污泥厌氧发酵产氢的影响因素

污水生物处理过程中产生大量剩余污泥, 通常采用厌氧发酵处理并获取甲烷气体. 产氢产酸是污泥厌氧消化过程中的一个中间阶段. 本研究考察了原污泥和经碱处理的污泥在不同初始pH(3.0～12.5)条件下的产氢效果, 以及污泥性质和污泥浓度等对产氢效果的影响. 结果表明, 当初始pH为11.0时污泥发酵的产氢率达到最大值.采用原污泥发酵产氢时, 在初始pH为11.0的条件下发酵产氢获得的最大产氢率为8.1 mL/g, 而经碱处理的污泥在同样初始pH的条件下发酵产氢可将其产氢率提高一倍左右, 达到16.9 mL/g. 污泥经碱处理后厌氧发酵4d无甲烷产生, 且可有效地降低氢气消耗的速率. 另外, 污泥的VSS/SS值过低时会大大降低污泥的产氢率, 而污泥浓度对产氢率无明显影响.     

pH值与乙酸对易腐有机垃圾水解过程的抑制

通过外部添加水解酶比较和区分pH值和乙酸对水解的影响,结果表明:以固相挥发性固体和元素碳的减少以及液相有机碳的增加表征水解率,在pH=7时最大,144h的水解率可达66.9%;与pH=7相比,pH=8-9时,水解率降低8%-24%;pH=5-6,水解率降低40%-60%.20g·l-1乙酸的加入抑制了水解,在不同pH值条件下与不添加乙酸的水解相比,抑制程度为2%-35%,pH=7时乙酸的抑制最显著,可达35%.颗粒态物料的水解过程动力学符合Chen-Hashimoto公式.     

Analysis of metabolic changes in Trichoderma asperellum TJ01 at different fermentation time-points by LC-QQQ-MS

Trichoderma spp. are among the most widely recognized biocontrol fungi used to inhibit pathogens and promote plant growth. These functions are related to primary and secondary metabolites. This study investigated the different metabolites in Trichoderma asperellum TJ01 cultured for 24 and 72?h using liquid chromatography with triple-quadrupole mass spectrometry. Compared to the 24?h culture of T. asperellum TJ01, the 72?h culture with amino acid metabolism tended to decrease while sugar and lipid metabolisms tended to increase. Furthermore, the 72?h culture had a higher proportion of upregulated flavonoids, in combination with a higher proportion of downregulated alkaloids, and equal proportions of upregulated and downregulated polyphenols and hormones. This study also identified a few valuable medicinal substances such as trigonelline and 5-hydroxytryptophan in T. asperellum TJ01 fermentation cultures.     

污泥膜覆盖好氧发酵堆体流场模拟及应用研究简

运用Gambit软件建立了污泥好氧发酵堆体的多孔介质模型,通过自行设计的实验装置获得了堆体的通风粘性阻力系数和惯性阻力系数以及功能膜压差与透气量之间的关系,用Fluent软件分析了堆体不同截面形状及底部通风管数量对堆体通风均匀性的影响,为确定合理的通风管数量及截面几何形状提供理论依据。对上海奉贤区城镇污水厂污泥处理工程发酵仓进行堆体流场模拟,确定堆体采用小拱形截面形状,堆高2 m,宽8 m,底部设置4条通风管,实际运行效果良好。     

水生植物酸碱预处理对厌氧发酵联产氢气-甲烷的影响简

采用酸碱预处理乌梁素海典型沉水植物龙须眼子菜和挺水植物芦苇,通过厌氧发酵动力学分析、还原糖变化及微观结构解析,研究酸碱预处理对水生植物厌氧发酵联产氢气-甲烷的影响。实验结果表明,酸碱预处理后水生植物厌氧发酵联产氢气-甲烷两阶段累积产气量、氢气及甲烷含量均显著提高,酸处理效果优于碱处理。采用0.5 mol/L HCl预处理龙须眼子菜效果最佳,最大氢气、甲烷含量分别达42.65%和52.82%,产氢气速率为4.118 mL/h,产甲烷速率最高达14.199 mL/h。芦苇经1 mol/L HCl预处理效果最佳,最高氢气、甲烷含量分别为32.22%和65.26%。扫描电镜微观结构分析表明,酸碱预处理可显著破坏芦苇、龙须眼子菜的纤维素结构,有效增加植物与微生物接触面积,有利于厌氧发酵联产氢气-甲烷工艺的快速启动和稳定运行。     

利用三七渣固态发酵灵芝菌的研究

以川芝6号为发酵菌种,对三七渣固态发酵灵芝菌的培养基制备条件进行了研究和优化。结果表明,优化的培养基制备条件为采用过60目筛的三七渣,酵母粉添加量5%(质量分数,下同),磷酸二氢钾添加量0.025%,培养基含水量70%,不调节初始pH。在此条件下进行灵芝发酵,发酵培养物中灵芝菌丝体的质量分数最高可达31.27%。     

城市生活垃圾和污水处理厂剩余污泥混合发酵的原料配比优化研究

以城市生活垃圾和污水处理厂的剩余污泥为混合原料,研究了混合原料的不同配比对厌氧发酵过程及产气的影响。结果表明:城市生活垃圾与剩余污泥以挥发性固体(VS)质量比为2∶1混合后,厌氧发酵效果最好,累计产气量最高,达到8 721mL,发酵后的总固体(TS)、VS、COD去除率分别达43.65%、35.98%、47.88%;各实验组在发酵过程中的pH、氨氮浓度和碱度均在合理范围内,未对厌氧发酵反应造成影响;以适当配比的城市生活垃圾和剩余污泥为混合原料,进行中温联合厌氧发酵是可行的,联合厌氧发酵可以弥补单一原料的缺陷,在一定程度上改善厌氧发酵效果。     

猪粪干发酵物料流动性指标研究

干式沼气发酵工艺的研究中,影响干发酵工艺的最大问题是出料困难.出料的方法及设备的研究开发都涉及物料流动性.目前,还没有表征干发酵物料流动性的指标.针对该问题,本研究考察了塌落度、休止角和静摩擦系数3种参数表征猪粪干发酵物料流动性的可行性.通过3种指标对流速的曲线拟合,发现塌落度与流速的关联性最好,灵敏度系数曲线显示塌落度的灵敏度较休止角和静摩擦系数高.塌落度的测定上限和测定下限分别为253和279 mm,对应的流速分别为0.01和0.29 m/s;休止角和静摩擦系数的准确度均超出了要求的范围,所以无测定限.塌落度的最大相对误差、相对平均偏差和相对标准偏差分别为12.79％、23.62％和30.68％,远低于休止角和静摩擦系数,因此,塌落度测量结果的准确度和精密度高于休止角和静摩擦系数.从参数的准确度和精密度以及测量方法的灵敏性和测定限几方面综合考虑,塌落度适合作为表征猪粪干发酵物料流动性的指标.     

热处理时间对餐厨垃圾高温干式厌氧发酵的影响

餐厨垃圾中有机物大部分以大分子的形式存在,对其进行热处理,破坏大分子有机物的存在形式,将会影响其干式厌氧发酵的过程。实验对餐厨垃圾进行了热处理(100℃),处理后将其在含固率(TS)20%、接种率25%的条件下进行高温55℃厌氧发酵。实验结果表明,热处理后,餐厨垃圾的理化性质发生显著变化,累计产气量、TS和VS的去除率均增大。当热处理时间为15 min时,餐厨垃圾的SCOD值最高,为59.49 g/L,比未处理时提高了3.3倍。同样该条件下,累计产气量也最高,为2 782.8 m L,与未处理相比累积产气量提高58.30%,第二产气高峰比未处理提前3天。各发酵瓶发酵前后TS、VS去除率的变化趋势与累计产气量的变化基本一致,累计产气量越大,TS、VS的去除率越大。     

Kinetics study of fermentative hydrogen production from liquid swine manure supplemented with glucose under controlled pH

Kinetics of H₂ production from liquid swine manure supplemented with glucose by mixed anaerobic cultures was investigated using batch experiments under four different pH conditions (4.4, 5.0, 5.6, and uncontrolled). The temperature for the experiments was controlled at 37 ± 1°C and the length of experiments varied between 50 and 120 hours, depending upon the time needed for completion of each individual experiment. The modified Gompertz model was evaluated for its suitability for describing the H₂ production potential, H₂ production rate, and substrate consumption rate for all the experiments. The results showed that the Gompertz model could adequately fit the experimental results. The effect of pH was significant on all kinetic parameters for H₂ production including yield, production rate and lag time, and the substrate utilization rate. The optimal pH was found to be 5.0, at which a maximum H₂ production rate (0.64 L H₂/h) was obtained, and deviation from the optimal pH could result in substantial reductions in H₂ production rate (0.32 L H₂/h for pH 4.0 and 0.43 L H₂/h for pH 5.6). The results also showed that if pH was not controlled for the batch fermentation process, the substrate utilization efficiency could steeply decrease from 98.8% to 33.7%.