Marcel Schrader, Nils Hoffmann, Stefan Schmideder, Charlotte Deffur, Carsten Schilde, Heiko Briesen, Arno Kwade
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The pellets are subjected to mechanical stress during cultivation, which can lead to structural changes affecting product titer and process conditions. To numerically investigate the mechanical behavior of pellets under normal stresses, the discrete element method (DEM) was used for the first time to simulate pellet compression. Initially, pellet structures were generated using a biological growth model and represented by a flexible fiber model. Force–displacement curves were recorded during compression to investigate the influencing factors. The effects of pellet size, fiber segment length, biological growth and DEM model parameters were studied. A strong influence of the growth parameters on the radial hyphal fraction and thus on the compression force was shown. Furthermore, the mechanical properties of the fiber joints significantly determined the pellet mechanics in the considered compression range. 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引用次数: 0
摘要
丝状微生物能够利用可再生副产品和废料生产出多种工业相关物质,如酶或活性药物成分。微生物生长的特点是形成由管状多分枝细胞(菌丝)组成的复杂多孔网络(菌丝体)。除生产化学物质外,菌丝体还越来越多地用于纺织品、包装、食品和建筑材料。总之,菌丝的机械行为对许多应用都至关重要。在浸没培养过程中,会形成球形的菌丝网络(颗粒)。球团在培养过程中会受到机械应力,从而导致结构变化,影响产品滴度和工艺条件。为了从数值上研究球团在正常应力下的机械行为,我们首次使用离散元素法(DEM)来模拟球团压缩。首先,使用生物生长模型生成颗粒结构,并用柔性纤维模型表示。在压缩过程中记录了力-位移曲线,以研究影响因素。研究了颗粒尺寸、纤维段长度、生物生长和 DEM 模型参数的影响。结果表明,生长参数对径向菌丝分数有很大影响,因此对压缩力也有很大影响。此外,在所考虑的压缩范围内,纤维接头的机械特性对球团的力学性能有重要影响。总之,该模拟方法为不同菌丝体应力的数字化研究提供了一种新工具,未来可用于通过遗传和工艺工程方法增强菌丝体结构。
Simulation of the compression of pellets out of filamentous microorganisms using DEM
Filamentous microorganisms enable the production of a wide range of industrially relevant substances, such as enzymes or active pharmaceutical ingredients, from renewable side products and waste materials. The microorganisms' growth is characterized by the formation of complex, porous networks (mycelium) of tubular, multi-branched cells (hyphae). The mycelium is increasingly used in textiles, packaging, food and construction materials, in addition to the production of chemical substances. Overall, the mycelium's mechanical behavior is essential to many applications. In submerged cultures, spherical hyphal networks (pellets) are formed. The pellets are subjected to mechanical stress during cultivation, which can lead to structural changes affecting product titer and process conditions. To numerically investigate the mechanical behavior of pellets under normal stresses, the discrete element method (DEM) was used for the first time to simulate pellet compression. Initially, pellet structures were generated using a biological growth model and represented by a flexible fiber model. Force–displacement curves were recorded during compression to investigate the influencing factors. The effects of pellet size, fiber segment length, biological growth and DEM model parameters were studied. A strong influence of the growth parameters on the radial hyphal fraction and thus on the compression force was shown. Furthermore, the mechanical properties of the fiber joints significantly determined the pellet mechanics in the considered compression range. Overall, the simulation approach provides a novel tool for the digital investigation of stress on different mycelia, which may be used in the future to enhance mycelial structures through genetic and process engineering methods.
期刊介绍:
GENERAL OBJECTIVES: Computational Particle Mechanics (CPM) is a quarterly journal with the goal of publishing full-length original articles addressing the modeling and simulation of systems involving particles and particle methods. The goal is to enhance communication among researchers in the applied sciences who use "particles'''' in one form or another in their research.
SPECIFIC OBJECTIVES: Particle-based materials and numerical methods have become wide-spread in the natural and applied sciences, engineering, biology. The term "particle methods/mechanics'''' has now come to imply several different things to researchers in the 21st century, including:
(a) Particles as a physical unit in granular media, particulate flows, plasmas, swarms, etc.,
(b) Particles representing material phases in continua at the meso-, micro-and nano-scale and
(c) Particles as a discretization unit in continua and discontinua in numerical methods such as
Discrete Element Methods (DEM), Particle Finite Element Methods (PFEM), Molecular Dynamics (MD), and Smoothed Particle Hydrodynamics (SPH), to name a few.