锯末添加量对餐厨废弃物生物干化效率和细菌群落的影响

    Effects of sawdust addition on bio-drying efficiency and bacterial community of food waste

    • 摘要: 餐厨废弃物存在含水率高、内部孔隙率低等问题,可以通过添加辅料来改善,适宜的辅料添加量有助于促进生物干化过程有机质降解和腐殖质形成,以提高生物干化效率。锯末作为一种富含碳源且低成本的辅料之一,近年来被广泛应用于各种废弃物资源化利用的研究中,但餐厨废弃物与锯末的配比如何影响微生物群落演替进而提升生物干化效率的过程机制尚不清楚。该研究在55 L生物干化反应器中,探究餐厨废弃物与锯末湿质量比为5:1(T1)、7:1(T2)和10:1(T3)三种处理对生物干化过程中的关键理化指标(包括温度、含水率、挥发性固体含量、电导率、酸碱度、种子发芽指数、总有机碳、总氮、总磷、总钾和碳氮比等)和细菌群落结构的影响。结果表明:与T1、T3相比,T2处理高温期持续时间最久,分别延长了50.00%、100.00%,在生物干化结束时含水率最低、有机质降解率最高,水分去除率达37.14%,挥发性固体降解率为15.88%;T2的种子发芽指数比T1、T3处理分别提前3、6 d达到80%以上,且在生物干化结束时,总养分含量升高28.32%,其中总磷含量升高最为显著,升高了121.62%,约为其他处理的1.92和1.90倍,说明T2处理的物料配比更有助于堆体腐熟和提高养分含量;此外,T2处理的BacillusUreibacillusThermobifida等堆肥有益菌属的相对丰度更高,且Chao1和Shannon指数更大;相关性分析表明UreibacillusSymbiobacteriumTepidimicrobiumBacillus与堆体温度显著正相关(P<0.05),ThermobifidaPusillimonasVulgatibacterMycobacterium与种子发芽率指数显著正相关(P<0.05),与挥发性固体含量、含水率和总氮含量显著负相关(P<0.05)。餐厨废弃物和锯末的湿质量比为7:1时,水分去除和有机质降解效果最好、细菌群落丰富度尤其是堆肥有益菌属的相对丰度最高,有利于定向筛选和培养功能微生物,提高餐厨废弃物生物干化效率。

       

      Abstract: As we all know, the bio-drying of food waste has problems such as high moisture content and low internal porosity, and these conditions can be improved by adding auxiliary materials. In particular, the appropriate amount of auxiliary materials can help promote the degradation of organic matter and the formation of humus during bio-drying process, so as to improve the efficiency of bio-drying. As one of the auxiliary materials with abundant carbon source and low cost, sawdust has been widely used in the research of various waste resource utilization in recent years, but the mechanism of how the ratio of food waste and sawdust regulates the succession of microbial communities and thus improves the efficiency of bio-drying is not clear. Based on this, in our study, three treatments with a wet-weight ratio of food waste and sawdust were set up, including 5:1 (T1), 7:1 (T2) and 10:1 (T3). And we carried out experiments in a 55 L bio-drying reactor in order to explore their effects on key physicochemical indexes and bacterial community structure during bio-drying, such as temperature, moisture content (MC), volatile solids content (VS), electric conductivity (EC), seed germination index (GI), total organic carbon (TOC), total nitrogen (TN), total phosphorus (TP), total potassium (TK), carbon-nitrogen ratio (C/N), and so on. The results showed that compared with the other two treatments, the duration of the high temperature period of T2 lasted the longest, extending by 50.00% and 100.00%, respectively. And at the end of bio-drying, the removal of moisture content was the lowest, the degradation rate of organic matter was the highest, the water removal rate was 37.14%, and the degradation rate of volatile solids was 15.88%. The seed germination index of T2 reached more than 80% earlier 3 and 6 days than T1 and T3 treatments, and the total nutrient content increased by 28.32% at the end of bio-drying, among which the total phosphorus content increased the most significantly, increasing by 121.62%, which was about 1.92 and 1.90 times that of the other treatments, indicating that the material and additive ratio of T2 treatment was more conducive to promoting the maturity of the pile and increasing the nutrient content. Furthermore, the relative abundance of beneficial compost genus such as Bacillus, Ureibacillus and Thermobifida in T2 was higher, and the Chao1 and Shannon indexes were larger than that of others. Correlation analysis showed that the relative abundance of Ureibacillus, Symbiobacterium, Tepidimicrobium and Bacillus were significantly positively correlated with temperature of pile (P<0.05), the relative abundance of Thermobifida, Pusillimonas, Vulgatibacter, Mycobacterium were positively correlated with seed germination index (P<0.05), and negatively correlated with volatile solids content, moisture content and total nitrogen content (P<0.05). When the wet-weight ratio of food waste and sawdust was 7:1, the results of water removal and organic matter degradation were the best, and bacterial community richness was the highest, especially the relative abundance of beneficial bacteria in the compost. Therefore, it is beneficial for the targeted screening and cultivation of functional microorganisms, and improves the bio-drying efficiency of food waste.

       

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