活性炭深度处理工艺用于地下回灌的水质研究

以北京高碑店污水处理厂二级生化出水为对象,研究了用于地下回灌的活性炭三级处理工艺.活性炭可有效降低DOC,UV-254和COD,部分去除可吸附有机卤化物(AOX).再经过土壤含水层处理,约90%的可吸附有机溴化物(AOBr)可被去除.Ames试验结果显示活性炭工艺可有效降低二级生化出水中的致突物.GC/MS分析表明,活性炭吸附可降低有机物含量,再经土壤含水层处理,大部分有机物及优先控制的污染物可被去除.      

炼铁工序减污降碳协同增效技术评估方法研究

为推广减污降碳协同控制技术,以炼铁工序为研究对象,从协同度、成本收益和环境影响3个维度评价炼铁工序源头、过程节能技术、末端治理技术和低碳技术的协同控制效益。从污染物和碳排放协同度分析来看,源头、过程节能技术能有效推动炼铁工序污染物和碳排放的协同减排,而末端控制技术对污染物和温室气体的减排不具有协同性。绿氢冶炼技术和熔剂性球团制备技术污碳减排协同度较高,此外高炉喷吹焦炉煤气技术、高炉煤气回收技术和高炉热风炉双预热能协同减少VOCs和碳排放。在当前我国碳交易价格条件下,从成本收益分析来看节能技术和污染物末端治理技术具有可推广性。随着碳交易价格的上涨,绿氢冶炼和碳捕集（CCS）技术减排成本呈下降趋势。绿氢冶炼技术、污染物末端治理技术最能有效地减少环境影响,其他节能技术也能相应减少环境影响,而现有条件下CCS技术的实施会增加对环境的影响。综合污染物和温室气体协同减排的协同度、经济效益和环境效益评估,炼铁工序中源头防治和节能技术可作为我国现阶段减污降碳协同增效技术进行推广,随着未来碳交易价格的增长和能源的转型,绿氢冶炼技术和CCS技术具有较大应用前景。

     

几种吸附材料在含油废水处理中的应用

含油废水的来源广泛、成分复杂且对环境危害严重,吸附法是处理含油废水常用的方法,吸附剂性能的优劣对处理含油废水有至关重要的影响。介绍几种典型的吸附材料包括活性炭、高吸油树脂、粉煤灰和膨润土;活性炭是处理含油废水最常用的吸附材料,高吸油树脂则是新型的有机吸附剂,粉煤灰来源广且价格低廉,膨润土资源丰富;几种吸附材料各有优点缺点,其特性、吸附机理、在含油废水处理中的应用也不尽相同,通过比较分析,提出了未来用于含油废水处理吸附材料的发展趋势。     

介质阻挡放电等离子体分解CO2

温室效应导致全球变暖已成为全球性的环境问题之一.采用放电等离子体法转化CO2,不仅可消纳温室气体,缓解全球变暖的巨大影响,还可制备化工原料CO和O2.充分利用了C1(含1个碳原子的化合物分子)资源,对高频同轴式介质阻挡放电等离子体分解纯CO2进行了研究.结果发现:在采用不锈钢光滑内电极,放电间隙为2.0mm,注入功率为180W,气体流量为170mL/min的条件下,CO2转化率可达18.2%,CO和O2产率分别为10.1%和4.7%;增大注入功率,减小气体流量、选择合适的放电间隙和内电极形式,均有利于提高CO2转化率,获得更多的CO和O2.     

海藻酸钠包埋活性炭与细菌的条件优化及其对Pb2+的吸附特征研究

利用海藻酸钠固定化包埋活性炭与多黏类芽孢杆菌GA1,通过正交试验研究海藻酸钠溶液浓度、包炭量及包菌量吸附Pb2+的最佳配比,并研究了这种新型的固定化小球对Pb2+的吸附特征.结果表明,固定化活性炭与多黏类芽孢杆菌GA1小球最佳制备条件为海藻酸钠质量分数2.5%、包炭量1:20和包菌量1:2,在该制备条件下吸附率达到93.74%.固定化小球的最佳吸附条件为pH5、温度30℃和Pb2+初始浓度300mg·L-1,活性炭与GA1经固定后对pH、温度和Pb2+初始浓度适应范围扩大.吸附平衡曲线表明,对Pb2+的吸附在30min内是一个快速的过程,在2h时基本趋于平衡,且平衡曲线能较好地用Langmuir模型和Freundlich模型来描述,其吸附过程主要为单分子层吸附,最大单分子层吸附量为370.37mg·g-1.解吸结果表明固定化小球能有效地循环利用.     

磷酸活化纺织固体废弃物制备活性炭及表征

以纺织固体废弃物为原料,磷酸为活化剂,采用一步活化法制备活性炭。采用正交实验研究了磷酸浓度、浸渍时间、活化温度和活化时间对活性炭吸附性能的影响,得到最佳工艺条件,借助氮吸附等温线、BET方程、BJH方程、SEM和FTIR分析了活性炭孔结构和表面化学性质。结果表明:最佳工艺条件为磷酸浓度40%(质量分数)、浸渍时间24h、活化温度500℃、活化时间30min。最佳条件下活性炭碘值为967mg/g,亚甲基蓝值为112mL/g,BET比表面积为1107.51m2/g,总孔容积为1.239cm3/g,中孔容积为1.024cm3/g,中孔占82.65%。活性炭表面具有羟基、羰基、内酯基和多种含磷官能团。     

Potential for carbon sequestration in Canadian forests and agroecosystems

The potential for carbon (C) sequestration was examined in selectedCanadian forest settings and prairie agroecosystems under severalmanagement scenarios. A simple C budget model was developed toquantitatively examine C sequestration potential in living biomass of forestecosystems, in associated forest-product C pools, and in displaced fossil-fuelC. A review of previous studies was conducted to examine C sequestrationpotential in prairie agroecosystems. In the forest settings examined, ourwork suggests that substantial C sequestration opportunities can be realizedin the short term through the establishment of protected forest-C reserves.Where stands can be effectively protected from natural disturbance, peaklevels of biomass C storage can exceed that under alternative managementstrategies for 200 years or more. In settings where it is not feasible tomaintain protected forest-C reserves, C sequestration opportunities can berealized through maximum sustained yield management with harvestedbiomass put towards the displacement of fossil fuels. Because there is afinite capacity for C storage in protected forest-C reserves, harvesting forestbiomass and using it to displace the use of fossil fuels, either directlythrough the production of biofuels or indirectly through the production oflong-lived forest products that displace the use of energy-intensive materialssuch as steel or concrete, can provide the greatest opportunity to mitigategreenhouse gas emissions in the long term. In Canadian prairieagroecosystems, modest C sequestration can be realized while enhancingsoil fertility and improving the efficiency of crop production. This can bedone in situations where soil organic C can be enhanced without relianceupon ongoing inputs of nitrogen fertilizer, or where the use of fossil fuelsin agriculture can be reduced. More substantial C offsets can be generatedthrough the production of dedicated energy crops to displace the use offossil fuels. Where afforestation or reconstruction of native prairieecosystems on previously cultivated land is possible, this represents thegreatest opportunity to sequester C on a per unit-area basis. However,these last two strategies involve the removal of land from crop production,and so they are not applicable on as wide a scale as some other Csequestration options which only involve modifications to currentagricultural practices.     

Brazil's Electric Power Choices and Their Corresponding Carbon Emissions Implications

This study analyzes the options for meeting power demand in the Brazilianpower sector through the year 2015. Three policy cases are constructedto test economic and environmental policy measures against a baseline:advanced technologies scenario, environmental control scenario and carbon(C) elimination scenario. Least-cost modeling simulated these scenarios throughchanges in emissions fees and caps, costs for advanced technologies,demand side efficiency, and clean energy supplies. Results show that, in theabsence of alternative policies, new additions to Brazil's electric powersector will shift rapidly from hydroelectricity to combined-cycle natural gasplants. When the cost of environmental impacts are incorporated in theprice of power, the least-cost mix of electric power generation technologycould change in other ways. In all scenarios, energy efficiency andcogeneration play an important role in the least-cost power solution. Savingelectricity through increased efficiency offsets the needs for new supply andhas enormous potential in Brazil's industrial sector. Efficiency also reducesthe environmental burden associated with electricity production andtransmission, without compromising the quality of the services demandedby end users. Interesting enough, carbon dioxide (CO₂) emissions will remainrelatively low under almost every conceivable scenario.     

应用δ~(13)C值探讨土壤中有机碳的迁移规律

C3 植物与C4 植物具明显的δ13C值差异 ,利用这种特性 ,选取荔波茂兰喀斯特森林边缘处这个C3植物—C4 植物转换生长的地点 ,分别采集森林与农田各三个剖面的土壤样品 ,根据测定其土壤总有机碳、不同粒径及不同比重组分的δ13C值间的相互关系来推导土壤有机碳的若干迁移规律     

溶剂萃取法从活性炭滤泥中回收增塑剂

本工作用溶剂萃取法从炭泥中回收增塑剂,通过小试筛选最佳的溶剂,确定工艺条件;在年产百万吨级的工业装置上进行生产性试验,结果为抽出率达炭泥量的50％以上,溶剂回收率达90％以上,回收的增塑剂产品达到部标二级品标准.