Hydrogen Production via Off-Sun Solar-Thermal Supercritical Water Gasification and Membrane Reforming of Piggery Waste

SolarPACES Conference Proceedings Pub Date : 2024-02-02 DOI:10.52825/solarpaces.v1i.748

Louise Bardwell, Alireza Rahbari, John Pye

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Abstract

Supercritical water gasification (SCWG) represents an emerging technology for liquid fuel synthesis, offering large potential in significantly improving the efficiency and environmental impact of clean fuel production. Compared to conventional gasification, SCWG proceeds at much lower temperatures, allowing char and tar-free gasification of biomass and for low-quality and high-moisture content biomass to be used. As the thermochemical processes involved in SCWG and steam methane reforming (SMR) are highly endothermic, combining them with concentrated solar power (CSP) and thermal energy storage (TES) could allow the process to be driven solely by renewable energy. As such, this work models an off-sun SCWG/SMR system using novel molten salt, proposed to reach up to 600°C [1], which overcomes the previously limiting molten salt temperature of 550°C. Using an off-sun configuration, it deals with the on-sun configuration’s issues of degraded lifetime and creep-fatigue, allowing for uniform heating and a reduced load on the reactors. The novel technology of an integrated Pd-based membrane reactor, highly selective to H₂, was chosen given its ability to carry out SMR at temperatures in the viable range of new molten salts. The system uses a waste feedstock, piggery waste, to provide the dual benefit of reducing the environmental cost associated with piggery waste’s release of CH4. From the model created in Aspen Plus, a plant output of 7.2 kmolH₂/h (1,135 Nm³/h of H₂), was obtained with a flow rate of 150 kg/h of dry piggery waste, a membrane area of 131.8 m², and a 73% CH4 conversion from the feed.

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通过非太阳光热超临界水气化和猪舍废料膜转化制氢

超临界水气化（SCWG）是一种新兴的液体燃料合成技术，在显著提高清洁燃料生产的效率和环境影响方面具有巨大潜力。与传统气化技术相比，超临界水气化的温度要低得多，可以实现生物质的无炭化和无焦油气化，也可以使用低质量和高水分含量的生物质。由于 SCWG 和蒸汽甲烷重整（SMR）所涉及的热化学过程是高度内热的，因此将它们与聚光太阳能（CSP）和热能储存（TES）相结合，可使该过程完全由可再生能源驱动。因此，本研究利用新型熔盐为离太阳 SCWG/SMR 系统建模，该系统的熔盐温度最高可达 600°C [1]，克服了之前熔盐温度为 550°C 的限制。该系统采用非太阳结构，解决了太阳结构寿命缩短和蠕变疲劳的问题，实现了均匀加热，减轻了反应堆的负荷。由于能够在新型熔盐的可行温度范围内进行 SMR，因此选择了对 H₂ 具有高度选择性的集成式钯基膜反应器的新技术。该系统使用废弃原料--养猪场废弃物，具有双重优势，可降低养猪场废弃物释放 CH4 所带来的环境成本。根据在 Aspen Plus 中创建的模型，在干猪舍废料流量为 150 kg/h、膜面积为 131.8 m²、进料的 CH4 转化率为 73% 的情况下，设备输出为 7.2 kmolH₂/h（1,135 Nm³/h H₂）。

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