微波紫外耦合辐射降解间硝基苯磺酸钠及活性炭再生

针对活性炭吸附法处理污水所面临的吸附剂物耗大及其所形成的危险废弃物处置难题,采用微波紫外耦合辐射技术对活性炭无害化再生。以活性炭吸附电镀废水中的间硝基苯磺酸钠(3-NBSA)为研究对象,考察了p H对活性炭吸附3-NBSA效果的影响,研究了活性炭的吸附动力学和吸附等温线,最后探讨了微波功率、微波辐照时间、空气流量及再生次数对活性炭再生效果和再生损耗率的影响。实验结果表明,p H在2~8范围内对活性炭吸附效果影响不大,活性炭吸附动力学符合准二级动力学模型,等温吸附特性可用Freundlich等温方程式来描述。活性炭再生实验的最佳工艺条件:微波功率为500W,微波辐照时间为10 min,空气流量为0.024 m3/h。最佳工艺条件下活性炭的再生率达到99.62%,且连续再生5次后仍能达到90.02%。实验表明,在微波紫外耦合辐射作用下比只在微波作用下,活性炭的再生效果和3-NBSA的降解效果更好。     

粉煤灰协同微波-Fenton氧化法处理活性艳蓝KN-R染料废水

以粉煤灰联合微波-Fenton氧化工艺处理活性艳蓝KN-R生产废水,考察了粉煤灰投加量及吸附时间对处理效果的影响,并通过正交实验对微波-Fenton工艺参数进行了优化。实验结果表明,粉煤灰絮凝吸附与微波-Fenton氧化具有协同效应;在粉煤灰投加量为40 g/L,搅拌吸附时间为20 min,滤液pH值为4,Fe2＋和H2O2投加量分别为3.6 mmol/L和0.15 mol/L,微波功率为200 W,辐射反应时间为4 min的优化条件下,染料废水的处理效果最好,COD和色度的去除率分别达到90.90%和99.98%。     

改性氧化铝微波诱导催化氧化处理高浓度苯酚废水的研究

采用微波诱导催化氧化技术，以改性氧化铝为催化剂，对高浓度模拟苯酚废水进行氧化处理。考察了微波功率、催化剂投加量、H202投加量、废水pH值和微波反应时间等因素对苯酚去除效果的影响。实验结果表明，处理30mL质量浓度为1 100mg/L的苯酚模拟废水，在微波功率500W，催化剂加入量1 g(液固比30∶1)，30％双氧水...     

活性炭协同Fe~(2+)催化H_2O_2氧化处理染料废水及其表面附着污染物对催化活性的影响

采用动态连续处理装置研究颗粒活性炭(GAC)催化H_2O_2氧化活性红X-3B染料(RRX-3B)的效能以及GAC表面吸附污染物对催化性能的影响,考察GAC与Fe~(2+)协同催化作用。研究结果表明:RRX-3B的处理效果随着流速的增加而逐渐降低;新GAC/H_2O_2体系降解效果优于单独GAC吸附与单独H_2O_2氧化,GAC重复使用存在部分失活现象使其脱色率和COD去除率下降,且表面预先吸附污染物的GAC在重复使用过程中下降更为明显;固定H_2O_2投加量为5 mmol·L~(-1),按n(Fe~(2+)):n(H_2O_2)为1:20投加Fe~(2+),GAC与Fe~(2+)联合体系能持续有效使RRX-3B氧化脱色,重复使用4次后脱色率仍可达99.65%,GAC和Fe~(2+)之间存在协同催化H_2O_2降解RRX-3B的作用。GAC表面附着的Fe~(2+)能够加强催化作用,且有效延长其使用寿命。     

超声前处理强化活性炭吸附活性艳红X-3B染料废水

探究了超声前处理活性艳红X-3B染料废水强化活性炭吸附降解性能及不同超声参数的影响规律,包括超声功率和超声时间。研究结果表明,超声前处理活性艳红X-3B染料废水可通过空化效应使有机大分子裂解为小分子易于被活性炭吸附,同时可强化其到活性炭微孔中传输,提高了活性炭吸附降解性能,最佳超声功率为320 W。浓度越高,所需超声时间越长,当超声达到一定时间后,继续超声不会影响染料分子的吸附。超声前处理虽然不会改变吸附平衡时间,但可有效增加活性炭处理活性艳红X-3B染料废水的饱和吸附量。     

微波—Cu/Fe双金属催化剂—过氧化氢工艺催化降解甲基橙废水的研究

采用超声浸渍法制备了具有较高催化活性的Cu/Fe双金属催化剂。采用微波—Cu/Fe双金属催化剂—过氧化氢工艺处理甲基橙废水,并研究了相关影响因素。结果表明,Cu/Fe双金属催化剂的Cu和Fe具有协同催化效应,可大大提高甲基橙废水的降解率。在Cu/Fe双金属催化剂投加量10g/L、过氧化氢(质量分数为30%)投加体积1.0mL、微波功率500 W、辐照时间5min的最优化条件下,50mL质量浓度为100mg/L的甲基橙废水降解率可达98.94%。     

MnO_2/Al_2O_3吸附草甘膦及微波紫外耦合降解再生工艺

以掺混煅烧法制备Mn O2/Al2O3,并对草甘膦进行吸附,将吸附态草甘膦置于微波紫外耦合系统中进行降解和再生。研究并给出了Mn O2/Al2O3的最佳制备条件、最佳吸附条件和微波紫外耦合降解再生的最佳工艺参数。Mn O2/Al2O3最佳制备条件为Mn O2质量分数15%,煅烧温度500℃,煅烧时间2 h。在常温下,Mn O2/Al2O3对草甘膦的最大吸附量为75 mg/g。微波紫外耦合系统最佳工艺参数为功率500 W,时间25 min,空气量0.06 m3/h。在此操作条件下,Mn O2/Al2O3的再生率达到85%,并且可以多次再生利用,草甘膦最终降解产物为二氧化碳、氮氧化物、磷酸和水,矿化率为65%。     

微波耦合氯化铁调理对活性污泥脱水性能及热值的影响

为实现活性污泥高效脱水和资源化利用,研究了微波耦合氯化铁调理活性污泥。主要考察微波耦合氯化铁对活性污泥脱水性能和热值的影响。微波辐射能够改善活性污泥的脱水性能,优化参数为功率700 W、时间100 s。微波耦合氯化铁调理进一步增强了活性污泥的脱水性能,先投加氯化铁后微波辐射的调理(氯化铁+微波)效果优于先微波辐射后投加氯化铁的调理(微波+氯化铁)效果,脱水效果的改善得益于活性污泥絮体的增大以及EPS的减少。微波调理后的活性污泥(干基)热值随着微波辐射时间的增长逐渐降低,而微波耦合氯化铁调理后的活性污泥(干基)热值随着氯化铁投加量的增加先增加后减少。     

微波强化内电解处理活性艳红染料废水

提出了一种微波强化内电解处理染料废水的新方法,结果表明:微波不仅可以再生炭铁混合物,而且可以氧化分解活性炭吸附的染料;铁屑不仅与活性炭构成内电解作用,同时还可以促进微波再生活性炭;微波作用多次后炭铁混合物对废水的去除率仍能保持色度去除率99%、COD去除率64%;同时探讨了微波作用时间、微波作用次数、铁屑粒径、炭铁比例和pH值等因素对废水去除率的影响,并初步探讨了其反应机理。     

青霉菌对印染废水吸附脱色及深度处理的研究

利用青霉菌P 1(Penicilliumsp )对 2种染浴废水中的染料进行吸附去除 ,研究结果表明 ,吸附处理 3h ,黑色和红色染浴废水色度基本被去除 ,去除率分别达 98 0 %和 74 5 % ,但去色处理后废水的CODCr值仍偏高。对去除色度的废水进一步用活性污泥进行深度处理 ,黑色和红色废水的CODCr去除率分别为 75 9%和 89 7%。青霉菌菌丝通过吸附作用从废水中抽提出的染料分子在有染料降解细菌L 1和L 2的降解池中脱色降解 ,菌丝吸附脱色能力得到再生。     

微波辐射回用活性炭对水中亚甲基蓝和Cd~(2+)去除效果的研究

考察了微波-活性炭联合处理技术对模拟染料废水中亚甲基蓝和Cd2+的去除效果。对于100 mL浓度为1 000 mg/L的亚甲基蓝溶液、活性炭用量为10 g时,新活性炭对亚甲基蓝的去除率为99.99%;采用700 W微波对吸附亚甲基蓝的活性炭辐射10 min进行再生并回用,经微波辐射再生10次后活性炭对亚甲基蓝的去除率为99.68%,未经微波作用反复使用10次的活性炭对亚甲基蓝的去除率为85.41%。结果表明:微波处理有效地减缓了活性炭吸附能力的下降速率,实现了活性炭再生和反复使用。在吸附过程中,Cd2+使活性炭对亚甲基蓝的吸附能力略有下降,而共存的亚甲基蓝则促进了活性炭对Cd2+的吸附,对新炭和再生后活性炭物理化学特性的表征证明了活性炭对亚甲基蓝的吸附为物理吸附,对Cd2+的吸附为化学吸附。     

微波辐射回用活性炭对水中亚甲基蓝和Cd2＋去除效果的研究

考察了微波-活性炭联合处理技术对模拟染料废水中亚甲基蓝和Cd2＋的去除效果。对于100 mL浓度为1 000 mg/L的亚甲基蓝溶液、活性炭用量为10 g时,新活性炭对亚甲基蓝的去除率为99.99%;采用700 W微波对吸附亚甲基蓝的活性炭辐射10 min进行再生并回用,经微波辐射再生10次后活性炭对亚甲基蓝的去除率为99.68%,未经微波作用反复使用10次的活性炭对亚甲基蓝的去除率为85.41%。结果表明：微波处理有效地减缓了活性炭吸附能力的下降速率,实现了活性炭再生和反复使用。在吸附过程中,Cd2＋使活性炭对亚甲基蓝的吸附能力略有下降,而共存的亚甲基蓝则促进了活性炭对Cd2＋的吸附,对新炭和再生后活性炭物理化学特性的表征证明了活性炭对亚甲基蓝的吸附为物理吸附,对Cd2＋的吸附为化学吸附。     

Microwave Process for Volatile Organic Compound Abatement

ABSTRACT

The CHA Corporation has completed the U.S. Air Force Phase II Small Business Innovation Research program to investigate the feasibility of using a novel microwave-based process for the removal and destruction of volatile organic compounds (VOCs) in effluents from noncombustion sources, such as paint booth ventilation streams. Removal of solvents by adsorption, followed by the regeneration of saturated granular activated carbon (GAC) by microwave energy, was achieved in a single fixed-bed reactor. Microwave regeneration of the fixed-bed-saturated carbon restored the original GAC adsorption capacity. After 20 adsorption/regeneration cycles, the adsorption capacity dropped from 13.5 g methyl ethyl ketone (MEK)/100 g GAC to 12.5 g MEK/100 g GAC. During microwave regeneration of the GAC fixed bed, the concentrated desorbed paint solvent was oxidized by passing the solvent mixture through a fixed bed of an oxidation catalyst mixed with silicon carbide in a microwave reactor. A 98% oxidation efficiency was consistently achieved from the oxidation of VOCs in the microwave catalytic reactor.     

核桃壳粉对水溶液中Pb2＋的吸附

实验通过间歇吸附方式研究了核桃壳粉对水溶液中Pb^2＋的吸附特性，探讨了核桃壳粉粒径及用量、溶液pH、Pb^2＋初始浓度等参数对吸附的影响，并讨论了吸附过程的热力学和动力学特征。结果表明，核桃壳粉对Pb^2＋吸附的最佳pH为5．0，去除率随吸附剂粒径的减小、用量的增加、Pb^2＋初始浓度的减小而增加。优化实验条件下，0～0．3mm15g／L的吸附剂在298K时，对pH=5的50mL50mg／LPb^2＋溶液的去除率达96．98％。核桃壳粉对Pb^2＋的吸附等温线符合Sips模型，在283、293和303K的最大吸附量分别为18．25、18．27和20．94mg／g。吸附过程是放热的、混乱度减小的自发过程，且符合准二级动力学模型。吸附速率常数随温度升高而减小，在293和303K时分别在90和120min基本达到平衡。结合FTIR和SEM手段发现核桃壳对Pb^2＋的吸附以物理吸附为主，同时包括离子交换、螯合等化学吸附以及颗粒内扩散步骤，是一个复杂的过程。     

Microwave process for volatile organic compound abatement

The CHA Corporation has completed the U.S. Air Force Phase II Small Business Innovation Research program to investigate the feasibility of using a novel microwave-based process for the removal and destruction of volatile organic compounds (VOCs) in effluents from noncombustion sources, such as paint booth ventilation streams. Removal of solvents by adsorption, followed by the regeneration of saturated granular activated carbon (GAC) by microwave energy, was achieved in a single fixed-bed reactor. Microwave regeneration of the fixed-bed-saturated carbon restored the original GAC adsorption capacity. After 20 adsorption/regeneration cycles, the adsorption capacity dropped from 13.5 g methyl ethyl ketone (MEK)/100 g GAC to 12.5 g MEK/100 g GAC. During microwave regeneration of the GAC fixed bed, the concentrated desorbed paint solvent was oxidized by passing the solvent mixture through a fixed bed of an oxidation catalyst mixed with silicon carbide in a microwave reactor. A 98% oxidation efficiency was consistently achieved from the oxidation of VOCs in the microwave catalytic reactor.     

满江红干体对锌离子的生物吸附

以满江红干体为生物吸附剂，研究了不同条件下对废水中Zn²⁺的净化作用。结果表明，满江红干体对Zn²⁺的吸附是一个快速的过程，前5 min的吸附量达到最大吸附量的62.9%，30 min达到吸附平衡；初始pH值对Zn²⁺的吸附有显著的影响，最适pH值为6；随着干体量的增加，吸附率逐渐提高而吸附量则降低；随着Zn²⁺初始浓度的增加，吸附率逐渐降低而吸附量则提高。满江红干体对Zn²⁺的吸附符合Langmuir吸附等温线方程，最大吸附容量达57.5 mg/g。5次吸附解吸循环实验数据表明，重复次数和再生处理对满江红干体的吸附能力没有产生显著影响。因此，满江红干体在处理含Zn²⁺废水中的重复使用是可行的。     

改性玉米秸秆吸附Cu2+的动力学和热力学

本研究用ZnCl2作为活化剂,使用功率640 W的微波照射4 min的方法制备改性玉米秸秆。考察投加量、pH、吸附时间对吸附性能的影响,并对等温吸附特征、吸附动力学和热力学进行了系统研究。结果表明:投加量为0.2 g,pH为6,改性玉米秸秆对Cu2+具有很好的吸附效果,吸附在8 h后达到平衡。该吸附过程符合Langmuir及Freundlich等温吸附模型和准二级动力学方程,其反应的吉布斯自由能△G<0,为自发反应过程。     

磷酸活化-微波热解改性污泥对镉的吸附性能

以城市污水处理厂剩余污泥为原料,利用磷酸活化-微波热解制取改性污泥。以此污泥作为吸附剂,对含Cd2+废水进行了吸附实验研究。考察了溶液反应时间、Cd2+浓度、pH值和吸附剂用量对镉吸附去除效果的影响;利用等温吸附实验作出吸附等温线,并考察了改性污泥吸附剂吸附Cd2+的动力学方程。实验结果表明,改性污泥对Cd2+有良好的吸附性能,吸附最佳pH值为6.0,吸附较好地符合一级动力学吸附模型和Langmuir-Freundlich等温吸附方程,吸附为物理吸附,吸附反应发生12 h后达到吸附平衡。     

Diagnosis of dissolved organic matter removal by GAC treatment in biologically treated papermill effluents using advanced organic characterisation techniques

Granular activated carbon (GAC) exhaustion rates on pulp and paper effluent from South East Australia were found to be a factor of three higher (3.62 cf. 1.47 kg m⁻³) on Kraft mills compared to mills using Thermomechanical pulping supplemented by Recycled Fibre (TMP/RCF). Biological waste treatment at both mills resulted in a final effluent COD of 240 mg L⁻¹. The dissolved organic carbon (DOC) was only 1.2 times higher in the Kraft effluent (70 vs. 58 mg L⁻¹), however, GAC treatment of Kraft and TMP/RCF effluent was largely different on the DOC persisted after biological treatment. The molecular mass (636 vs. 534 g mol⁻¹) and aromaticity (5.35 vs. 4.67 L mg⁻¹ m⁻¹) of humic substances (HS) were slightly higher in the Kraft effluent. The HS aromaticity was decreased by a factor of 1.0 L mg⁻¹ m⁻¹ in both Kraft and TMP/RCF effluent. The molecular mass of the Kraft effluent increased by 50 g mol⁻¹ while the molecular mass of the TMP/RCF effluent was essentially unchanged after GAC treatment; the DOC removal efficiency of the GAC on Kraft effluent was biased towards the low molecular weight humic compounds. The rapid adsorption of this fraction, coupled with the slightly higher aromaticity of the humic components resulted in early breakthrough on the Kraft effluent. Fluorescence excitation-emission matrix analysis of the each GAC treated effluent indicated that the refractory components were higher molecular weight humics on the Kraft effluent and protein-like compounds on the TMP/RCF effluent. Although the GAC exhaustion rates are too high for an effective DOC removal option for biologically treated pulp and paper mill effluents, the study indicates that advanced organic characterisation techniques can be used to diagnose GAC performance on complex effluents with comparable bulk DOC and COD loads.     

Microwave-induced nanoscale zero-valent iron degradation of perchloroethylene and pentachlorophenol

Microwave (MW) is applied to enhance perchloroethylene (PCE) or pentachlorophenol (PCP) removal using zero-valent iron (ZVI; Fe⁰) as the dielectric medium. ZVI has a much higher dielectric loss factor (39.5) than other media; it is capable of absorbing MW radiation rapidly to speed up the release of electrons, leading to rises of the ZVI particle surface temperature. If the MW power is continued, excessive electricity will accumulated inside ZVI particles, resulting in sparks. The results show that during the initial 5 sec (700 W), the linear aliphatic PCE has a faster decomposing rate than the ringed PCP (82.0% vs. 4.8%) because less energy is required for decomposing the linear-chlorine bond (90 kcal mol^?1) than ring-chlorine bonds (95 kcal mol^?1). Later, the removal rate for either PCE or PCP remains the same when the exposure time is between 5 and 60 sec. Without MW irradiation, linear PCE molecules have larger surface area to contact ZVI, and hence they have better removal efficiencies than PCP molecules. Using Fe⁰ as a microwave dielectric medium to treat PCE or PCP is a new and worthwhile treatment technology; it is environmentally friendly, and its use will eliminate the secondary pollution.

Implications Nanoscale iron particles are characterized by high surface-area-to-volume ratios, high specific surface area, and high surface reactivity. With a much higher dielectric loss factor, it is capable of absorbing MW radiation rapidly to speed up the release of electrons, leading to rise in temperature. The time needed to achieve a satisfactory treatment is also reduced, leading to significant saving of energy consumption to make this method cost-effective and also environmentally friendly for the industry to pursuit sustainable development.