Coupled Biogas and Fiber Production from Agricultural Residues and Energy Crops with Steam Explosion Treatment

B. Hülsemann, Marian Baumgart, Leonhard Lenz, Elviliana, Marie Föllmer, G. Sailer, Konstantin Dinkler, H. Oechsner
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Abstract

The global demand for packaging materials and energy is constantly increasing, requiring the exploration of new concepts. In this work, we presented a bioeconomic concept that uses steam explosion and phase separation to simultaneously generate fibers for the packaging industry and biogas substrate for the energy sector. The concept focused on fiber-rich residues and fiber-rich ecological energy crops from agriculture. Feasibility of the concept in the laboratory using feedstocks, including Sylvatic silphia silage, Nettle silage, Miscanthus, Apple pomace, Alfalfa stalks, and Flax shives was confirmed. Our results showed that we were able to separate up to 26.2% of the methane potential while always extracting a smaller percentage of up to 17.3% of organic dry matter (ODM). Specific methane yields of 297–486 LCH4 kgODM−1 in the liquid and 100–286 LCH4 kgODM−1 in the solid phase were obtained. The solid phases had high water absorption capacities of 216–504% due to the steam explosion, while the particle size was not significantly affected. The concept showed high potential, especially for undried feedstock.
利用蒸汽爆破处理从农业秸秆和能源作物中耦合生产沼气和纤维
全球对包装材料和能源的需求不断增加,需要探索新的概念。在这项工作中,我们提出了一种生物经济概念,即使用蒸汽爆炸和相分离同时为包装工业生产纤维,为能源部门生产沼气基板。该概念侧重于农业中富含纤维的残留物和富含纤维的生态能源作物。该概念的可行性在实验室中使用的原料,包括森林silphia青贮,荨麻青贮,芒草,苹果渣,苜蓿秸秆和亚麻片被证实。我们的结果表明,我们能够分离高达26.2%的甲烷潜力,同时始终提取较小百分比的有机干物质(ODM),最高可达17.3%。液相和固相的甲烷比产率分别为297 ~ 486 LCH4 kgODM−1和100 ~ 286 LCH4 kgODM−1。由于蒸汽爆炸,固相具有216 ~ 504%的高吸水率,而粒径没有受到显著影响。这个概念显示出很高的潜力,特别是对于未干燥的原料。
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