微小型反应器下嗜热微生物菌剂协同盐酸堆肥效果

doi:10.14088/j.cnki.issn0439-8114.2026.05.009

湖北农业科学 ›› 2026, Vol. 65 ›› Issue (5): 56-62.doi: 10.14088/j.cnki.issn0439-8114.2026.05.009

微小型反应器下嗜热微生物菌剂协同盐酸堆肥效果

陈文辉, 张政, 袁军委, 王羿, 林思远, 曹玉贤, 侯俊

农业农村部长江中游作物绿色高效生产重点实验室（部省共建）/涝渍灾害与湿地农业湖北省重点实验室/长江大学农学院,湖北荆州 434025

收稿日期:2025-12-24 出版日期:2026-05-25 发布日期:2026-05-26
通讯作者: 侯俊（1983-）,男,湖北襄阳人,副教授,博士,主要从事农业废弃物处理与稻渔养分综合管理等研究,（电子信箱）houjungoodluck1@163.com。
作者简介:陈文辉（2004-）,男,江西赣州人,在读本科生,专业方向为农业废弃物处理,（电子信箱）chenjdbest@163.com
基金资助:
湖北省重点研发计划项目（2025BCB078; 2023BBB082）

Synergistic effectiveness of thermophilic microbial agent with hydrochloric acid composting in micro-reactor

CHEN Wen-hui, ZHANG Zheng, YUAN Jun-wei, WANG Yi, LIN Si-yuan, CAO Yu-xian, HOU Jun

Key Laboratory of Green and Efficient Production of Crops in the Middle Reaches of the Yangtze River, Ministry of Agriculture and Rural Affairs(Co-construction by Ministry and Province)/Hubei Key Laboratory of Waterlogging Disaster and Agricultural Use of Wetland/College of Agriculture, Yangtze University, Jingzhou 434025, Hubei, China

Received:2025-12-24 Published:2026-05-25 Online:2026-05-26

摘要/Abstract

摘要： 为了考察微小型反应器下嗜热微生物菌剂协同盐酸的堆肥效果,在微小型反应器堆肥的条件下采用好氧堆肥方式,设置4个处理,分别为添加物料鲜重1.5%的常规发酵菌剂（CK）、添加物料鲜重1.5%的常规发酵菌剂且每千克物料添加0.03 mol H⁺（CKA）、添加物料鲜重2.0%的嗜热微生物菌剂（TMF）、添加物料鲜重2.0%的嗜热微生物菌剂且每千克物料添加0.03 mol H⁺（TMFA）,发酵周期为21 d,探究嗜热微生物菌剂协同盐酸堆肥下氮素转化特征与腐熟效果。结果表明,嗜热微生物菌剂可提高堆体温度,最高达55.35 ℃,并提高堆体含水率;17 d时各处理种子发芽指数均大于70%,达到完全腐熟状态。与CK相比,TMFA可显著降低堆体pH和电导率,并显著增加55.52%的硝态氮含量（P<0.05）,但全氮和全碳损失分别显著增加42.59%和42.19%（P<0.05）。常规发酵菌剂下添加盐酸增加8.35%的全氮含量,而嗜热微生物菌剂下添加盐酸增加2.99%的全氮含量且显著增加15.36%的全碳含量（P<0.05）。各处理氨气累积排放量无显著差异（P>0.05）。

关键词: 堆肥, 畜禽粪便, 嗜热微生物菌剂, 添加剂, 盐酸, 微小型反应器, 碳氮损失, 腐熟

Abstract: In order to investigate the composting effect of the thermophilic microbial agent combined with hydrochloric acid in the micro-reactor, the aerobic composting method was used under the condition of micro-reactor composting. Four treatments were set up, which were conventional fermentation agent at 1.5% of fresh material weight (CK), conventional fermentation agent at 1.5% of fresh material weight with 0.03 mol H⁺ per kilogram of material (CKA), thermophilic microbial agent at 2.0% of fresh material weight (TMF), and thermophilic microbial agent at 2.0% of fresh material weight with 0.03 mol H⁺ per kilogram of material (TMFA). The fermentation period was 21 days to explore the nitrogen transformation characteristics and maturity effect of the thermophilic microbial agent combined with hydrochloric acid composting. The results showed that the thermophilic microbial agent could increase the temperature of the pile, up to 55.35 ℃, and increase the moisture content of the pile. At 17 d, the seed germination index of each treatment was greater than 70%, reaching a completely decomposed state. Compared with CK, TMFA significantly reduced the pH and electrical conductivity of the pile, and significantly increased the nitrate nitrogen content by 55.52% (P<0.05), but the total nitrogen and total carbon losses were significantly increased by 42.59% and 42.19%, respectively(P<0.05). The addition of hydrochloric acid under the conventional fermentation agent increased the total nitrogen content by 8.35%, while the addition of hydrochloric acid under the thermophilic microbial agent increased the total nitrogen content by 2.99% and significantly increased the total carbon content by 15.36% (P<0.05). There was no significant difference in the cumulative emission of ammonia in each treatment (P>0.05).

Key words: composting, livestock manure, thermophilic microbial agent, additive, hydrochloric acid, micro-reactor, carbon and nitrogen loss, maturation

中图分类号:

S141.4

陈文辉, 张政, 袁军委, 王羿, 林思远, 曹玉贤, 侯俊. 微小型反应器下嗜热微生物菌剂协同盐酸堆肥效果[J]. 湖北农业科学, 2026, 65(5): 56-62.

CHEN Wen-hui, ZHANG Zheng, YUAN Jun-wei, WANG Yi, LIN Si-yuan, CAO Yu-xian, HOU Jun. Synergistic effectiveness of thermophilic microbial agent with hydrochloric acid composting in micro-reactor[J]. HUBEI AGRICULTURAL SCIENCES, 2026, 65(5): 56-62.

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微小型反应器下嗜热微生物菌剂协同盐酸堆肥效果

Synergistic effectiveness of thermophilic microbial agent with hydrochloric acid composting in micro-reactor

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