温度对干化污泥水蒸气气化产气特性的影响

采用固定床气化装置,在水蒸气流量为0.32 kg/h条件下进行了污泥水蒸气气化实验。研究了温度对污泥气化气体产率、氢气产率、气体成分与低位热值、气体能源转化率的影响。结果表明:随着反应温度从700℃上升到1 000℃;气体产率从0.39 m3/kg升至0.61 m3/kg;氢气产率从0.18 m3/kg升至0.34 m3/kg;气体能源转化率从54%升至88%;产气的低位热值从10 688.1 kJ/m3提高至11 168.9 kJ/m3。同时产气中H2和CO含量随着温度的升高而增加,CH4、CO2和CnHm含量随温度的升高而减少。因此,为了获得更多的可燃气体,建议在污泥水蒸气气化工艺中,气化温度必须大于800℃。     

Elemental mercury (Hg0) removal from coal syngas using magnetic tea-biochar: Experimental and theoretical insights

Mercury is ranked 3^rd as a global pollutant because of its long persistence in the environment. Approximately 65% of its anthropogenic emission (Hg⁰) to the atmosphere is from coal-thermal power plants. Thus, the Hg⁰ emission control from coal-thermal power plants is inevitable. Therefore, multiple sorbent materials were synthesized using a one-step pyrolysis method to capture the Hg⁰ from simulated coal syngas. Results showed, the Hg⁰ removal performance of the sorbents increased by the citric acid/ultrasonic application. T5CUF_0.3 demonstrated the highest Hg⁰ capturing performance with an adsorption capacity of 106.81 µg/g within 60 min at 200 °C under complex simulated syngas mixture (20% CO, 20% H₂, 10 ppmV HCl, 6% H₂O, and 400 ppmV H₂S). The Hg⁰ removal mechanism was proposed, revealing that the chemisorption governs the Hg⁰ removal process. Besides, the active Hg⁰ removal performance is attributed to the high dispersion of valence Fe₃O₄ and lattice oxygen (α) contents over the T5CUF_0.3 surface. In addition, the temperature programmed desorption (TPD) and XPS analysis confirmed that H₂S/HCl gases generate active sites over the sorbent surface, facilitating high Hg⁰ adsorption from syngas. This work represented a facile and practical pathway for utilizing cheap and eco-friendly tea waste to control the Hg⁰ emission.     

低温下玉米秸秆与牛粪混合厌氧发酵产气特性研究

通过静态试验,探究在15℃的低温条件下,经过预处理的玉米秸秆和牛粪,在不同混合配比下厌氧发酵的产气特性。试验结果表明:将牛粪与秸秆按1∶1配比的产气效果最好,相对于配比为2∶1、3∶1的累积产气量分别高出52.66%和73.60%。随着发酵过程进行,COD波动很大。发酵过程中碳源主要由玉米秸秆提供,秸秆所占比例越大,COD降解率越高。日产气量达到高峰的时间稍滞后于VFA,秸秆比例越大的组别,VFA整体处于越高水平。而辅酶F420与产气量之间关系不显著。发酵初期CMC酶活力变化显著,且以玉米秸杆与牛粪配比为1∶1为配比的一组CMC酶活力高于其余2组,最高值达到了15.042 U/g。     

O_3-MBR法深度处理煤气废水

以经多级生物处理后的煤气废水为原水,采用O3-MBR组合工艺对其进行深度处理,以满足回用要求.结果表明:采用臭氧氧化工艺,当废水pH为11和臭氧投加量〔ρ(臭氧)〕为189.2mg/L时,CODCr和色度的去除率分别为46.5%和80.2%,ρ(BOD5)/ρ(CODCr)由0.02升至0.29,废水的可生化性得到明显改善;臭氧氧化工艺出水再通过MBR作进一步处理,CODCr,NH3-N和色度的去除率分别达23.0%,76.3%和70.0%,且出水水质稳定;总体上,废水经O3-MBR组合工艺处理,CODCr,NH3-N,色度和浊度的平均总去除率分别达到58.7%,76.3%,88.6%和95.1%;处理后出水的ρ(CODCr)50mg/L,ρ(NH3-N)5mg/L,浊度0.2NTU,色度约为30度,出水水质满足生产工艺回用的要求.     

等离子体热解气化有机废弃物制氢的关键技术分析

等离子体热解气化有机固体废物制氢是一种先进高效的废物处理及资源化利用技术.首先,本文讨论了等离子体热解气化有机废弃物的机理,也概括了等离子体发生器的类型及其特点,其次分析了等离子体处理固体废弃物的影响因素,认为输入功率和载气类型等是影响等离子体处理的主要因素,最后总结了等离子体处理医疗垃圾、农林生物质、污泥等的应用现状与前景,指出等离子体热解气化固体废弃物是一种很有潜力的制氢方法.     

内置预分离复合式飞灰过滤器的开发与应用

针对飞灰过滤器除尘压降高、反吹清灰频繁、过滤元件破损、使用寿命短和大型化受到限制等问题,开发了内置旋风预分离复合式飞灰过滤器,并在工业装置上进行了应用,应用结果表明:过滤器压降明显降低、旋风分离器压降满足系统要求、延长了陶瓷滤芯的使用寿命、减少了因飞灰过滤器故障造成整个装置停车,同时,可带来直接经济效益约1 709万元/a、间接经济效益超过5 000万元。     

煤气化废水中有机物对磷酸铵镁结晶法去除氨氮的影响

研究了杂环类(吡啶、喹啉)和酚类(间甲酚、二甲酚、苯酚)有机物对磷酸铵镁结晶法(MAP,magnesium ammonium phosphate)处理废水中氨氮的影响.研究表明,杂环和酚类有机物均对MAP法的除氮效果产生抑制作用,杂环类有机物的抑制作用大于酚类有机物,其中加入吡啶、喹啉、间甲酚、二甲酚、苯酚相比于对照组(21 mg·L-1),氨氮残余浓度分别升高45.17、56.66、43.01、50.68、49.72 mg·L-1.因为络合作用和吸附作用,多组分体系MAP晶体产生的抑制作用强于单一组分体系.     

生物膜反应器降解生物质气化洗焦废水

陶瓷球作为固定介质 ,接种本实验室保藏的Pseudomonassp1和Pseudomonassp2混合菌种 ,应用生物膜反应器处理生物质气化过程中产生的洗焦废水 ,对反应器运转整个过程的进出水COD浓度、进出水苯、萘、菲、吡啶、喹啉、异喹啉的含量、反应器内和反应器出水含菌量进行测定 ,以了解生物膜反应器处理生物质气化洗焦废水的特性 .结果表明 ,反应器经挂膜、增菌后 ,可达到稳定运转状态 ,有效的控制了反应器内微生物细胞的流失 ,使生物质气化洗焦废水中的有机物得到较好去除 .     

Supercritical gasification for the treatment of o-cresol wastewater

The supercritical water gasification of phenolic wastewater without oxidant was performed to degrade pollutants and produce hydrogen-enriched gases. The simulated o-cresol wastewater was gasified at 440-650℃ and 27.6 MPa in a continuous Inconel 625 reactor with the residence time of 0.42-1.25 min. The influence of the reaction temperature, residence time, pressure, catalyst, oxidant and the pollutant concentration on the gasification efficiency was investigated. Higher temperature and longer residence time enhanced the o-cresol gasification. The TOC removal rate and hydrogen gasification rate were 90.6% and 194.6%, respectively, at the temperature of 650℃ and the residence time of 0.83 min. The product gas was mainly composed of H2, CO2, CFL and CO, among which the total molar percentage of H2 and CFL was higher than 50%. The gasification efficiency decreased with the pollutant concentration increasing. Both the catalyst and oxidant could accelerate the hydrocarbon gasification at a lower reaction temperature, in which the catalyst promoted H2 production and the oxidant enhanced CO2 generation. The intermediates of liquid effluents were analyzed and phenol was found to be the main composition. The results indicate that the supercritical gasification is a promising way for the treatment of hazardous organic wastewater.