造纸污泥工厂化堆肥过程中理化性质的动态变化

工厂化强制通风静态垛好氧堆肥试验结果表明,造纸污泥与木屑按10∶1比例混合后,2~3 d即可达到60℃,高温期维持时间超过10 d,完全符合我国标准CJJ/T52-93规定,达到无害化要求;堆肥过程中堆体上层温度大于下层;高温堆肥后物料含水率降低20.2%,脱水效果明显;造纸污泥堆肥过程中物料的挥发性固体持续降低;堆体耗氧速率在升温阶段后期上升到最大值,此后持续降低,到堆肥后期趋于稳定。     

新型调理剂CTB-2污泥堆肥的氧气时空变化特征研究

采用新型CTB-2调理剂与城市污泥进行堆肥,研究了堆肥过程中氧气、温度的时空变化特征。结果表明,m（CTB-2调理剂）：m（污泥）=1：2能够有效降低污泥容重,改善堆体结构;堆体能够快速升温至高温期并持续7d以上,最终完成无害化;采用该比例的调理剂能够保证堆体的通风供氧,使堆体各层通风后的氧气体积分数都恢复至19％以上,最低氧气体积分数维持在数17％以上;堆肥过程中堆体的氧气体积分数、耗氧速率和温度都具有明显的层次效应,堆体耗氧速率呈先升高后降低的趋势,堆体通风后的氧气和最低氧气体积分数均随着堆肥的进行而增加。     

污泥堆肥处理过程中氧气消耗的动态变化与分布特征

对城市污水污泥、粪渣污泥和造纸污泥进行好氧堆肥试验,以研究不同物料堆肥过程中氧气消耗的动态变化、分布特征及其差异.结果表明.不同污泥堆肥时,耗氧速率和温度具有相似的动态变化阶段.在堆体刚进入高温阶段时,耗氧速率不断升高并达到峰值,之后则逐渐减小并趋于稳定,堆肥结束时的耗氧速率只相当于最大值的1/3～1/15.物料组成影响升温速率,耗氧速率的最大值及达到最大值的时间.有机物含量高时,堆体温度上升快、维持持续高温的时间长.堆体各部位耗氧速率存在差异;中间部位的耗氧速率始终较高,在升温期,上层的耗氧速率略高于下层,此后下层的耗氧速率高于上层.堆体上层和下层的氧气含量在堆肥过程中波动较小(>18%),而中间部位的氧气含量波动较大,在高温阶段其含量较低(约12%).使用无机调理剂(CTB调理剂)时,耗氧速率明显小于使用有机调理剂的处理,供氧所需的通风量减少35.9%;堆体升温较慢,温度变化较平缓.根据研究结果提出了优化通风控制的建议.     

城市污泥堆肥过程中H2S的释放动态及其控制策略

以城市污泥为对象，研究了不同堆肥原料配比对H2S释放的影响．结果表明，在堆肥过程中，尽管从释放H2S浓度的动态变化来看存在一定的波动，但总体趋势是：降温期〉高温期〉升温期．采用堆肥物料上、下分层的处理，堆肥所需时问较短，堆体腐熟时H2S的总释放量也最少；同时，采用大功率风机进行鼓风，堆体释放H2S浓度的最大值降低．因此，在城市污泥的堆肥中，采用堆肥物料上下分层与大功率风机相结合的措施，既可以减少H2S的释放量，又可以缩短堆肥时间，是一种有潜在应用价值的堆肥技术．     

Biodegradation of triclosan and triclocarban in sewage sludge during composting under three ventilation strategies

TCS and TCC can be biodegraded during sewage sludge composting. Ventilation significantly accelerated the biodegradation of TCS and TCC in sludge. Composting can reduce the environmental risk of TCS and TCC in sewage sludge. Triclosan (TCS) and triclocarban (TCC) are widely used in home and personal care products as antimicrobial agents. After these products are used, TCS and TCC enter the terrestrial environment and pose a great risk to humans and animals. In this research, the biodegradation of TCS and TCC was investigated during sewage sludge composting with ventilation rates of 108, 92, and 79 m³/min. TCS and TCC were mainly biodegraded in the mesophilic and thermophilic phases, and the biodegradation rates improved with an increase in ventilation. After sewage sludge was composted for 16 days with forced ventilation (108 m³/min), the concentration of TCS decreased from 497.4 to 214.5 μg/kg, and the concentration of TCC decreased from 823.2 to 172.7 μg/kg. The biodegradation rates of TCS and TCC were 65.2% and 83.1%, respectively. However, after the sewage sludge was stacked for 16 days, the biodegradation rates of TCS and TCC were only 17.0% and 18.2%, respectively. The environmental risks of TCS and TCC in the sewage sludge piles significantly decreased after composting. In the sludge pile with a ventilation rate of 108 m³/min, the RQ values of TCS and TCC decreased from 8.29 and 20.58 to 3.58 and 4.32 after composting for 16 days, respectively. There is still a high risk if the sludge compost is directly used as a culture substrate. Nevertheless, the environmental risk could be decreased distinctly if a reasonable quantity of sludge compost is applied to land to ensure an RQ of<1 for TCS and TCC.