影响食物垃圾中温厌氧消化产甲烷和系统回收的因素。

IF 2 4区环境科学与生态学 Q3 ENVIRONMENTAL SCIENCES

Environmental Technology Pub Date : 2025-09-05 DOI:10.1080/09593330.2025.2551908

Yujun Ma, Shuo Yang, Hongbo Wang, Mei Li, Liping Qiu

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引用次数: 0

摘要

食物垃圾（FW）具有很高的生产潜力，可以在厌氧消化（AD）过程中以沼气形式转化为可再生能源。在中温消化（37°）条件下进行了批量试验，以评估不同投加比（10-35%）、盐类（0-20 g·L-1）和含油量（0-20 g·L-1）对AD过程中甲烷（CH4）产量、工艺稳定性和有机还原的影响。结果表明，CH4用量比为20%时效果最佳，而CH4用量比为> ~ 30%时抑制效果最佳。盐（-1）提高了AD效率，在CH4产量314.75 mL g VS-1 （1 g·L-1盐）时达到峰值，而> 15 g·L-1盐抑制了甲烷生成。15 g·L-1的油在消化12 d后甲烷产率最高（393.66 mL氯化铵产量g VS-1），而20 g·L-1的油则产生抑制作用。过高的有机负荷率（OLR）（>3.0 g VS/L/d）触发挥发性脂肪酸(VFAs) > 20000 mg/L的积累，酸化pH = 5.94，导致沼气生产崩溃；通过调整pH值、饥饿和接种污泥进行恢复，使VFAs减少96-100%，在中性pH = 7.35、甲烷含量为65%的条件下，恢复稳定的沼气产量（0.63-2.09 L/L/d）。微生物协同作用和VFA降解确保了系统在安全OLR≤3.0 g VS/L/d下的弹性，突出了FW可再生能源回收的可行性。

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Factors affecting methane production and system recovery in mesophilic anaerobic digestion of food waste.

Food waste (FW) has high production potential that can be converted into renewable energy in the form of biogas during anaerobic digestion (AD). Batch tests under mesophilic (37°) disgestion were performed to evaluate the effects of different dosage ratios (10-35%), salts (0-20 g·L^-1) and oil content (0-20 g·L^-1) on methane (CH₄) production, process stability and organic reduction during the AD. The results showed that optimal CH₄ occurred at a dosage ratio of 20%, while ratios > 30% caused inhibition. Salt (<5 g·L^-1) enhanced AD efficiency, peaking at 314.75 mL CH₄ production g VS^-1 (1 g·L^-1 salt), whereas > 15 g·L^-1 salt suppressed methanogenesis. Oil at 15 g·L^-1 maximized methane yield (393.66 mL CH₄ production g VS^-1) with 12-day digestion, while 20 g·L^-1 oil induced inhibition. Excessive organic loading rate (OLR) (>3.0 g VS/L/d) triggered the accumulation of Volatile Fatty Acids (VFAs) > 20,000 mg/L and an acidification pH = 5.94, collapsing biogas production; recovery via pH adjustment, starvation, and sludge inoculation reduced VFAs by 96-100%, restoring stable biogas output (0.63-2.09 L/L/d) with neutral pH = 7.35 and 65% methane content. Microbial synergy and VFA degradation ensured system resilience under safe OLR ≤ 3.0 g VS/L/d, highlighting FW's viability for renewable energy recovery.

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来源期刊

Environmental Technology 环境科学-环境科学

CiteScore

6.50

自引率

3.60%

发文量

审稿时长

4 months

期刊介绍： Environmental Technology is a leading journal for the rapid publication of science and technology papers on a wide range of topics in applied environmental studies, from environmental engineering to environmental biotechnology, the circular economy, municipal and industrial wastewater management, drinking-water treatment, air- and water-pollution control, solid-waste management, industrial hygiene and associated technologies. Environmental Technology is intended to provide rapid publication of new developments in environmental technology. The journal has an international readership with a broad scientific base. Contributions will be accepted from scientists and engineers in industry, government and universities. Accepted manuscripts are generally published within four months. Please note that Environmental Technology does not publish any review papers unless for a specified special issue which is decided by the Editor. Please do submit your review papers to our sister journal Environmental Technology Reviews at http://www.tandfonline.com/toc/tetr20/current