced by humanactivity. In fact, Hallstättersee became facultativelymeromictic. This process was interrupted by increased chlorideinput of more than 30 mg L^-1 due to accidental wash outfrom an upstream salt mine rendering Hallstätterseehomogenous in 1978 to 1980 resulting in complete over-turn. Conditions substantially improved in both lakes after miningpractices were altered and restoration measures againsteutrophication were initiated. Chloride and phosphorusconcentrations declined, while oxygen conditions substantiallyimproved in the following years. Conditions in Traunseesubstantially improved and chloride levels near the sedimentdecreased to less than 140 mg L^-1. The third lakeconsidered here, Attersee, always remained in a near-naturalstate although some signs of increased nutrient levels becamevisible in the late 1970s. Chloride concentrations of around 3 mgL^-1 in this lake can be considered as background levels.Attersee can now serve as a reference site for deep Alpine lakesbecause of its ultra-oligotrophic and pristine nature.     

简易流动注射仪化学发光法测定水环境中的铵态氮

在０．１Ｍ的碱性条件下，ＮＢＳ（Ｎ—溴代丁二酰亚　胺）在荧光素的增敏作用下氧化氯化铵，产生强的化学发光。基于此本文详细研究了其反应　的特性和影响因素，在优化的实验条件下体系对氯化铵的测定范围为１．０×１０－７～１　．５×１０－５ｇ／ｍＬ，检出限为３．６×１０－８ｇ／ｍＬ，对５．０×１０－６ｇ／ｍＬ氯化铵　进行１１次平行测定，其ＲＳＤ为２．８％。将本法用于环境水样中ＮＨ＋４的分析，并与常规的　方法进行对照，获得了满意的结果。     

废二氯甲烷回收工艺的研究

文章为使废二氯甲烷回收再利用,研究了直接精馏和洗料精馏两种回收工艺,确定采用洗料-精馏回收方法可以使废二氯甲烷的收率达95%以上,且回收后的二氯甲烷的各项指标均达到再利用的标准.     

气相色谱法测定地下水中氯化苄

建立了气相色谱法测定地下水中氯化苄的方法。选用ＧＤＸ５０２大孔树脂或Ｃ１８小预处理柱吸附浓缩地下水中氯化苄，用苯洗脱，洗脱液注入色谱仪进行分析。方法回收率为８６４９８１％，变异系数＜８％。     

氯化亚砜生产的环境风险评价

用危险指数法对氯化亚砜生产过程各单元的风险性进行了评价，预测了制备锅爆炸事故的环境影响范围和程度。     

Effects of hydrogen addition on the confined and vented explosion behavior of methane in air

Multi-component gas mixture explosion accidents occur and recur frequently, while the safety issues of multi-component gas mixture explosion for hydrogen–methane mixtures have rarely been addressed.Numerical simulation study on the confined and vented explosion characteristics of methane-hydrogen mixture in stoichiometric air was conducted both in the 5 L vessel and the 64 m³ chamber, involving different mixture compositions and initial pressures. Based on the results and analysis, it is shown that the addition of hydrogen has a negative effect on the explosion pressure of methane-hydrogen mixture at adiabatic condition. While in the vented explosion, the addition of the hydrogen has a significant positive effect on the explosion hazard degree. Additionally, the addition of hydrogen can induce a faster reactivity and enhance the sensitivity of the mixture by reducing the explosion time and increasing the rate of pressure rise both in confined and vented explosion. Both the maximum pressure and the maximum rate of pressure rise increase with initial pressure as a linear function, and also rise with the increase of hydrogen content in fuel. The increase in the maximum rate of pressure rise is slight when hydrogen ratio is lower than 0.5, however, it become significant when hydrogen ratio is higher than 0.5. The maximum rate of pressure rise for stoichiometric hydrogen-air is about 10 times the one of stoichiometric methane-air.Furthermore, the vent plays an important role to relief pressure, causing the decrease in explosion pressure and rate of pressure rise, while it can greatly enhance the flame speed, which will extend the hazard range and induce secondary fire damages. Additionally it appears that the addition of hydrogen has a significant increasing effect on the flame speed. The propagation of flame speed in confined explosion can be divided into two stages, increase stage and decrease stage, higher hydrogen content, higher slope. But in the vented explosion, the flame speed keeps increasing with the distance from the ignition point.