低温等离子体技术及其在柴油机排气处理中的应用

概述了等离子体特点及分类 ,介绍了低温等离子体的产生及其净化柴油机排气的应用进展 ,分析了低温等离子体技术有效处理柴油机排气的机理 ,阐述了未来低温等离子体处理柴油机排气的主要方向与应用前景。     

低温等离子体技术处理挥发性有机物

介绍了低温等离子体技术在处理挥发性有机物（VOCs）的研究现状和成果;探讨了低温等离子体技术的发展趋势.     

低温等离子体技术及其在柴油机排气处理中的应用

概述了等离子体特点及分类，介绍了低温等离子体的产生及其净化柴油机排气的应用进展，分析了低温等离子体技术有效处理柴油机排气的机理，阐述了未来低温等离子体处理柴油机排气的主要方向与应用前景。     

低温等离子体处理废液技术研究概述

低温等离子体技术包括热等离子体技术和冷等离子体技术。该技术处理废液具有范围广、快速、高效、无二次污染等优点,尤其对难降解有毒废液的处理,其先进性和优越性更为突出,被认为是21世纪环境污染物处理领域中最有发展前途的新技术之一。综述了低温等离子体处理废液技术的研究和进展,重点分析了冷等离子体技术处理难降解有机废液的作用机理,探讨了其现存的主要问题,并指出了今后需要研究的方向。     

低温等离子体处理柴油机NOx和PM试验研究

建立了一种具有较强实用性的介质阻挡放电等离子体反应器试验装置.借助静态试验研究其放电特性,通过发动机台架试验探讨了利用低温等离子体处理柴油机2种主要有害排放物NOx和PM的效果和化学反应机理,并通过模拟试验作了处理PM的进一步验证.试验结果表明,放电功率对于低温等离子体活性成分的产生有重要影响,应当优选放电参数以获得高的放电功率从而达到更好的处理效果;采用低温等离子体处理柴油机排气,NOx总量变化不大,主要将NO转化成NO2;低温等离子体可以有效去除柴油机排气中的PM,去除率随能量密度的增大而提高.     

美国推出数据存储新技术

由化工厂、制药厂、垃圾填埋场、污水处理厂以及家庭装修等产生的恶臭,严重影响人们的生活和健康,迫切需要加以治理。上海乾瀚环保公司开发成功具有自主知识产权的低温等离子体空气净化设备,对各类恶臭气体、烟尘、废气、细菌等都具有很好的处理效果。低温等离子体被称作物质的第四形态,其原理是利用螺旋微波温冷光技术产生的高能离子束和电子束形成的低温等离子体,以每秒300万～3000万次的速度反复轰击恶臭气体分子,激活、电离、裂解废气中各种成分,     

柴油车排气颗粒物的后处理技术

本文分析探讨了柴油机排气颗粒物的组成、危害及后处理技术。介绍了颗粒捕集器及其消极和积极再生方法、采用氧化催化剂或四效催化剂的催化净化器和低温等离子体 -催化净化技术。     

有毒有害气体低温等离子体催化处理反应器

等离子体催化技术是目前国内外公认的治理低浓度有害气体的有效方法之一。本文概述了填充床式反应器、点对板式反应器、平板式反应器和复合式反应器中利用低温等离子体结合催化剂处理有害废气的研究结果,并对反应器的结构、脱除效率及应用情况作了介绍。     

相对湿度对ZSM-5分子筛低温等离子体再生特性的影响

低温等离子体再生法是一种低温、快速和高效的吸附材料再生新方法。运用管式单介质阻挡放电反应器产生的低温等离子体对吸附了苯的ZSM-5分子筛进行再生处理,分析了湿度对低温等离子体放电状态的影响,研究了湿度对材料吸附性能及低温等离子体再生效果的影响,考察了特定湿度条件下低温等离子体再生吸附材料的可重复性。实验结果表明,当相对湿度小于60%时,吸附材料的脱附效率和再生效率随湿度增加而升高;当相对湿度由60%升高至80%时,吸附材料的脱附效率和再生效率开始下降;但通过对比不同湿度条件再生后吸附材料的饱和吸附容量可以发现,湿度越低,再生后吸附材料的饱和吸附容量越大;在相对湿度30%的条件下,重复再生效率稳定,且重复再生后吸附材料仍有较好的吸附效果。     

低温等离子体杀菌的实验研究

由于传统的化学水处理方式有化学成分残留和环境污染问题,因而迫切需要开发新型的水处理技术。本研究针对现有杀菌消毒方法的不足之处,利用低温等离子体进行杀菌处理的实验研究,对电压、水层厚度、气体种类及电极形式的影响进行考察。结果表明,低温等离子体用于杀菌不仅效果显著,而且使用方便、快捷、安全并无残留,因而适于饮用水或者生活污水的杀菌处理。     

Decomposition of volatile organic compounds using gliding arc discharge plasma

ABSTRACT

This work provides a systematic review on the decomposition of volatile organic pollutants in flue gas through the gliding arc (GA) plasma technology. To begin with, the basic mechanisms of GA plasma generation are summarized and three characteristic stages existed during the GA plasma generation process are revealed: gas breakdown stage, equilibrium stage, and non-equilibrium stage. Then, the types of GA reactors are comparatively illustrated. Possible destruction mechanisms of volatile organic compounds (VOCs) by GA plasma are discussed by taking chloroform, benzene, and methanol as examples. Furthermore, the effects of many operating parameters on the VOCs destruction efficiency are comprehensively analyzed. Simultaneously, the product distribution, energy cost, technical and economic during the whole decomposition process are considered. Finally, the advantages and disadvantages of GA plasma and its further development trend are concluded from the academic and industrial application of GA plasma in VOCs decomposition.

Implications: This paper comprehensively describes the principle, characteristics, research progress and engineering application examples of the degradation of volatile organics by gliding arc discharge plasma, so that readers can fully understand the degradation of volatile organics by gliding arc discharge plasma and provide theoretical basis for the industrial application of the degradation of volatile organics by gliding arc discharge plasma.     

Decomposition of volatile organic compounds using corona discharge plasma technology

This paper explores the application of corona plasma technology as a tool in treatment of volatile organic compounds (VOCs). The review introduces the principle of corona discharge and describes the characteristics of plasma, especially of various corona plasma reactors. By summarizing the main features of such reactors, this paper provides a brief background to different power sources and reactor configurations and their application to VOC treatment design. Considering chlorinated compounds, benzene series and sulfur compounds, this paper reveals the probable mechanism of corona plasma in VOC degradation. Additionally, the effects of numerous technical parameters – such as reactor structure, shape and materials of electrodes, and humidity – are analyzed comprehensively. Product distribution, energy efficiency and economic benefits are invoked as factors to evaluate the performance of VOC degradation. Finally, the practical application of corona plasma and its advantages are briefly introduced. The review aims to illustrate the enormous potential of corona plasma technology in the treatment of VOCs, and identifies future directions.

Implications: This paper comprehensively describes the principle, characteristics, research progress and engineering application examples of the degradation of volatile organics by corona discharge plasma, to provide a theoretical basis for the industrial application of this process.     

高压脉冲电晕法治理有机废气实验研究

介绍了采用高压脉冲电晕法去除乙醇,甲醛,二氧甲灶模拟废气的情况。实验在线一板式电晕反应器内进行,考察了电压峰值,气体浓度,停留时间和含湿量等不同因素对去除率的影响。实验结果表明能达到较好的去除效果。     

A Field Demonstration of the UV/Oxidation Technology to Treat Ground Water Contaminated with VOCs

This paper presents the Geld evaluation results of the ultraviolet radiation (UV)/oxidation technology developed by Ultrox International, Santa Ana, California. The Geld evaluation was performed at the Lorentz Barrel and Drum (LB&D) site in San Jose, California, under the Superfund Innovative Technology Evaluation program in February and March of 1989.

The UV/oxidation technology uses UV radiation, ozone, and hydrogen peroxide to oxidize organic contaminants present in water. At the LB&D site, this technology was evaluated in treating ground water contaminated with volatile organic compounds (VOCs). The Ultrox system achieved VOC removals greater than 90 percent. Most VOCs were removed through chemical oxidation. However, for a few VOCs, such as 1, 1, 1-trichloroethane and 1, 1-dichloroethane, stripping also contributed toward removal. The treated ground water met the applicable discharge standards for discharge into a local waterway at 95 percent confidence level. There were no harmful air emissions to the atmosphere from the Ultrox system, which is equipped with an off-gas treatment unit.     

介质阻挡放电和水吸收联合降解挥发性有机化合物

依据介质阻挡放电(DBD)和溶液吸收处理气态污染物的原理,设计出一种DBD和水吸收联合降解挥发性有机化合物(VOCs)的实验装置.研究其对甲苯的降解效果.考察了放电电压、甲苯初始浓度、模拟废气流量对甲苯降解效果的影响.分析了DBD和水吸收的相互作用.结果表明.DBD和水吸收联合可以提高甲苯的降解率.在放电电压为15.9 kV时甲苯的降解率为81.5%.比单独放电时提高了13.3百分点;甲苯的降解率随着放电电压增大而升高,随着气体流量和甲苯初始浓度增大而降低.该技术可以作为放电等离子体前处理工艺,为高效处理上业废气提供参考.     

活性炭纤维净化印刷过程产生的VOCs废气

介绍了应用局部排气的方法,收集印刷过程的挥发性有机化合物(VOCs)废气,应用活性炭纤维(ACF)吸附脱附有机废气回收净化装置,进行印刷厂VOCs废气的回收与治理,详细描述了印刷车间VOCs废气的收集与处理工艺过程及其效果.测试结果表明,应用此工艺和设备可以有效地进行印刷过程大风量的VOCs废气的回收和治理.     

放电等离子体与饲养酵母联合处理味精废水的初步研究

对采用放电等离子体与饲养酵母联合处理味精废水进行了初步研究。结果表明，放电等离子体预处理后废水的CODcr值普遍升高，但经假丝酵母联合处理后CODCr去除率增加了38．3％，效果明显优于仅采用饲养酵母法处理的味精废水，说明放电等离子体预处理可使味精废水中的有机大分子破坏成小分子，有利于生物降解，为味精废水治理提供了一条新的途径。实验初步研究了联合处理后的CODcr去除率与预处理电压、预处理电流、预处理次数的关系，结果表明存在相应的最优值。     

非平衡等离子体技术对有害气体污染物的降解研究进展

由于非平衡等离子体化学过程在增强氧化能力、促进分子离解以及加速化学反应等方面具有很高的效率 ,因此 ,近年来利用非平衡等离子技术对气体污染物的破坏分解研究受到了广泛的关注。本文简述了非平衡等离子体技术对气体污染物的降解原理 ,综述了国内外利用这一技术破坏各种气体污染物的最新进展 ,讨论了放电功率、停留时间、催化剂、化合物结构等因素对放电反应效率的影响 ,并展望了其应用前景     

非热平衡等离子体协同催化脱除挥发性有机化合物的研究进展

单纯运用非热平衡等离子体(NTP)技术脱除挥发性有机化合物(VOCs)的效率和能量利用率并不高,而且在降解过程中可能会产生某些有害副产物。为了克服NTP技术在VOCs治理方面的缺陷,可将NTP和化学催化方法组合运用,结合两者的优势使系统的VOCs脱除率、能量利用率和CO2选择率显著提高。从催化反应器结构、NTP与催化剂协同作用的原理等方面总结了近年来NTP协同催化技术在VOCs脱除方面的应用状况。最后指出,NTP协同催化技术在VOCs脱除方面有良好的应用前景,但要真正实现其工程应用,仍有很多问题亟待研究和解决。     

Microwave plasma conversion of volatile organic compounds

A microwave-induced, steam/Ar/O2, plasma "torch" was operated at atmospheric pressure to determine the feasibility of destroying volatile organic compounds (VOCs) of concern. The plasma process can be coupled with adsorbent technology by providing steam as the fluid carrier for desorbing the VOCs from an adsorbent. Hence, N2 can be excluded by using a relatively inexpensive carrier gas, and thermal formation of oxides of nitrogen (NOx) is avoided in the plasma. The objectives of the study were to evaluate the technical feasibility of destroying VOCs from gas streams by using a commercially available microwave plasma torch and to examine whether significant byproducts were produced. Trichloroethene (TCE) and toluene (TOL) were added as representative VOCs of interest to a flow that contained Ar as a carrier gas in addition to O2 and steam. The O2 was necessary to ensure that undesirable byproducts were not formed in the process. Microwave power applied at 500-600 W was found to be sufficient to achieve the destruction of the test compounds, down to the detection limits of the gas chromatograph that was used in the analysis. Samples of the postmicrowave gases were collected on sorbent tubes for the analysis of dioxins and other byproducts. No hazardous byproducts were detected when sufficient O2 was added to the flow. The destruction efficiency at a fixed microwave power improved with the addition of steam to the flow that passed through the torch.