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DENG Jie, WEI Yuquan, WANG Yuyun, ZHANG Kui, ZHAN Yabin, CHANG Yuan, TAO Yueyue, WANG Haihou, XU Zhi, LI Ji. EFFECTS OF OIL ON HUMIFICATION PROCESS OF AEROBIC COMPOSTING OF KITCHEN WASTE[J]. ENVIRONMENTAL ENGINEERING , 2024, 42(6): 111-118. doi: 10.13205/j.hjgc.202406013
Citation: DENG Jie, WEI Yuquan, WANG Yuyun, ZHANG Kui, ZHAN Yabin, CHANG Yuan, TAO Yueyue, WANG Haihou, XU Zhi, LI Ji. EFFECTS OF OIL ON HUMIFICATION PROCESS OF AEROBIC COMPOSTING OF KITCHEN WASTE[J]. ENVIRONMENTAL ENGINEERING , 2024, 42(6): 111-118. doi: 10.13205/j.hjgc.202406013

EFFECTS OF OIL ON HUMIFICATION PROCESS OF AEROBIC COMPOSTING OF KITCHEN WASTE

doi: 10.13205/j.hjgc.202406013
  • Received Date: 2023-06-24
    Available Online: 2024-07-11
  • As an important component of kitchen waste, oil has an important influence on kitchen waste composting. In this study, 0% (T1), 3% (T2), 6% (T3), and 12% (T4) vegetable oil were added to the kitchen waste for aerobic composting. The amount of oil added was based on the dry weight of the kitchen waste added to the compost. The effects of oils on the humification of kitchen waste aerobic composting were studied by characterizing the changes in physical and chemical properties, humic acid components, and humic acid precursors in the composting process. The results showed that: After 30 days of aerobic composting of the kitchen waste with different concentrations of oil, the compost of different treatment groups reached the requirements of decomposition, and the highest temperature was 70.9 ℃, 64.8 ℃, 65 ℃ and 67.2 ℃, respectively. The high-temperature period of compost reached more than 7 days. The germination rates of seeds were 119.22%, 113.50%, 114.03%, and 120.52%, respectively. In the T2, T3, and T4 treatment groups, oil accumulation occurred at high temperatures, and the highest oil content was 1.66 times, 1.99 times, and 1.76 times the initial oil content. On the 30th day of composting, the HA/FA ratio of the four treatment groups was 0.55, 0.70, 0.80, and 1.30, respectively. The HA/FA ratio was the highest when the oil content was 12%, indicating that the humification degree of compost was the strongest when the oil content was 12%. Adding 12% oil can prolong the high-temperature period of compost and promote the formation of precursors, thus promoting the humification process of compost. The results of redundancy analysis showed that the content of oil was positively correlated with the formation of humic acid precursors and humus components. In conclusion, when the oil content is 12% of the dry weight of food waste, the degradation of oil has the best effect on the humification process of kitchen waste aerobic compost.
  • [1]
    任海静,马一祎,王攀.我国城市餐厨垃圾处理与再生利用技术发展分析[J].建设科技,2021(17):26-30.
    [2]
    常燕青,黄慧敏,赵振振,等.餐厨垃圾资源化处理与高值化利用技术发展展望[J].环境卫生工程,2021,29(1):44-51.
    [3]
    胡新军,张敏,余俊锋,等.中国餐厨垃圾处理的现状、问题和对策[J].生态学报,2012,32(14):4575-4584.
    [4]
    姜虎, 李文哲, 刘建,等. 城市餐厨垃圾资源化利用的问题和对策[J]. 环境科学与管理, 2010,35(6):27-31.
    [5]
    王森,张卡,王泳浩,等.一株油脂降解菌的筛选鉴定及降解效果分析[J].生物技术进展,2021,11(1):99-10.
    [6]
    任连海,黄燕冰,王攀,等.含油率对餐厨垃圾干式厌氧发酵的影响[J]..环境科学学报,2015,35(8):2534-2539.
    [7]
    邓蒙轩,周爱娟,万方,等.优化餐厨垃圾乳化液深度去油方案[J].科学技术与工程,2020,20(4):1704-1710.
    [8]
    符歆灏. 高效油脂降解菌的筛选及脂肪酶性质研究[D]. 上海:上海师范大学,2021.
    [9]
    康燕莉,孟宪刚,李纲,等.1株高效油脂降解菌的筛选鉴定及其特性研究[J].安徽农业科学,2013,41(9):4077-4079.
    [10]
    詹亚斌,魏雨泉,陶兴玲,等.耐高温油脂降解菌株的筛选、鉴定及其在好氧堆肥中的应用[J].环境污染与防治,2021,43(7):812-818.
    [11]
    薛晶晶,李彦明,常瑞雪,等.厨余与园林废物共堆肥过程氮素转化及损失[J].农业工程学报,2021,37(10):192-197.
    [12]
    李孟婵,张鹤,杨慧珍,等.不同原料好氧堆肥过程中碳转化特征及腐殖质组分的变化[J].干旱地区农业研究,2019,37(2):81-87

    ,94.
    [13]
    ZHANG Z C, ZHAO Y, WANG R X, et al. Effect of the addition of exogenous precursors on humic substance formation during composting[J].Waste Management 2018,79:462-471.
    [14]
    ZHOU X, LI J, ZHANG J, et al. Bioaugmentation mechanism on humic acid formation during composting of food waste[J].Science of the Total Environment, 2022,830:154783.
    [15]
    卢方圆,王若兰,涂燕林,等.藜麦储藏期间多酚含量变化及稳定性研究[J].粮食与油脂,2022,35(5):91-96

    ,102.
    [16]
    李季,彭生平.堆肥工程实用手册[M].北京:化学工业出版社,2011.
    [17]
    NY/T 525—2021, 有机肥料[S].北京:北京农业出版社,2021.
    [18]
    张建华,田光明,姚静华.不同调理剂对猪粪好氧堆肥效果的影响[J].水土保持学报,2012,26(3):131-135.
    [19]
    AMIR S, HAFIDI M, MERLINA G, et al. Structural characterization of fulvic acids during composting of sewage sludge[J].Process Biochemistry, 2005,40(5):1693-1700.
    [20]
    FOURTI O, JEDIDI N, HASSEN A. Humic substances change during the co-composting process of municipal solid wastes and sewage sludge[J]. World Journal of Microbiology and Biotechnology, 2010,26(12):2117-2122.
    [21]
    ZHAO X Y, TAN W B, PENG J J, et al. Biowaste-source-dependent synthetic pathways of redox functional groups within humic acids favoring pentachlorophenol dechlorination in composting process[J].Environment International, 2020,135:105380.
    [22]
    徐成,刘国涛,王政,等.添加腐熟堆肥对厨余垃圾堆肥腐殖质形成的影响[J].环境科学与技术,2020,43(8):122-127.
    [23]
    潘根兴,丁元君,陈硕桐,等. 从土壤腐殖质分组到分子有机质组学认识土壤有机质本质[J].地球科学进展, 2019,34(5):451-470.
    [24]
    MINH TRAN Q N, MIMOTO H, KOYAMA M, et al. Lactic acid bacteria modulate organic acid production during early stages offood waste composting[J]. Science of the Total Environment,2019, 687:341-347.
    [25]
    MA J, FENG S, WANG Z Z, et al. Pyrolysis characteristics of biodried products derived from municipal organic wastes: synergistic effect of bulking agents and modification of biodegradation[J]. Environmental Research,2021,206:112300.
    [26]
    LEMUS G R, LAU A K. Biodegradation of lipidic compounds in synthetic food wastes during composting[J].Canadian Biosystems Engineering/Le Genie des Biosystems au Canada,2002,44(6):33-36.
    [27]
    任连海,王攀,贺艳坤.含油量对餐厨垃圾好氧堆肥的影响[J].建设科技,2013(8):50-53.
    [28]
    OSKARS B, TATIANA D, GALINA T. Characterisation of humic substances formed during co-composting of grass and wood wastes with animal grease[J]. Environmental Technology,2012,33:12,1427-1433.
    [29]
    TAN K H. Humic matter in soil and the environment: principles and controversies[M]. Boca Raton: CRC Press, 2003.
    [30]
    STEVENSON F J. Humus chemistry: genesis, composition, reactions[M]. John Wiley & Sons, 1994.
    [31]
    ORLOV D S. Humic substances of soils and general theory of humification[M]. Boca Raton: CRC Press, 2020.
    [32]
    ZHANG Y C, YUE D B, MA H. Darkening mechanism and kinetics of humification process in catechol-Maillard system[J]. Chemosphere, 2015, 130: 40-45.
    [33]
    ONWOSI C O, IGBOKWE V C, ODIMBA J N, et al. Composting technology in waste stabilization: on the methods, challenges and future prospects[J]. Journal of Environmental Management, 2017, 190: 140-157.
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