Beijing Key Laboratory of Bioprocess Laboratory, Beijing University of Chemical Technology, Beijing 100029, PR China.
Bioresour Technol. 2013 Oct;145:10-6. doi: 10.1016/j.biortech.2013.03.030. Epub 2013 Mar 15.
To avoid the inhibition from both of waste oil and high concentrations of cationic elements, anaerobic digestion of food waste in a dual solid-liquid (ADSL) system was examined in this present paper. Results from batch test indicated that a higher methane yield could be obtained in the ADSL system. The methane yield of food solid waste (FSW), food liquid waste (FLW) and raw food waste (RFW) were 643, 659 and 581 mL/g-VS, respectively. In semi-continuous anaerobic digestion, the optimum organic loading rates (OLR) for FSW, FLW and RFW were 9, 4 and 7 g-VS/L/d, respectively. The total methane production of RFW and ADSL systems, based on 1 kg-VS(RFW), were 405 and 460 L, respectively, indicating that the methane production increased by 13.6% in the ADSL system. The optimum C/N ratio, redistribution of metal element and lower content of waste oil in FSW explain the higher methane production.
为避免废油和高浓度阳离子元素的抑制作用,本研究采用双固-液(ADSL)系统对食物垃圾进行厌氧消化。批处理试验结果表明,ADSL 系统可获得更高的甲烷产量。食物固废(FSW)、食物液废(FLW)和原始食物垃圾(RFW)的甲烷产量分别为 643、659 和 581 mL/g-VS。在半连续厌氧消化中,FSW、FLW 和 RFW 的最佳有机负荷率(OLR)分别为 9、4 和 7 g-VS/L/d。基于 1 kg-VS(RFW),RFW 和 ADSL 系统的总甲烷产量分别为 405 和 460 L,表明 ADSL 系统中的甲烷产量增加了 13.6%。FSW 中较高的甲烷产量可归因于最佳 C/N 比、金属元素再分配和较低的废油含量。