污泥炭生物滴滤池除臭性能及其微生物机制研究

doi:10.3969/j.issn.1000-5641.2026.01.009

摘要/Abstract

摘要：

恶臭已成为制约污水处理厂可持续发展的关键瓶颈, 生物滴滤池 (Biological Trickling Filters, BTFs) 因能耗低、易维护被广泛采用, 但其除臭性能高度依赖填料特性. 以竹炭填料作为对照组, 系统评估了市政污泥热解炭 (污泥炭) 填料的除臭性能, 并比较了二者在常温 (25℃) 和相对低温 (15℃) 条件下对NH₃、H₂S及臭气浓度的去除效果. 同时, 结合微生物高通量测序分析, 揭示了污泥炭除臭的微生物机制. 研究结果表明: 污泥炭BTF在25℃条件下, 对NH₃、H₂S和臭气浓度的去除率分别达到88.4%、96.1%和87.8%, 与竹炭除臭水平基本相当; 当温度降低至15℃条件下, 污泥炭BTF的除臭效果相较于竹炭平均降低6.3%. 此外, 微生物解析表明污泥炭中富集的马赛菌属 (Massilia) 和微枝形杆菌属 (Microvirga) 等反硝化-硫氧化菌通过gln、glt基因驱动的谷氨酸合成途径与dsr、sox基因驱动的硫自养反硝化途径协同降解恶臭组分. 综合分析表明, 污泥炭可替代高成本竹炭作为BTF除臭填料, 不仅为BTF低成本除臭提供新视角, 而且也为市政污泥资源化提供了新途径.

关键词: 生物滴滤池, 污泥炭, 除臭, 微生物群落结构, 功能基因

Abstract:

Odor emissions have become a critical bottleneck restricting the sustainable development of municipal wastewater treatment plants. Biological trickling filters (BTFs) are widely adopted because of their low energy consumption and ease of maintenance, yet their deodorization performance depends greatly on the characteristics of the packing material. Using bamboo charcoal as the control, this study systematically evaluated the deodorization performance of municipal sludge pyrolysis char (sludge char) as a BTF packing material and compared the removal efficiencies of NH₃, H₂S, and odor concentration under ambient (25℃) and relatively low (15℃) temperatures. Utilizing high-throughput sequencing analysis, the microbial mechanism of sludge char deodorization was revealed. The results showed that, the removal rates at 25℃ of NH₃, H₂S, and odor concentration by the sludge-char BTF reached 88.4%, 96.1%, and 87.8%, respectively, which were essentially equivalent to the rates of bamboo charcoal. When the temperature was decreased to 15℃, the deodorization efficiency of the sludge-char BTF was reduced by an average of 6.3% compared to that of bamboo charcoal. Furthermore, microbial analysis indicated that denitrifying sulfur-oxidizing bacteria enriched in the sludge char, such as Massilia and Microvirga, synergistically degraded odor components through the glutamate synthesis pathway driven by gln and glt genes, coupled with the sulfur-autotrophic denitrification pathway mediated by dsr and sox genes. The comprehensive analysis demonstrates that sludge char can replace high-cost bamboo charcoal as a BTF packing materia, providing not only a new perspective for low-cost deodorization in BTFs but also a novel approach for the resource utilization of municipal sludge.

Key words: biotrickling filter, sludge char, deodorization, microbial community structure, functional gene

中图分类号:

TU991

孙晓. 污泥炭生物滴滤池除臭性能及其微生物机制研究[J]. 华东师范大学学报（自然科学版）, 2026, 2026(1): 99-109.

Xiao SUN. Deodorization performance and microbial mechanisms of sludge-char packed biological trickling filter[J]. J* E* C* N* U* N* S*, 2026, 2026(1): 99-109.

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生物炭	比表面积/(m²/g)	总孔容/(cm³/g)	平均孔径/nm
污泥炭	15.59	0.029	7.47
竹炭	365.76	0.160	3.28

生物炭	元素含量/%
生物炭	C	H	O	N	S
污泥炭	18.79	1.20	19.79	3.17	4.12
竹炭	82.45	1.92	10.44	0.94	0.12

样品	Sobs	Shannon	Simpson	Ace	Chao	Coverage
污泥炭 (15℃)	140	3.762	0.055	144	143	0.99
竹炭 (15℃)	206	2.720	0.168	216	209	0.99
污泥炭 (25℃)	154	4.562	0.037	162	159	0.99
竹炭 (25℃)	258	3.167	0.127	266	262	0.99