混凝法处理丙烯腈-丁二烯-苯乙烯树脂废水

以聚合氯化铝铁为混凝剂、阴离子型聚丙烯酰胺为助凝剂,采用混凝法处理丙烯腈-丁二烯-苯乙烯树脂（ABS）废水（简称废水）,考察了聚合氯化铝铁加入量、沉降时间、搅拌转速、搅拌时间、废水pH和混凝温度对废水处理效果的影响。实验结果表明,在聚合氯化铝铁加入量50mg／L、阴离子型聚丙烯酰胺加入量2mg／L、废水pH6．0～8．0、快速搅拌1min、慢速搅拌6min、沉降时间25min、混凝温度20～25℃的条件下,废水的SS去除率达97％以上,COD去除率达77％以上。     

Regeneration performance and carbon consumption of semi-coke and activated coke for SO2 and NO removal

To decrease the operating cost of flue gas purification technologies based on carbon-based materials, the adsorption and regeneration performance of low-price semi-coke and activated coke were compared for SO₂ and NO removal in a simulated flue gas. The functional groups of the two adsorbents before and after regeneration were characterized by a Fourier transform infrared (FTIR) spectrometer, and were quantitatively assessed using temperature programmed desorption (TPD) coupled with FTIR and acid–base titration. The results show that semi-coke had higher adsorption capacity (16.2% for SO₂ and 38.6% for NO) than activated coke because of its higher content of basic functional groups and lactones. After regeneration, the adsorption performance of semi-coke decreased because the number of active functional groups decreased and the micropores increased. Semi-coke had better regeneration performance than activated coke. Semi-coke had a larger SO₂ recovery of 7.2% and smaller carbon consumption of 12% compared to activated coke. The semi-coke carbon-based adsorbent could be regenerated at lower temperatures to depress the carbon consumption, because the SO₂ recovery was only reduced a small amount.     

A review of the catalysts used in the reduction of NO by CO for gas purification

The reduction of NO by the CO produced by incomplete combustion in the flue gas can remove CO and NO simultaneously and economically. However, there are some problems and challenges in the industrial application which limit the application of this process. In this work, noble metal catalysts and transition metal catalysts used in the reduction of NO by CO in recent years are systematically reviewed, emphasizing the research progress on Ir-based catalysts and Cu-based catalysts with prospective applications. The effects of catalyst support, additives, pretreatment methods, and physicochemical properties of catalysts on catalytic activity are summarized. In addition, the effects of atmosphere conditions on the catalytic activity are discussed. Several kinds of reaction mechanisms are proposed for noble metal catalysts and transition metal catalysts. Ir-based catalysts have an excellent activity for NO reduction by CO in the presence of O₂. Cu-based bimetallic catalysts show better catalytic performance in the absence of O₂, in that the adsorption and dissociation of NO can occur on both oxygen vacancies and metal sites. Finally, the potential problems existing in the application of the reduction of NO by CO in industrial flue gas are analyzed and some promising solutions are put forward through this review.

     

Evaluation of sulfur trioxide detection with online isopropanol absorption method

Measurement of the SO_3 concentration in flue gas is important to estimate the acid dew point and to control corrosion of downstream equipment. SO_3 measurement is a difficult question since SO_3 is a highly reactive gas, and its concentration is generally two orders of magnitude lower than the SO_2 concentration. The SO_3 concentration can be measured online by the isopropanol absorption method; however, the reliability of the test results is relatively low. This work aims to find the error sources and to evaluate the extent of influence of each factor on the measurement results. The test results from a SO_3 analyzer showed that the measuring errors are mainly caused by the gas–liquid flow ratio, SO_2 oxidation, and the side reactions of SO_3. The error in the gas sampling rate is generally less than 13%. The isopropanol solution flow rate decreases 3% to 30% due to the volatilization of isopropanol, and accordingly, this will increase the apparent SO_3 concentration. The amount of SO_2 oxidation is linearly related to the SO_2 concentration. The side reactions of SO_3 reduce the selectivity of SO_4~(2-) to nearly 73%. As sampling temperature increases from180 to 300°C, the selectivity of SO_4~(2-) decreases from 73% to 50%. The presence of H2 O in the sample gas helps to reduce the measurement error by inhibiting the volatilization of the isopropanol and weakening side reactions. A formula was established to modify the displayed value, and the measurement error was reduced from 25%–54% to less than 15%.     

Carbon consumption and regeneration of oxygen-containing functional groups on activated carbon for flue gas purification

Environmental Science and Pollution Research - High carbon consumption is an important factor restricting the wide application of activated carbon technology for flue gas purification. A fixed-bed...