3种农业废弃物处置水面溢油研究

用小麦秸秆、玉米秸秆和木屑作为吸油材料对0#柴油进行吸附研究,比较3种农业废弃物在纯油、油水样中的吸附性能及漂浮性能,并采用正交实验对影响3种农业废弃物除油率的因素条件进行了优化.结果表明:(1)小麦秸秆、木屑和玉米秸秆对柴油的吸附速率都很快,无论是在纯油中,还是在油水样中,5 min即可达到吸附饱和状态.在纯油中,小麦秸秆饱和吸油量最大,为8.54 g/g;木屑次之,为8.20 g/g;玉米秸秆饱和吸油量最小,为7.03 g/g.在油水样中,小麦秸秆饱和吸油量最大,为8.54 g/g;木屑次之,为8.08 g/g;玉米秸秆饱和吸油量最小,为7.02 g/g.(2)振荡使得小麦秸秆、木屑和玉米秸秆漂浮性能都出现明显下降,它们的漂浮率依次为小麦秸秆＞木屑＞玉米秸秆.(3)在振荡频率为0 r/min、投加量为0.9g、油膜厚度为0.55 mm的条件下,玉米秸秆和木屑粒径为830～1 700 μm、小麦秸秆粒径为500～830 μm时,除油效果最佳.     

蒲绒-芦苇机械混合复合材料的吸油性能

2010年本实验室开始生物质对柴油的吸附实验,和前人的结论一致,生物质热改性后其吸油和漂浮性能提高,但成本增加很多。受到前人复合吸油材料的启发,2012年开展了蒲绒-芦苇机械混合复合材料吸油和漂浮性能的研究,并采用正交实验对影响除油效果的因素进行优化。结果表明,蒲绒-芦苇复合材料较之芦苇吸油性能提高,且比各组分的叠加饱和吸油量还高。震荡使芦苇的漂浮率明显降低,但对蒲绒及复合材料的影响较小。正交实验结果显示,投加量0.7g,油膜厚度0.55 mm,不震荡时,蒲绒除油最佳;在相同条件下,粒径为380~500μm的芦苇除油最佳,蒲绒和该粒径的芦苇按质量比为1∶4混合成的复合材料的除油效果最佳。     

麦秆对水中扑草净的吸附性能研究

农业秸秆富含纤维素、木质素等组分,是良好的吸附材料。采用麦秆作为吸附剂,其对浮油及溶解油具有良好吸附效果。选用麦秆为吸附剂,探究其对扑草净的吸附效果。主要考察麦秆粒径、投加量、振荡频率、扑草净初始质量浓度4种因素对吸附的影响,研究麦秆对扑草净的吸附等温线和吸附动力学过程,并采用正交实验对影响吸附的因素进行优化。结果表明:(1)麦秆可有效降低废水中扑草净浓度,在振荡频率150r/min、麦秆粒径250~500μm、投加量0.500 0g、吸附300min时,扑草净初始质量浓度由5.20mg/L降至3.22mg/L,去除率为38.08%。(2)单因素吸附平衡实验表明,随麦秆粒径增加(150~4 000μm),其比表面积减小,平衡吸附量随之减小,麦秆粒径150~250μm时平衡吸附量为0.192 0 mg/g,显著大于1 700~4 000μm时的平衡吸附量(0.059 3mg/g);随麦秆投加量增加(0.100 0~1.000 0g),去除率随之提高,平衡吸附量与之相反,0.100 0g投加量时平衡吸附量为0.222 0mg/g;随着振荡频率加剧,麦秆在水中扩散增强,与扑草净碰撞几率增加,振荡频率250r/min时平衡吸附量为0.191 0mg/g;随扑草净初始质量浓度增加(1.03~6.18mg/L),平衡吸附量随之增加,初始质量浓度为6.18mg/L,平衡吸附量为0.226 0mg/g。(3)分别以Henry型、Langmuir型、Freundlich型吸附等温式进行拟合,资料表明,以Henry型吸附等温式较适宜描述该吸附过程。(4)采用伪一级动力学方程、伪二级动力学方程、Elovich经验方程、颗粒内扩散方程分析吸附动力学过程,以伪二级动力学方程较符合。(5)在振荡频率为150r/min、初始质量浓度为2.00mg/L、麦秆粒径为250~500μm、投加量为0.700 0g时,扑草净最佳去除率为47.80%。     

改性木屑对海上溢油的吸附

为提高吸油倍率降低吸水倍率,对天然松木屑进行了改性,得到了一种新的除油吸附剂。对该吸附剂的吸油吸水性能进行测定,并确定最佳条件。结果显示:改性木屑吸油效果提升显著,在纯原油中吸油倍率是天然松木屑的2.50倍;吸水倍率降低了80%;漂浮性能好;吸附2 min就能达到吸附平衡,吸附速率是原始松木屑和活性炭的15倍;粒径对改性木屑吸水吸油性能基本无影响;低温和中性条件有利于油的吸附。     

有机膨润土吸附苯胺的性能及工艺条件的优化

以钙基膨润土为原料，钠化后用溴化十六烷基三甲铵（CTMAB）进行有机改性，制得有机膨润土。在单因素吸附实验的基础上，采用L16（4^4）正交实验法对有机膨润土吸附水中苯胺的工艺条件进行了优化研究。结果表明，当矿物的粒径小于74／μm、振荡速度为150r／min、吸附液为25mL，并且以此三者为固定因素时，其优化工艺条件为有机膨润土投加量2．0g，温度40℃，pH7，吸附时间1．5h。     

生物质材料预处理餐饮废水

采用4种廉价的生物质材料（水葫芦、柚子皮、木屑、核桃壳）用于餐饮废水的预处理。通过静态烧杯实验，研究了各生物质材料预处理废水的效果及最佳处理条件。结果表明，生物质材料对废水中COD的去除率均在45％以上，油脂吸附量为4～16mg／g，最优吸附材料为水葫芦，COD去除率达65％，油脂吸附量为16mg／g；水葫芦和柚子皮的最佳处理条件为：粒径〈0．2mm，投加量为20g／L，废水pH为4，处理时间为2h，温度为20℃；木屑和核桃壳的最佳实验条件为：粒径〈0．2mm，投加量为28g／L，pH为2，处理时间为2．5h，温度为20℃。生物质对餐饮废水的预处理，为废水中大量有机物和废弃油脂的去除提供了新思路和途径。     

狭叶香蒲绒纤维对油的吸附与机理

为了解香蒲绒纤维对油的吸附性能与机理,通过静态实验,研究了吸附时间、温度、香蒲绒投加量、油浓度对狭叶香蒲绒吸附水溶液中0#柴油、菜籽油的影响。香蒲绒纤维对油的吸附大约15 min达到平衡;2种油类物质的吸附量随温度、香蒲绒投加量增加而降低,随0#柴油和菜籽油含量增加而增加。热力学分析表明,香蒲绒对油类物质的吸附过程自发而且放热;拟二级动力学模型比拟一级动力学模型对吸附动力学实验结果拟合度更高;相比Freundlich等模型,0#柴油和菜籽油的平衡吸附量与Langmuir吸附等温模型的拟合效果更好;25℃条件下,由Langmuir线性模型得到的0#柴油和菜籽油的最大吸附量Qm分别为32.15 g/g和34.60 g/g。香蒲绒纤维表面粗糙、凹凸不平,主要含有O—H、C=O、C—O等官能团,平均蜡质含量为19.86%。结果表明,香蒲绒纤维是处理含油废水廉价且效果良好的吸附剂,吸附机理以物理吸附为主。     

利用钢渣对聚驱采油废水进行深度处理

利用钢渣对模拟聚驱采油废水进行深度处理，依靠吸附作用去除水中的HPAM。考察了钢渣粒径、搅拌速度、pH以及吸附时间对HPAM去除率的影响，进行了吸附等温线和吸附热力学分析，并对钢渣进行了吸附再生实验。当搅拌速度为250r／min，pH为2～10，吸附时间为90rain，钢渣粒径为10-16目、投加量为100g／100mL时，HPAM的去除率可达到84％以上。钢渣对HPAM的吸附符合Langmuir等温式，吸附自由能变和吸附焓的结果都表明，该吸附属于物理吸附。吸附之后的钢渣可以通过600℃焚烧得到再生，再生后仍可保持良好的吸附性能。     

鸡蛋壳废料对水体中Cr(Ⅵ)的吸附特征与机理

利用鸡蛋壳废料对水中的Cr(Ⅵ)进行吸附处理,研究溶液p H、振荡时间、投加量和温度对鸡蛋壳废料吸附水体中Cr(Ⅵ)的特征和吸附机理。结果表明,在含有1 mg/L的Cr(Ⅵ)溶液的100 m L吸附体系中,鸡蛋壳废料可在30 min内完成吸附过程。溶液p H=2.5时,吸附量最大。鸡蛋壳投加量为1.0 g时,平衡吸附容量为0.0917 mg/g。利用鸡蛋壳去除水中Cr(Ⅵ)的最佳工艺参数为振荡时间30 min,初始p H为3.0,投加量2.0 g,体系温度35℃。鸡蛋壳对Cr(Ⅵ)的吸附过程用Langmiur和Freundlich方程能较好拟合,其中理论饱和吸附量在20℃、30℃和40℃时分别为0.1944、0.2034和0.2096 mg/g。吸附的焓变为8.76×10-3k J/mol,熵变为-45.96 J/(mol·K),吉布斯自由能变均为正值,变化范围是4.357~9.693 k J/mol。鸡蛋壳对Cr(Ⅵ)的吸附过程主要为物理性的单分子层和多分子层吸附。     

活性炭吸附-超临界CQ解吸附四氯乙烯的特性研究

应用Boyd理论研究了活性炭吸附水中四氯乙烯（PCE）的吸附速率以及超临界CO2萃取PCE饱和活性炭的解吸附速率。结果表明，在0．5～48．0h内，吸附速率曲线具有直线相关关系，R^2=0．9960，其吸附速率可用粒内扩散系数D．表示，Di=4．00×10^-10cm2／s；在超临界CO2解吸附过程中，在1～5min内，时间与解吸附率存在直线相关关系，R2=0．9475，其解吸附速率用粒内扩散系数Di／SF表示，Di/SF=-5．19×10^-5cm2／s，比Di大10^5倍，说明超临界流体具有优越的传输性能；用Boyd理论可粗略描述活性炭吸附-超临界C02解吸附PCE的过程。     

火力发电厂飞灰对抗生素磺胺的吸附性能

研究了吸附时间、飞灰用量、初始溶液pH和振荡频率等因素对飞灰吸附去除水溶液中磺胺的影响,并对其吸附机理进行了初步探讨。研究结果表明,飞灰用量增大有利于提高其对磺胺的吸附去除率。在25℃、振荡频率150 r/min、飞灰用量50 g/L、磺胺浓度4 mg/L条件下吸附10 min,磺胺的吸附去除率可达到92.8%。电厂飞灰对磺胺的吸附符合二级动力学模型,属于单分子层吸附。     

Fine particle removal performance of a two-stage wet electrostatic precipitator using a nonmetallic pre-charger

A novel two-stage wet electrostatic precipitator (ESP) has been developed using a carbon brush pre-charger and collection plates with a thin water film. The electrical and particle collection performance was evaluated for submicrometer particles smaller than 0.01- 0.5 micrometer in diameter by varying the voltages applied to the pre-charger and collection plates as well as the polarity of the voltage. The collection efficiency was compared with that calculated by the theoretical models. The long-term performances of the ESP with and without water films were also compared in tests using Japanese Industrial Standards dust. The experimental results show that the carbon brush pre-charger of the two-stage wet ESP had approximately 10% particle capture, while producing ozone concentrations of less than 30 ppb. The produced amounts of ozone are significantly lower than the current limits set by international agencies. The ESP also achieved a high collection rate performance, averaging 90% for ultrafine particles, as based on the particle number concentration at an average velocity of 1 m/sec corresponding to a residence time of 0.17 sec. Higher particle collection efficiency for the ESP can be achieved by increasing the voltages applied to the pre-charger and the collection plates. The decreased collection efficiency that occurred during dust loading without water films was completely avoided by forming a thin water film on the collection plates at a water flow rate of 6.5 L/min/m(2).     

无硫膨胀石墨的制备及吸油性能

通过单因子实验考察了无硫膨胀石墨制备过程中氧化剂及插层剂用量、氧化反应及插层反应时间、氧化反应及插层反应温度对无硫膨胀石墨膨胀体积的影响。通过正交实验确定了制备无硫膨胀石墨的最优条件是:石墨(g)∶浓硝酸(mL)∶30%H2O2(mL)∶乙酸酐(mL)=1∶2.25∶0.25∶0.6,在30℃条件下氧化反应60 min,加入插层剂后在60℃条件下插层反应90 min,此条件无硫膨胀石墨的膨胀体积达317 mL/g使用XPS、FT-IR、XRD和SEM对无硫膨胀石墨进行了表征并对其吸油性能和再生性能进行了研究。结果表明,所制备无硫膨胀石墨对原油和柴油的最大吸附量分别为66.3 g/g和62.7 g/g。吸附原油后的无硫膨胀石墨抽滤再生后首次再生率为49.1%,原油的回收率为64.5%。     

A multiple testing approach for hazard evaluation of complex mixtures in the aquatic environment: the use of diesel oil as a model

Traditional single species toxicity tests and multiple component laboratory-scaled microcosm assays were combined to assess the toxicological hazard of diesel oil, a model complex mixture, to a model aquatic environment. The immediate impact of diesel oil dosed on a freshwater community was studied in a model pond microcosm over 14 days: a 7-day dosage and a 7-day recovery period. A multicomponent laboratory microcosm was designed to monitor the biological effects of diesel oil (1.0 mg litre(-1)) on four components: water, sediment (soil + microbiota), plants (aquatic macrophytes and algae), and animals (zooplanktonic and zoobenthic invertebrates). To determine the sensitivity of each part of the community to diesel oil contamination and how this model community recovered when the oil dissipated, limnological, toxicological, and microbiological variables were considered. Our model revealed these significant occurrences during the spill period: first, a community production and respiration perturbation, characterized in the water column by a decrease in dissolved oxygen and redox potential and a concomitant increase in alkalinity and conductivity; second, marked changes in microbiota of sediments that included bacterial heterotrophic dominance and a high heterotrophic index (0.6), increased bacterial productivity, and the marked increases in numbers of saprophytic bacteria (10 x) and bacterial oil degraders (1000 x); and third, column water acutely toxic (100% mortality) to two model taxa: Selenastrum capricornutum and Daphnia magna. Following the simulated clean-up procedure to remove the oil slick, the recovery period of this freshwater microcosm was characterized by a return to control values. This experimental design emphasized monitoring toxicological responses in aquatic microcosm; hence, we proposed the term 'toxicosm' to describe this approach to aquatic toxicological hazard evaluation. The toxicosm as a valuable toxicological tool for screening aquatic contaminants was demonstrated using diesel oil as a model complex mixture.     

工业废渣基除磷材料的静态吸附研究

研究了高效除磷材料（EPRC）对磷素的吸附特性，考察了投加量、初始浓度、初始pH值、粒径等对EPRC吸附性能的影响，分析了不同条件下EPRC的吸附过程。结果表明，最佳投加量为3.5 g/250 mL时，去除率达91.07%，出水TP浓度为0.45 mg/L。随着粒径减小，EPRC对磷素的吸附量增大，吸附平衡时间缩短。溶液初始pH值在碱性条件下，吸附容量变大。     

有机改性成都粘土预处理垃圾渗滤液

以成都粘土为原料,十六烷基三甲基溴化铵(HDTMA)为改性剂制备有机改性土,并将其应用于垃圾渗滤液的预处理。采用单因素静态吸附实验,以粘土对垃圾渗滤液COD和氨氮的去除率作为考查指标,初步探究有机改性土预处理垃圾渗滤液的适宜条件;并对有机改性粘土及原土进行性能表征,初步分析其吸附机理。研究结果表明,有机土的处理效果明显优于原土,处理效果上比原土提高了1.6~2.3倍;有机土预处理垃圾渗滤液适宜条件为:投加量120 g/L、搅拌速度200 r/min、搅拌时间50 min、pH=7、静置时间为6 h。     

基于改性凹凸棒土的强化混凝处理高藻低浊原水工艺

针对水厂低浊高藻水的处理难题,研究了改性凹凸棒土(改性凹土)联合聚合氯化铝(PAC)强化混凝的除藻除浊效果。设计实验原水条件为叶绿素a(chl-a)浓度为98.58~110.35μg/L,浊度(5.6±0.5)NTU。考察了PAC和改性凹土的复配投加量、混凝沉淀时间、pH、投加顺序、搅拌速率等工艺参数对Chl-a和浊度耦合去除效果的影响。结果表明,"PAC+改性凹土"对Chl-a和浊度的去除效果明显优于单投PAC的效果。当PAC投药量12 mg/L,改性凹土投药量10 mg/L,沉淀时间20 min时,对Chl-a和浊度的去除率可分别达到92.5%和89.2%,可至少减少40%的PAC投量,且形成的矾花密实,沉降速度快,去除效率高。最适pH范围为7~8。投加顺序应为先投加改性凹土,混合搅拌转数宜慢速,可控制为50 r/min。     

改性凹凸棒黏土脱除120~#溶剂油硫化物的研究

以甘肃临泽产凹凸棒黏土(以下简称凹土)为原料制备吸附剂,对120#溶剂油进行脱硫实验,同时采用脱硫率、X射线衍射(XRD)和红外光谱(IR)对吸附剂进行了表征.结果表明:(1)以临泽凹土为原料制备吸附剂的最佳条件为焙烧时间3.0h、焙烧温度350℃、未精制吸附剂质量和溶剂油体积的比值1∶5 g/mL、脱硫时间75 min.按此最佳条件制备吸附剂,可将120#溶剂油含硫量由424 μg/g降至213 μg/g.脱硫率可以达到49.8％.(2)经过XRD及IR分析,120 #溶剂油中的硫被脱除后在吸附剂中以硫醚和CaS的形式存在.用浸渍法制备的吸附剂达到了一定的脱硫效果.     

Characterization of top phase oil obtained from co-pyrolysis of sewage sludge and poplar sawdust

To research the impact of adding sawdust on top phase oil, a sewage sludge and poplar sawdust co-pyrolysis experiment was performed in a fixed bed. Gas chromatography (GC)/mass spectrometry (MS) was used to analyze the component distribution of top phase oil. Higher heating value, viscosity, water content, and pH of the top phase oil product were determined. The highest top phase oil yield (5.13 wt%) was obtained from the mixture containing 15 % poplar sawdust, while the highest oil yield (16.51 wt%) was obtained from 20 % poplar sawdust. Top phase oil collected from the 15 % mixture also has the largest amount of aliphatics and the highest higher heating value (28.6 MJ/kg). Possible reaction pathways were proposed to explain the increase in the types of phenols present in the top phase oil as the proportion of poplar sawdust used in the mixture increased. It can be concluded that synergetic reactions occurred during co-pyrolysis of sewage sludge and poplar sawdust. The results indicate that the high ash content of the sewage sludge may be responsible for the characteristic change in the top phase oil obtained from the mixtures containing different proportions of sewage sludge and poplar sawdust. Consequently, co-pyrolysis of the mixture containing 15 % poplar sawdust can increase the yield and the higher heating value of top phase oil.