酸性水储罐安全性研究

为预防酸性水储罐气相空间闪爆事故的发生,取样分析了某炼厂酸性水罐气相空间组成,根据气相组成配制了3种混合可燃气体,利用5 L爆炸极限测试仪测定了混合可燃气体在不同氧含量条件下的爆炸极限,根据爆炸极限数据计算出3种混合可燃气体的极限氧含量。结果表明:随着体系中氧含量增加,爆炸上限明显升高,爆炸下限无明显变化;烃类物质含量高时,混合可燃气体的爆炸上下限均降低,爆炸极限宽度变小;硫化氢和氢气含量高时,混合可燃气体爆炸上下限均升高,爆炸极限宽度变大;3种气相组成的极限氧含量分别为:8.1%、9.9%和10.3%,为防止罐顶气相组成发生闪爆,建议氧含量浓度控制在4%以内,当氧含量浓度到达5%时建议启动氮气联锁进行惰化和稀释。     

兰州市废旧手机产生量预测分析研究

手机普及率日益提高,随之产生的废弃量也日益增多,分别采用时间梯度模型、市场供给A模型、斯坦福(stanford)模型对兰州市2013年-2022年废旧手机的产生量进行了预测.结果显示,不同模型预测结果之间存在较大差异,市场供给A模型和斯坦福(Stanford)模型的预测结果比较接近,均大于时间梯度模型的预测结果,三种模型预测的兰州市2022年废旧手机的产生量分别为40.40万、46.67万和21.04万部.总体上看,兰州市废旧手机的产生量增长趋势较快.     

基于AHP-模糊综合评价法的规划环境影响评价有效性研究

文章从评价主体、评价对象、介入时间、评价内容、公众参与、技术方法、政策制度等方面构建了包括"评价人员素质、早期介入、指标体系、评价标准、公众参与方式、工作程序完整性、法律法规、替代方案"等19项评价指标,提出了AHP-模糊综合评价法对规划环境影响评价有效性进行综合评价的方法,并以南阳石化专业园区规划环境影响评价为实证案例进行了定量分析.     

亚洲季风的多尺度变化规律及其与全球气候变化的关系

在科技部"973"计划和国家自然科学基金委的资助下,西安交通大学全球环境变化研究院程海教授带领研究团队利用中国、印度、乌兹别克斯坦等地的洞穴石笋,重建了目前全球最长的,有绝对年代控制的高分辨率亚洲季风和中亚核心区气候变化的石笋记录,深入研究了不同时间尺度上亚洲季风的变化规律、影响机制及其与全球气候变化的关系。直接验证了10万年的冰期循环是4—5个岁差周期的平均,发现了高低纬气候系统之间的"简洁"关系,进一步证实亚洲季风与太阳辐射变化在岁差尺度上没有显著的相位差,揭示了亚洲季风与西风带气候模态之间的耦合分异,研究了历史时期百到十年尺度的季风降水变化并尝试预估未来变化趋势。以上成果为全球气候变化研究提供了重要标尺,加强了对于气候系统相互作用、强迫因子及其响应机制的理解,为全球气候事件研究和模拟工作提供了重要的新线索,也为相关政府部门制定水资源的长期规划提供了科学依据。     

悬浮膜(CFM)分离技术在油田废水处理中的应用

应用微电解等技术对油田废水进行预处理,然后用悬浮膜进行分离,使其中的油、微生物和固体物与水相分离,使其达到回注用水要求。重点对CFM分离设备的结构及原理加以介绍,以期推进过滤技术的进步,提高油田废水的处理水平。     

循环半干法技术净化垃圾焚烧炉尾气

垃圾焚烧已在全国各地兴起,人们一直对其引起的大气污染问题十分关注,其中尾部烟气净化是防治大气污染的最重要环节,分析了富春环保热电股份有限公司的垃圾焚烧炉循环半干法烟气净化工艺、设计指标、运行效果。     

明胶厂剩余高钙污泥作为燃煤固硫剂的应用研究

明胶生产产业在废水处理工艺中产生大量剩余高钙污泥,采用该剩余污泥作为燃煤固硫剂,在高温管式电阻炉内进行燃烧实验,通过测定燃烧前和燃烧后样品中的硫含量确定该剩余污泥的固硫效果。通过单因素研究煤粉粒径、剩余污泥粒径和剩余污泥/煤样%等影响因素对固硫率的影响。在单因素试验的基础上通过正交设计法优选达到较高固硫率的实验条件。实验结果表明:影响固硫率的因素从大到小依次为燃烧温度>剩余污泥/煤样%>煤粉粒径>剩余污泥粒径。以剩余污泥作为固硫剂,固硫率最高的实验条件为:燃烧温度800℃,剩余污泥/煤样为3%,煤粉粒径60⁹0目,剩余污泥粒径9090目,剩余污泥粒径90¹20目。并且,当温度达到1150℃,煤粉粒径90120目。并且,当温度达到1150℃,煤粉粒径90¹20目,剩余污泥粒径为60120目,剩余污泥粒径为60⁹0目,污泥/煤样(质量比)为3%时,固硫率可达62.78%,说明在高温下该剩余污泥保持较高的固硫率。将明胶厂剩余污泥作为固硫剂是较为合适的再利用方法,可有效缓解当前该污泥大量堆积污染环境的状况。     

Decrease of NH4+-N by bacterioplankton accelerated the removal of cyanobacterial blooms in aerated aquatic ecosystem

We used aerated systems to assess the influence of the bacterioplankton community on cyanobacterial blooms in algae/post-bloom of Lake Taihu, China. Bacterioplankton community diversity was evaluated by polymerase chain reaction-denaturing gradient gel electrophoresis(PCR-DGGE) fingerprinting. Chemical analysis and nitrogen dynamic changes illustrated that NH4+-N was nitrified to NO2-N and NO3-N by bacterioplankton. Finally, NH4+-N was exhausted and NO3-N was denitrified to NO2-N, while the accumulation of NO2-N indicated that bacterioplankton with completely aerobic denitrification ability were lacking in the water samples collected from Lake Taihu. We suggested that adding completely aerobic denitrification bacteria(to denitrify NO2-N to N2)would improve the water quality. PCR-DGGE and sequencing results showed that more than 1/3 of the bacterial species were associated with the removal of nitrogen, and Acidovorax temperans was the dominant one. PCR-DGGE, variation of nitrogen, removal efciencies of chlorophyll-a and canonical correspondence analysis indicated that the bacterioplankton significantly influenced the physiological and biochemical changes of cyanobacteria. Additionally, the unweighted pair-group method with arithmetic means revealed there was no obvious harm to the microecosystem from aeration. The present study demonstrated that bacterioplankton can play crucial roles in aerated ecosystems, which could control the impact of cyanobacterial blooms in eutrophicated fresh water systems.     

Effects of physical and chemical characteristics of surface sediments in the formation of shallow lake algae-induced black bloom

Surface sediments are closely related to lake black blooms. The dissolved oxygen （DO） distribution and its penetration depth in surface sediments as well as the migration and transformation of redox sensitive elements such as Fe and S at the sediment-water interface are important factors that could influence the formation of the black bloom. In this study, dredged and undredged sediment cores with different surface properties were used to simulate black blooms in the laboratory. The Micro Profiling System was employed to explore features of the DO and ∑H2S distribution at the sediment-water interface. Physical and chemical characteristics in sediments and pore waters were also analyzed. The results showed that sediment dredging effectively suppressed the black blooms. In the undredged treatment, DO penetration depth was only 50 μm. Fe^2＋ concentrations, ∑H2S concentrations, and ∑H2S production rates were remarkably higher in surface sediments and pore waters compared to control and dredged treatments. Furthermore, depletion of DO and accumulation of Fe^2＋ and ∑H2S in surface sediments and pore waters provided favorable redox environments and necessary material sources for the blooms. The study results proved that physical and chemical characteristics in surface sediments are important factors in the formation of the black bloom, and could provide scientific guidance for emergency treatment and long-term pre-control of black blooms.     

Interface-mediated synthesis of monodisperse ZnS nanoparticles with sulfate-reducing bacterium culture

We have created a new method of ZnS nanospheres synthesis. By interface-mediated precipitation method (IMPM), monodisperse ZnS nanoparticles was synthesized on the particle surface of sulfate-reducing bacterium nutritious agar culture. Sulfate-reducing bacterium (SRB) was used as a sulfide producer because of its dissimilatory sulfate reduction capability, meanwhile produced a variety of amino acids acting as templates for nanomaterials synthesis. Then zinc acetate was dispersed into nutritious agar plate. Subsequently agar plate was broken into particles bearing much external surface, which successfully mediated the synthesis of monodisperse ZnS nanoparticles. The morphology of monodisperse ZnS nanospheres and SRB were examined by scanning electron microscopy (SEM), and the microstructure was investigated by X-ray diffraction (XRD). The thermostability of ZnS nanoparticles was determined by thermo gravimetric-differential thermo gravimetric (TG-DTG). The maximum absorption wavelengh was analysed with an ultraviolet-visible spectrophotometer within a range of 199–700 nm. As a result, monodisperse ZnS nanoparticles were successfully synthesized, with an average diameter of 80 nm. Maximum absorption wavelengh was 228 nm, and heat decomposed temperature of monodisperse ZnS nanoparticles was 596°C.