陈晨伟, 彭柳城, 丁榕, 黄智健, 易静, 杨福馨, 谢晶. 制备工艺参数对菌丝体生物质材料性能的影响[J]. 农业工程学报, 2022, 38(22): 183-189. DOI: 10.11975/j.issn.1002-6819.2022.22.020
    引用本文: 陈晨伟, 彭柳城, 丁榕, 黄智健, 易静, 杨福馨, 谢晶. 制备工艺参数对菌丝体生物质材料性能的影响[J]. 农业工程学报, 2022, 38(22): 183-189. DOI: 10.11975/j.issn.1002-6819.2022.22.020
    Chen Chenwei, Peng Liucheng, Ding Rong, Huang Zhijian, Yi Jing, Yang Fuxin, Xie Jing. Effects of preparation process parameters on the properties of mycelium biomass materials[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2022, 38(22): 183-189. DOI: 10.11975/j.issn.1002-6819.2022.22.020
    Citation: Chen Chenwei, Peng Liucheng, Ding Rong, Huang Zhijian, Yi Jing, Yang Fuxin, Xie Jing. Effects of preparation process parameters on the properties of mycelium biomass materials[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2022, 38(22): 183-189. DOI: 10.11975/j.issn.1002-6819.2022.22.020

    制备工艺参数对菌丝体生物质材料性能的影响

    Effects of preparation process parameters on the properties of mycelium biomass materials

    • 摘要: 为获得菌丝体生物质材料优化性能的最佳工艺参数,该研究以最小缓冲系数和弯曲强度为评定指标,通过3因素3水平正交试验研究了菌种接种量、基质颗粒度和水添加量对平菇菌丝体材料性能的影响。研究结果表明,正交试验9组菌丝体材料中菌丝平均直径最大为1 641 nm,最小为520 nm,前者后者的3.16倍,表明不同工艺参数显著(P<0.05)影响菌丝生长状态。影响菌丝体材料力学性能的最大因素是基质颗粒度,其次是水添加量和接种量。最佳工艺参数为接种量10%、基质颗粒度10 mm和水添加量60%,对应菌丝体材料的最小缓冲系数最低为4.17、弯曲强度最大为417.43 kPa,与发泡聚苯乙烯泡沫的弯曲强度相近。研究结果可为菌丝体材料制备工艺参数与性能的优化提供基础。

       

      Abstract: Abstract: Biodegradable packaging materials have received widespread attention in recent years. The reason is that non-biodegradable packaging materials have caused serious environmental and human health issues during disposal after mass production. Fortunately, the mycelium material can be expected to serve as one of the promising biodegradable materials. In this study, the mycelium biomass material was cultivated to determine the effect of preparation process parameters on mechanical properties. Pleurotus ostreatus was selected to inoculate in a culture substrate, including the wood chips, cotton seed hulls, corn cobs, wheat bran, lime, and gypsum. The process parameters were then optimized for the properties of mycelium biomass material. After that, a three-factor and the three-level orthogonal test was carried out to investigate the three process parameters (inoculum amounts, particle size of substrate, and water addition) using the minimum cushioning coefficient and bending strength as the evaluation indexes. The maximum and minimum average diameters of mycelium were 1 641 and 520 nm, indicating the significant influence of different process parameters on the growth state of mycelium. The influencing factors were ranked in descending order of the particle size of the substrate, followed by the water addition, and inoculum amount. The bending resistance and buffering effect of mycelium material decreased as the particle size of the substrate decreased, due to the reduced internal space of substrate material. The low growth of mycelium and adherence between the substrates was attributed to the limited deformation space of material for less air circulation. The best bending resistance and buffering efficiency were achieved in the amount of water addition of 60%. As such, the bonding between the substrate inside the material depended mainly on the amount of water addition. The better mechanical properties were obtained in the relatively strong bonding, where the metabolism and growth of mycelium with suitable water was a benefit to wrapping the substrate. By contrast, the air circulation was reduced, where too much water filled the internal void in the material. The needed oxygen and metabolic carbon dioxide were not exchanged during the mycelium growth in time, leading to the low bending strength and buffering performance of the mycelium material without growth. The best bending resistance and buffering efficiency were achieved in the optimal inoculum of 10%. Once the inoculum was too low, the strains have limited contact with the substrate area, resulting in a limited area for colonization and growth. The insufficient mycelium growth reduced the bonding between substrates, leading to a decrease in the bending strength of mycelium material. A high inoculum greatly contributed to the strains competing with each other for the nutrient source, leading to the limited growth of mycelium in all strains. The optimum process parameters were optimized for the inoculum amounts of 10%, the particle size of substrate 10 mm, and water addition of 60%, corresponding to the minimum cushioning coefficient of 4.17 and the highest bending strength of 417.43 kPa of the mycelium material. Therefore, the bending strength of mycelium material was comparable to that of expanded polystyrene foam. But, the cushioning performance was less than that of expanded polystyrene foam. Three process parameters can be expected to further optimize the growth of mycelium, particularly for the better mechanical properties of the mycelium material. This finding can provide a strong reference to optimize the preparation process parameters and mechanical properties of mycelium biomass material.

       

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