Sludge disintegration through advanced rotational hydrodynamic cavitation reactor for improvement of biogas production

IF 7.2 2区工程技术 Q1 ENGINEERING, CHEMICAL Journal of Environmental Chemical Engineering Pub Date : 2025-03-10 DOI:10.1016/j.jece.2025.116116

Hyungjoon Son , Sungyoun Na , Ming Guo , Dang Khoi Le , Joon Yong Yoon , Xun Sun

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Abstract

Sustainable sludge management in wastewater treatment plants (WWTPs) is vital. This study evaluated an advanced rotational hydrodynamic cavitation reactor (ARHCR) for its impact on anaerobic digestion (AD). Sludge was treated under varying rotational speeds, inlet pressures, and pressure drops, followed by biochemical methane potential (BMP) tests to assess AD performance. The results demonstrated the significant biogas yield improvement (14.4 % to 96.5 %) due to effective sludge disintegration, with rotational speed being the most influential factor. Lower-severity conditions may maximize profits by reducing bio-refractory substance formation. A comparative analysis demonstrated the ARHCR’s scalability advantage, particularly due to its effective hydrodynamic cavitation generation. Additionally, dimensional analysis confirmed its scale-up potential over similar reactors. An energy balance study revealed a 20 % increase in energy efficiency for AD with the ARHCR, supporting its feasibility as an efficient and sustainable sludge treatment solution. These findings highlight the ARHCR’s potential for enhancing WWTP sustainability.

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采用先进旋转流体动力空化反应器进行污泥分解，提高沼气产量

污水处理厂（WWTPs）的可持续污泥管理至关重要。本研究评估了一种先进的旋转流体动力空化反应器（ARHCR）对厌氧消化（AD）的影响。污泥在不同的转速、进口压力和压降下进行处理，然后进行生化甲烷势（BMP）测试，以评估AD的性能。结果表明，污泥有效分解可显著提高沼气产率（14.4 % ~ 96.5 %），其中转速是影响最大的因素。较低严重程度的条件可以通过减少生物难熔物质的形成来最大化利润。对比分析证明了ARHCR的可扩展性优势，特别是由于其有效的水动力空化产生。此外，量纲分析证实了它在类似反应堆上的放大潜力。一项能量平衡研究显示，使用ARHCR后，AD的能源效率提高了20% %，这证明了它作为一种高效、可持续的污泥处理方案的可行性。这些发现突出了ARHCR在提高污水处理厂可持续性方面的潜力。

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来源期刊

Journal of Environmental Chemical Engineering Environmental Science-Pollution

CiteScore

11.40

自引率

6.50%

发文量

2017

审稿时长

27 days

期刊介绍： The Journal of Environmental Chemical Engineering (JECE) serves as a platform for the dissemination of original and innovative research focusing on the advancement of environmentally-friendly, sustainable technologies. JECE emphasizes the transition towards a carbon-neutral circular economy and a self-sufficient bio-based economy. Topics covered include soil, water, wastewater, and air decontamination; pollution monitoring, prevention, and control; advanced analytics, sensors, impact and risk assessment methodologies in environmental chemical engineering; resource recovery (water, nutrients, materials, energy); industrial ecology; valorization of waste streams; waste management (including e-waste); climate-water-energy-food nexus; novel materials for environmental, chemical, and energy applications; sustainability and environmental safety; water digitalization, water data science, and machine learning; process integration and intensification; recent developments in green chemistry for synthesis, catalysis, and energy; and original research on contaminants of emerging concern, persistent chemicals, and priority substances, including microplastics, nanoplastics, nanomaterials, micropollutants, antimicrobial resistance genes, and emerging pathogens (viruses, bacteria, parasites) of environmental significance.