钻井废液的O_3/H_2O_2深度氧化处理研究

针对钻井废液COD高,成分复杂,难降解的特点,对经过破胶分离后的废水进行O3预氧化-中间混凝-O3/H2O2深度氧化处理工艺,考察了处理过程中pH值、O3与H2O2的加量、反应时间等。结果表明,当体系pH值为12,O3流量0.2m3/h,H2O2的加量700mg/L,反应时间50min时,原水COD由1462mg/L降至142mg/L,去除率高达90.28%。     

Evaluation of multiple reactions in dilute benzoyl peroxide concentrations with additives using calorimetric technology

Benzoyl peroxide (BPO) is a typical organic peroxide widely used in food processing, particularly flour bleaching. Due to the unstable nature of the oxygen-oxygen bond in BPO, it readily reacts under even mid-low-temperature conditions. Lower concentrations of BPO are also potentially explosive, even when combined with acid or alkaline additives. Given the history of both potential and documented industrial accidents, this study investigates the thermal stability of various BPO concentrations when mixed with acid or alkaline solutions. In addition, differential and integral kinetic models were applied to verify that the apparent activation energy data from the differential scanning calorimetry experiments were valid. The results of autocatalysis reactions and nth-order reaction simulations presented characteristics consistent with the experimental findings. The findings in this paper can be used as a reference for BPO products that are mediated with either an acid or an alkaline solution during production, storage, transportation, or use.     

Review of hydrogen safety during storage,transmission, and applications processes

Hydrogen is considered an excellent clean fuel with potential applications in several fields. There are serious safety concerns associated with the hydrogen process. These concerns need to be thoroughly understood and addressed to ensure its safe operation. To better understand the safety challenges of hydrogen use, application, and process, it is essential to undertake a detailed risk analysis. This can be achieved by performing detailed consequence modellings and assessing risk using the computational fluid dynamics (CFD) approach. This study comprehensively reviews and analyses safety challenges related to hydrogen, focusing on hydrogen storage, transmission, and application processes. Range of release and dispersion scenarios are investigated to analyse associated hazards. Approaches to quantitative risk assessment are also briefly discussed.     

Quantified risk assessment on life and property loss from road collision vehicle fires with hydrogen-fueled tank

Hydrogen fuel cell vehicles pose hazards different from conventional vehicles. This paper performs a risk assessment on road collision vehicle fires with hydrogen-fueled tank of 70 MPa. The high voltage battery fire caused by road collision can lead to onboard hydrogen release or explosion. Events progressions are analyzed and typical hydrogen consequences are evaluated quantitatively, including hydrogen jet fires and tank catastrophic rupture. Perimeters around the accident scene are proposed for the safety of general public and first responders, respectively. Risks of fatalities, injuries, and damages are all quantified in financial terms to make it possible to combine and compare.     

Sulfate reducing bacterial community and in situ activity in mature fine tailings analyzed by real time qPCR and microsensor

Sulfate reducing bacteria(SRB) play significant roles in anaerobic environments in oil sands mature fine tailings(MFTs). Hydrogen sulfide(H2S) is produced during the biological sulfate reduction process. The production of toxic H_2S is one of the concerns because it may hinder the landscape remediation efficiency of oil sands tailing ponds. In present study, the in situ activity and the community structure of SRB in MFT and gypsum amended MFT in two settling columns were investigated. Combined techniques of H_2S microsensor and dissimilatory sulfite reductase β-subunit(dsrB) genes-based real time quantitative polymerase chain reaction(qPCR) were applied to detect the in situ H_2S and the abundance of SRB. A higher diversity of SRB and more H_2S were observed in gypsum amended MFT than that in MFT, indicating a higher sulfate reduction activity in gypsum amended MFT; in addition, the activity of SRB varied as depth in both MFT and gypsum amended MFT: the deeper the more H_2S produced. Long-term plans for tailings management can be assessed more wisely with the information provided in this study.     

Fe2+-H2O2法处理DSD酸生产氧化母液的研究

为改善DSD酸氧化母液的可生化降解性,将废液先用有机絮凝剂TS-1(一种季胺盐)处理,TS-1的投加量为3g/L,其后用Fe²⁺-H₂O₂法氧化,Fe²⁺和H₂O₂的量分别为150mg/L,7g/L,废液COD和色度的去除率分别可达64%和62%。经处理后的废水,其BOD₅/COD≈0.3,可以认为已达到生化处理的要求。当H₂O₂的投量为2g/L,经Fe²⁺-H₂O₂氧化处理后的废液,再用FeCl₃进行两级混凝处理(FeCl₃的投加量分别为5g/L和2g/L),则COD和色度的去除率可达90%和95%。     

过氧化钙降解有机污染物研究进展

CaO₂具有很好的稳定性,可在水和土壤中逐步分解生成H₂O₂成为氧化反应的氧化剂,已作为H₂O₂的替代物用于环保领域的研究中。介绍了CaO₂的作用机理,综述了CaO₂用于处理含卤代物、染料、抗生素、苯系物等废水的研究进展,以及CaO₂用于治理含石油烃、多环芳烃、苯系物和农药的污染土壤的研究进展。提出未来的研究方向：充分利用CaO₂水解生成O₂和H₂O₂的特性,探索化学与生物联合修复技术;探究CaO₂与其他氧化剂联用技术,从而增加CaO₂修复技术的适用性和经济性。     

光助MIL-101(Fe)活化过氧化氢氧化洛克沙胂及同步吸附生成的砷酸根

采用铁基金属有机框架(MIL-101(Fe))在模拟太阳光下活化过氧化氢氧化降解ROX—吸附去除生成的砷酸根.结果表明,光助MIL-101(Fe)(250mg/L)活化氧化剂H2O2(1.0mmol/L)体系可在120min内实现95.27％的ROX去除率,反应过程中形成的无机砷酸盐(As(Ⅴ))会吸附在MIL-101...     

H_2O_2/草酸铁络合物对有机染料废水的光氧化脱色

研究了400W高压汞灯下有机染料模拟废水的光氧化脱色,实验结果表明:在近紫外光照射下,H_2O_2/草酸铁络合物能使染料迅速氧化脱色,其脱色速率显著高于UV/H_2O_2光氧化;pH在3左右,脱色效果最佳,pH>4脱色率急剧下降;Fe~(3+)、草酸和H_2O_2的浓度以及温度等因素对染料废水的光氧化脱色率均有较大影响;水溶性的单偶氮染料和双偶氮染料光氧化脱色效果最好。     

Influence of H2S and NH3 on biogas dry reforming using Ni catalyst: a study on single and synergetic effect

● NH₃ in biogas had a slight inhibitory effect on dry reforming. ● Coexistence of H₂S and NH₃ led to faster decline of biogas conversion. ● Regeneration was effective for catalysts deactivated under synergetic effect. Biogas is a renewable biomass energy source mainly composed of CH₄ and CO₂. Dry reforming is a promising technology for the high-value utilization of biogas. Some impurity gases in biogas can not be completely removed after pretreatment, which may affect the performance of dry reforming. In this study, the influence of typical impurities H₂S and NH₃ on dry reforming was studied using Ni/MgO catalyst. The results showed that low concentration of H₂S in biogas could cause serious deactivation of catalyst. Characterization results including EDS, XPS and TOF-SIMS confirmed the adsorption of sulfur on the catalyst surface, which was the cause of catalyst poisoning. We used air calcination method to regenerate the sulfur-poisoned catalysts and found that the regeneration temperature higher than 500 °C could help catalyst recover the original activity. NH₃ in the concentration range of 50–10000 ppm showed a slight inhibitory effect on biogas dry reforming. The decline rate of biogas conversion efficiency increased with the increase of NH₃ concentration. This was related to the reduction of oxygen activity on catalyst surface caused by NH₃. The synergetic effect of H₂S and NH₃ in biogas was investigated. The results showed that biogas conversion decreased faster under the coexistence of H₂S and NH₃ than under the effect of H₂S alone, so as the surface oxygen activity of catalyst. Air calcination regeneration could also recover the activity of the deactivated catalyst under the synergetic effect of H₂S and NH₃.