Pilot scale study of anaerobic treatment of food waste using ambient and solar heated digesters

IF 2 Q4 ENERGY & FUELS International Journal of Sustainable Energy Pub Date : 2023-11-29 DOI:10.1080/14786451.2023.2275818

S. Khune, Benton Onyango Otieno, J. Kabuba, George Ochieng, Peter Osifo

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Abstract

ABSTRACT Food waste (FW) is high in nutrients and has gained global attention as an ideal substrate for bioenergy recovery through anaerobic digestion (AD). Ambient digesters have been widely used because of their ease of installation, low cost, and low energy input. However, to improve biogas production sustainably, there is a need to consider reactor heating using renewable energy such as solar. This study sought to apply psychrophilic and mesophilic biodigester temperatures for FW treatment. For ambient digestion, a complete-mix flexible biodigester, named STH-1000A, covered in a greenhouse structure was operated between 24 and 32 °C. A prototype complete-mix tank biodigester, named VUT-1000C, was designed and operated at mesophilic conditions of 37 °C through solar geyser heating. VUT-1000C produced 1200 L of biogas per day while STH-1000A 150 L/day. VUT-1000C and STH-1000A generated up to 1.8 and 0.4 kWh of electricity, respectively. The power balance showed that VUT-1000C used 68% of its power production and STH-1000A consumed 398%. Digester heating using solar geyser is a novel and promising technique for achieving mesophilic condition leading to improved biogas production.

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利用常温沼气池和太阳能加热沼气池厌氧处理厨余垃圾的试验性研究

摘要食物垃圾（FW）营养成分高，是通过厌氧消化（AD）回收生物能源的理想基质，因此受到全球关注。常温沼气池因其易于安装、成本低、能源投入少而被广泛使用。然而，为了可持续地提高沼气产量，有必要考虑利用太阳能等可再生能源对反应器进行加热。本研究试图将亲水和中亲水生物发酵池温度用于处理 FW。为了进行常温消化，一个名为 STH-1000A 的全混合柔性生物发酵罐在 24 至 32 °C之间运行，该生物发酵罐覆盖在温室结构中。设计了一个名为 VUT-1000C 的完全混合槽生物发酵罐原型，通过太阳能喷泉加热，在 37 ℃ 的中嗜酸条件下运行。VUT-1000C 每天产生 1200 升沼气，而 STH-1000A 每天产生 150 升沼气。VUT-1000C 和 STH-1000A 的发电量分别为 1.8 千瓦时和 0.4 千瓦时。电力平衡显示，VUT-1000C 使用了其发电量的 68%，而 STH-1000A 消耗了 398%。利用太阳能喷泉对沼气池进行加热是一种新颖而有前途的技术，可实现中温条件，从而提高沼气产量。

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来源期刊

International Journal of Sustainable Energy ENERGY & FUELS-

CiteScore

5.70

自引率

3.20%

发文量

期刊介绍： Engineering and sustainable development are intrinsically linked. All capital plant and every consumable product depends on an engineering input through design, manufacture and operation, if not for the product itself then for the equipment required to process and transport the raw materials and the final product. Many aspects of sustainable development depend directly on appropriate and timely actions by engineers. Engineering is an extended process of analysis, synthesis, evaluation and execution and, therefore, it is argued that engineers must be involved from the outset of any proposal to develop sustainable solutions. Engineering embraces many disciplines and truly sustainable solutions are usually inter-disciplinary in nature.