超高效厌氧生物反应器能耗特征

化工学报 ›› 2009, Vol. 60 ›› Issue (12): 3097-3103.

超高效厌氧生物反应器能耗特征

陈小光;郑平;唐崇俭;张蕾

浙江大学环境与资源学院，浙江杭州 310029

出版日期:2009-12-05 发布日期:2009-12-05

Energy consumption of super-high-rate anaerobic bioreactor

CHEN Xiaoguang;ZHENG Ping;TANG Chongjian;ZHANG Lei

Online:2009-12-05 Published:2009-12-05

摘要/Abstract

摘要：

采用厌氧颗粒污泥和实验室模拟产气，研究了超高效厌氧生物反应器的能耗特征，建立了反应器分离单元、反应单元、布水单元以及反应器整体能耗模型。各能耗模型的模拟值与实测值吻合较好，可用于指导同类反应器能耗状况的优化。测定结果表明：反应器整体能耗的最大值为110.56×10^-4W，其中反应单元占83.0%，布水单元占17.0%，分离单元能耗可忽略不计。气液固三相时反应单元的能耗大于液固两相时的能耗。低表观液速时反应单元的能耗大于布水单元的能耗;反之，高表观液速时布水单元的能耗大于反应单元的能耗。反应器整体能耗对各参数的敏感性依次为ρ_p、u_l、V_p、u_g和d_p。

关键词:

超高效, 厌氧反应器, 能耗特征, 能耗模型, 灵敏度分析

Abstract:

The characteristics of energy consumption of the super-high-rate anaerobic bioreactor were investigated by using anaerobic granular sludge and simulated gas produced in the laboratory.Energy consumption models for the separation unit，reaction unit，water distribution unit and the whole reactor were established.The predictions from these models agreed well with the experimental data，and therefore the models can be used to optimize the energy consumption of the same kind of reactor.The maximum energy consumption in the whole reactor was 110.56×10^-4W，in which energy consumption of the reaction unit accounted for 83.0%，that of the water distribution unit accounted for 17.0%，and that of the separation unit was negligible.The energy consumption of the reaction unit of gas-fluid-solid three-phase was more than that of fluid-solid two-phase.As for the whole reactor，the energy consumption of the reaction unit was more than that of the water distribution unit at a low superficial liquid velocity.On the contrary，the energy consumption of the water distribution unit was more than that of the reaction unit at a high superficial liquid velocity.From parametric sensitivity analyses，the energy consumption of the whole reactor was significantly influenced by ρ_p，u_l，V_p，u_g and d_p.

Key words:

超高效, 厌氧反应器, 能耗特征, 能耗模型, 灵敏度分析

陈小光, 郑平, 唐崇俭, 张蕾. 超高效厌氧生物反应器能耗特征 [J]. 化工学报, 2009, 60(12): 3097-3103.

CHEN Xiaoguang, ZHENG Ping, TANG Chongjian, ZHANG Lei. Energy consumption of super-high-rate anaerobic bioreactor[J]. CIESC Journal, 2009, 60(12): 3097-3103.

[1]	韩红桂, 张璐, 乔俊飞. 基于多目标粒子群算法的污水处理智能优化控制[J]. 化工学报, 2017, 68(4): 1474-1481.
[2]	韩红桂, 张璐, 乔俊飞. 一种基于自适应回归核函数的污水处理能耗模型[J]. 化工学报, 2016, 67(3): 947-953.
[3]	公衍海, 张威, 熊智华. 基于锌电解过程机理模型的酸锌浓度控制策略[J]. 化工学报, 2013, 64(12): 4396-4400.
[4]	余亚琴, 吕锡武, 李靖. 改进型外循环厌氧反应器处理蓝藻启动与颗粒污泥特征[J]. 化工学报, 2013, 64(11): 4203-4209.
[5]	陆慧锋，郑平，张萌，张吉强，丁爽. 高浓度制药废水毒性与SPAC反应器运行性能[J]. 化工学报, 2012, 63(5): 1558-1565.
[6]	季军远, 邢雅娟, 郑平. 分段组合式厌氧生物反应器流态特性[J]. 化工学报, 2012, 63(10): 3045-3051.
[7]	任佳, 张益波, 高金凤, 潘海鹏, 戴文战. 热定型过程能耗建模及PSO参数优化[J]. 化工学报, 2011, 62(8): 2206-2211.
[8]	刘永红1,2，周孝德1，贺延龄3. 高效厌氧反应器流态与颗粒污泥流体力学特性研究进展 [J]. CIESC Journal, 2010, 29(1): 163-.
[9]	周雪飞, 张亚雷, 张选军, 蒋明. 新型外循环厌氧反应器污泥沉降的数值模拟 [J]. 化工学报, 2009, 60(3): 738-743.
[10]	胡茂冬, 周雪飞, 张亚雷, 施炜. 活性污泥法脱氮除磷工艺优化设计的灵敏度分析 [J]. 化工学报, 2009, 60(12): 3130-3136.
[11]	苏鸿洋, 夏雪芬, 张亚雷, 周雪飞. 常温下ABR反应器处理低浓度有机废水降解动力学 [J]. 化工学报, 2009, 60(10): 2614-2620.