Estimating the formation and thickness of a liquid layer on the surface of a packing material in biofiltration and their effects on gaseous toluene removal

Current Biochemical Engineering Pub Date : 2019-03-31 DOI:10.2174/2212711906666181120125211

Ahmad Masoud Mansooria and Takashi Higuchi

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Abstract

Packing materials, which are used in biofiltration systems treating gaseous volatile organic compounds, are expected to have optimal water content in their actual use. This is because high volume of water increases the diffusion resistance while low water content decreases microbial activity. Therefore the thickness of the liquid layer on the packing material needs to be identified to determine the mass transfer process of target pollutants. However, it cannot be measured directly due to the complicated surface structure of general packing materials. In this study, ideal biofiltration surfaces were prepared artificially by coating a plain membrane surface with mono-cultured biomass and a known thickness of liquid layer. The sorption velocity of gaseous toluene was then observed, within a considerable range of liquid thicknesses, on this biomass surface. The velocity of water vaporization from a porous PVF poly-vinyl formal (PVF) material was then measured. Finally, the relationship between thickness of liquid surface and the water content of the PVF material was calculated based on the experimental results and a set of mathematical models on vaporization. There is an appropriate range for the thickness of the water layer thickness on the biomass at the surface of packing material. In one case, this thickness was cited as approximately 0.1–0.2 mm for gaseous toluene. The PVF material was thought to form such a thick water layer at around 50–60% of its water content. The water content conditions that affect the formation of the water layer changed when biomass grew on the surface of the PVF material. The range declined from around 70% for new material to around 55% for biomass-rich material. This study quantitatively clarified the reason why there is optimal range of water content for the packing material of biofiltration; i.e., appropriate liquid layer thickness at the surface of packing materials is built by a certain range of water content.

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估计生物过滤中填料表面液体层的形成和厚度及其对去除气态甲苯的影响

用于处理气态挥发性有机化合物的生物过滤系统的包装材料，在实际使用中预计具有最佳的含水量。这是因为大量的水增加了扩散阻力，而低含水量则降低了微生物活性。因此，需要识别包装材料上液体层的厚度，以确定目标污染物的传质过程。但由于一般包装材料表面结构复杂，无法直接测量。在本研究中，通过在一个平坦的膜表面涂覆单一培养的生物质和已知厚度的液体层，人工制备了理想的生物过滤表面。然后在相当大的液体厚度范围内观察到气态甲苯在该生物质表面的吸附速度。然后测量了多孔PVF聚乙烯醇(PVF)材料的水蒸气蒸发速度。最后，根据实验结果和汽化数学模型，计算了PVF材料的液面厚度与含水率之间的关系。填料表面生物质上的水层厚度有一个合适的范围。在一种情况下，该厚度被引用为约0.1-0.2毫米的气体甲苯。PVF材料被认为在大约50-60%的含水量下形成如此厚的水层。当生物质在PVF材料表面生长时，影响水层形成的含水量条件发生了变化。这个范围从新材料的70%左右下降到富含生物质的材料的55%左右。本研究定量地阐明了生物过滤填料存在最佳含水率范围的原因;也就是说，填料表面适当的液层厚度是由一定范围的含水量决定的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Current Biochemical Engineering

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