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生物膜填料塔对低浓度甲苯废气的净化性能研究 总被引:14,自引:1,他引:14
在扩大的实验装置上,考察研究了入口气体甲苯浓度、气体流量、液体喷淋量、填料层高度、操作方式等因素对生物膜填料塔净化低浓度甲苯废气性能的影响,取得了一定的基础数据,为下一步的工业应用提供依据。 相似文献
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生物膜填料塔净化低浓度苯乙烯废气的实验研究 总被引:2,自引:0,他引:2
研究了进口气体中苯乙烯浓度、气体流量和液体流量等3个因素对生物膜填料塔净化苯乙烯废气的影响。研究结果表明,当进口气体中苯乙烯浓度为1000mg/m^3以下、气体流量为200L/h、循环液流量为10L/h的操作条件下,废气中苯乙烯的去除率可达90%以上。 相似文献
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生物法净化再生胶生产废气工业试验研究 总被引:5,自引:0,他引:5
在再生橡胶厂进行橡胶再生低浓度有机废气的生物法净化工业试验研究,对于甲苯浓度为300~1400mg/m^3的再生胶脱硫废气,在常温常压下以气体流量10~20m^3/h、循环液体喷淋量300~500L/h运行生物法废气净化装置获得了良好物净化效果。该装置连续运行100d的结果显示,其对再生胶废气中甲苯的净化效率可较长时间的保持在90%左右,废气经处理后可以实现达标排放,废气处理成本约为工厂再生胶产值的0.12%~0.14%,具有明显的技术先进性和经济合理性。 相似文献
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废气生物净化技术研究进展 总被引:9,自引:0,他引:9
废气生物净化技术是近年来发展起来的大气污染控制新技术,文章介绍了国内外这方面的历史及现状、主要处理工艺设备,概述了目前所进行的微生物学及反应动力学方面的研究,同时指出了今后的研究方向。 相似文献
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生物过滤塔处理实验室废气 总被引:1,自引:0,他引:1
研究了生物过滤塔处理实验室排放的模拟混合废气,考察了反应器对苯、甲苯、二甲苯、乙醇、丙酮、乙酸乙酯和甲烷等废气的去除效果。运行结果表明,在设备稳定运行期间,进气中总挥发性有机物(TVOCs)的浓度为124~380 mg/m3,而出气浓度在10~40 mg/m3,去除效率保持在85%以上。实验室废气中的多种污染物在生物过滤塔中去除机理不同,亲水性污染物的去除效率高于疏水性污染物。通过系统关停后重启,污染物的去除效果在第2天就能恢复,这为生物过滤塔处理实验室废气过程的停运检修或者系统闲置提供了可行性。 相似文献
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自制TiO2光催化涂料,重点对所制备的涂料在室内进行降解甲醛研究,考察了在不同分散剂、不同光催化剂以及不同甲醛初始浓度、不同光源、不同温度和不同湿度等环境因素下涂料对甲醛降解率的影响。结果表明,选用聚丙烯酸钠离子型分散剂,铜金属掺杂TiO2光催化剂制备的光催化涂料对甲醛降解率达80%以上且具有良好的耐久性,在室温(20℃左右)湿度50%日光灯照射下,甲醛初始浓度5μL时效果最佳。 相似文献
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石灰石湿法脱硫过程中SO2吸收数学模型 总被引:4,自引:1,他引:3
为揭示石灰石湿法脱硫体系中喷淋塔内SO2的浓度和脱硫效率的变化情况,针对喷淋塔内石灰石在气膜控制、气液膜控制和固体溶解控制的3个不同阶段,以双膜理论为基础,以单个石灰石颗粒为研究对象,通过石灰石在不同阶段的转化率和粒径变化,得到SO2在不同阶段脱硫效率随时间的变化规律,建立SO2吸收的数学模型.模型计算结果表明,在烟气行程上,脱硫效率受SO2气膜传质阻力和石灰石溶解速率限制.在吸收塔底部和上端SO2吸收速率较低,在SO2和石灰石摩尔比在适宜条件下,有效吸收段高度为2 m左右.理论模型揭示的规律对喷淋塔的设计和运行参数选取有一定借鉴意义. 相似文献
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利用自制光催化气体反应器体系,以活性炭纤维负载TiO2作催化剂,在紫外光照射下模拟降解室内污染气体甲醛,测试了活性炭纤维负载TiO2催化剂的催化活性,探讨了紫外光光强、催化剂的酸度、反应器内湿度及反应时间等控制反应的主要因素对甲醛降解率的影响。结果表明,活性炭纤维与TiO2的协同作用大大提高了对甲醛的降解效果;紫外光强增倍对甲醛降解率有一定提高,但提高幅度仅为11.71%;活性炭纤维用pH=5的TiO2溶胶浸泡做催化剂对甲醛的降解效果最好,60 min内降解率达到68.37%;反应器内的湿度为81%甲醛降解率最高,反应60 min后达82.2%;随着反应时间的延长,甲醛降解率的上升幅度不断减小,最高只能达到94.59%。 相似文献
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Elham F. Mohamed Mohammed A. El-Hashemy Nasser M. Abdel-Latif Waleed H. Shetaya 《Journal of the Air & Waste Management Association (1995)》2013,63(12):1413-1420
Agricultural wastes such as rice straw, sugar beet, and sugarcane bagasse have become a critical environmental issue due to growing agriculture demand. This study aimed to investigate the valorization possibility of sugarcane bagasse waste for activated carbon preparation. It also aimed to fully characterize the prepared activated carbon (BET surface area) via scanning electron microscope (SEM) and in terms of surface functional groups to give a basic understanding of its structure and to study the adsorption capacity of the sugarcane bagasse-based activated carbon using aqueous methylene blue (MB). The second main objective was to evaluate the performance of sugarcane bagasse-based activated carbon for indoor volatile organic compounds removal using the formaldehyde gas (HCHO) as reference model in two potted plants chambers. The first chamber was labeled the polluted chamber (containing formaldehyde gas without activated carbon) and the second was taken as the treated chamber (containing formaldehyde gas with activated carbon). The results indicated that the sugarcane bagasse-based activated carbon has a moderate BET surface area (557 m2/g) with total mesoporous volume and microporous volume of 0.310 and 0.273 cm3/g, respectively. The prepared activated carbon had remarkable adsorption capacity for MB. Formaldehyde removal rate was then found to be more than 67% in the treated chamber with the sugarcane bagasse-based activated carbon. The plants’ responses for this application as dry weight, chlorophyll contents, and protein concentration were also investigated.Implications: Preparation of activated carbon from sugarcane bagasse (SCBAC) is a promising approach to produce cheap and efficient adsorbent for gas pollutants removal. It may be also a solution for the agricultural wastes problems in big cities, particularly in Egypt. MB adsorption tests suggest that the SCBAC have high adsorption capacity. Formaldehyde gas removal in the plant chambers indicates that the SCBAC have potential to recover volatile gases. The results confirmed that the activated carbon produced from sugarcane bagasse waste raw materials can be used as an applicable adsorbent for treating a variety of gas pollutants from the indoor environment. 相似文献
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纯碱厂在生产纯碱过程中要排放出大量碱性废液 ,如果利用其作为净化锅炉烟气的脱硫剂 ,不仅减低了脱硫剂费用 ,而且消除了SO2 污染。本文在简单分析旋流板塔式除尘脱硫装置的结构和工作原理的基础上 ,探讨了利用碱性废液进行烟气除尘脱硫的主要影响因素 ,并找出了最佳操作条件。试验结果表明 :利用纯碱厂排放的碱性废液———一次盐泥进行锅炉烟气脱硫可以取得较高的净化效率 ,同时解决了因为碱性废液排放而给周围水域带来的污染。旋流板塔式除尘脱硫装置结构简单 ,脱硫效率高 ,并且运行安全稳定 ,是一项值得推广的技术 相似文献
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活性炭纤维负载TiO2光催化降解甲醛的影响因素 总被引:1,自引:0,他引:1
利用自制光催化气体反应器体系,以活性炭纤维负载TiO2作催化剂,在紫外光照射下模拟降解室内污染气体甲醛,测试了活性炭纤维负载TiO2催化剂的催化活性,探讨了紫外光光强、催化剂的酸度、反应器内湿度及反应时间等控制反应的主要因素对甲醛降解率的影响。结果表明,活性炭纤维与TiO2的协同作用大大提高了对甲醛的降解效果;紫外光强增倍对甲醛降解率有一定提高,但提高幅度仅为11.71%;活性炭纤维用pH=5的TiO2溶胶浸泡做催化剂对甲醛的降解效果最好,60 min内降解率达到68.37%;反应器内的湿度为81%甲醛降解率最高,反应60 min后达82.2%;随着反应时间的延长,甲醛降解率的上升幅度不断减小,最高只能达到94.59%。 相似文献
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Prediction of adsorption rate of phosphate removal from wastewater with gas concrete 总被引:1,自引:0,他引:1
《国际环境与污染杂志》2011,19(6):603-614
Gas concrete, a conventional structural material, is used to remove phosphate from wastewater. A batch study of phosphate removal from wastewater with waste particles of gas concrete has been performed. The concentration-time graphs were plotted against pH, temperature, and agitation speed, and the reaction rate equation was adapted to adsorption. The differential method was used to define reaction rate. The adsorption rates, reaction rate constants, and reaction rates were determined by tangent lines of drawn curves at different concentrations, depending on pH, temperature, and agitation speed. The adsorption rate increased with pH and temperature. The maximum effect of agitation speed on the adsorption rate was observed at 150 rpm. The activation energy of reaction and the pre-exponential factor were calculated using the Arrhenius equilibrium equation. The zeta potentials of waste gas concrete were determined at various pH values. The surface area of gas concrete was obtained using BET apparatus as 22 m2/g. The composition of gas concrete was determined by X-ray diffractometry. The results indicate that gas concrete is an effective adsorbent to remove phosphate from wastewater. 相似文献