废气治理的低温等离子体-催化协同净化技术

低温等离子体 催化协同净化技术具有能耗低、投资少、处理效率高、不产生二次污染等显著优点备受人们的关注。从挥发性有机化合物 (VOC)的转化、氮氧化合物的脱除、汽车尾气净化等不同废气治理的角度 ,概括了目前国内外在这方面的研究进展 。

等离子体协同催化还原NO_x过程的中间产物

等离子体协同选择性催化还原(PF-SCR)可以促进富氧环境下氮氧化物(NOx)的有效脱除。为了考察中间产物对NOx去除的影响,该文采用等离子体反应器与催化反应器分离的"两段法",以C2H4为还原剂、Ag/γ-Al2O3为催化剂,对等离子体处理后产生的活性中间产物如C2H2、醛类和含氮有机物等做了定量研究。气相色谱(GC)谱图表明提高能量密度,活性中间产物的峰面积也随着增加。通过对烃类活化产物C2H2和HCHO的检测,给出了能量密度与C2H2、HCHO生成浓度的关系曲线。活性中间产物使PF-SCR系统的NOx去除效果随能量密度增加而不断改善。能量密度为394 J.L-1时等离子体可以将NOx的去除率从单独Ag/γ-Al2O3作用下的31.5%提高到79.9%。

NPSC体系下Ti/HZSM-5在线催化裂解生物油的实验研究

采用离子交换法对HZSM-5进行了Ti负载改性,利用SEM(EDS)、XRD、BET和Py-IR对Ti/HZSM-5进行了表征;建立了低温等离子体协同催化(Non-thermal plasma synergistic catalysis,NPSC)体系,并在该体系下利用Ti/HZSM-5进行了在线催化裂解生物油的研究,分析了"三效"(包括低温等离子体、HZSM-5本身和改性成分)催化对生物油品质以及催化剂稳定性的影响。结果表明,精制生物油产率降低,但其理化特性得到明显提升,高位热值达37.02 MJ/kg;精制生物油中烃类含量和组成均得到明显提升和改善,低温等离子体技术的协同作用,有效增强了裂解脱氧性能,烃类质量分数达89.49%,且多环芳香烃(Polycyclic aromatic hydrocarbons,PAHs)明显减少,但精制生物油仍属缺氢燃料;Ti改性成分与高能放电、HZSM-5之间存在多重交互作用,较强的裂解性能使Ti/HZSM-5结焦量有所增加,并出现两类焦炭"同构化"现象,较低的(nH/nC)eff使催化剂稳定性难以得到实质性提升。

不同组分过渡金属氧化物催化剂对介质阻挡放电固氮的影响机制

为了促进介质阻挡放电(DBD)协同催化固氮效果,制备了不同组分Mn/Co/W元素的单一型、二元和三元复合型负载催化剂,并将催化剂置入DBD气隙中进行等离子体协同催化固氮反应.通过X射线衍射(XRD)、扫描电子显微镜(SEM)和X射线能谱(EDS)表征了催化剂的性质,并采用紫外分光光度法测定了液相中的总氮浓度.结果表明,填充催化剂实验组比未填充催化剂组的总氮浓度明显提升.采用傅里叶变换红外光谱仪对有/无催化剂填充两种情况下DBD的气相产物进行了检测,结果表明,填充催化剂能促进空间内NO_(2)和N_(2)O_(5)的生成.通过DBD气相链式反应和催化原理揭示了总氮浓度得以提升的原因,是由于催化剂在等离子协同过程中提供了大量的氧空位,使得NO_(x)充分氧化.多元复合型催化剂能在单一型的基础上,通过金属元素价态的变换和能量的传递进一步促进固氮效果,三元复合型催化剂Mn_(3)WCo/γ-Al_(2)O_(3)在电压为22 kV时的固氮最高总氮浓度为119.13 mg/L,较未填充催化剂组的最大值提升了71.61%,能耗降低了21.70%.

Synergetic effect between non-thermal plasma and photocatalytic oxidation on the degradation of gas-phase toluene: Role of ozone

In this study, a hybrid process using non‐thermal plasma (NTP) and photocatalytic oxidation (PCO) was adopted for the degradation of gas‐phase toluene using TiO2 as the photocatalyst. To discover the synergetic effect between NTP and PCO, the performances of both sole (O3, UV, NTP, and PCO) and combined (O3 + TiO2, O3 + UV, NTP + UV, O3 + PCO, and NTP + PCO) processes were investigated from different perspectives, such as the toluene removal efficiency, selectivity of COx, mineralization rate, ozone utilization, and the generation of by‐products. The toluene removal efficiency of the combined NTP + PCO process was 80.2%, which was much higher than that of a sole degradation process such as NTP (18.8%) and PCO (13.4%). The selectivity of CO2 and the ozone utilization efficiency also significantly improved. The amount of by‐products in the gas phase and the carbon‐ based intermediates adsorbed on the catalyst surface dramatically reduced. The improvement in the overall performances of the combined NTP + PCO process was mainly ascribed to the efficient utilization of ozone in the photocatalytic oxidation, and the ozone further acting as an electron acceptor and scavenger, generating more hydroxyl radicals and reducing the recombination of electron‐ hole pairs.