Investigation of the relationship between fractal and hydraulic properties of porous structures of the upper respiratory tract of some Arctic animals

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引用次数: 1

Abstract

The respiratory ducts of animals and humans are presented by curved tubes with complex geometries. The open areas in such structures are filled with moving air governed by a pressure drop between the inlet and outlet of the duct. The complex structures formed by thin walls and warmed by constant blood flow at the body temperatures T=36-39 C serve for fast and efficient warming of the inhaled air to the body temperature and its moistening up to 100% humidity. The Arctic animals possess the most efficient nasal ducts allowing the heating of the inhaled air from T=-30-60C to T=38-39 C during the duct with the length L=8-15 only. The detailed geometry of the nasal ducts of some Arctic animal has been studied on the computed tomograms (CT) scans of the heads of the animals found in the open databases and published in literature. The highly porous structures on some slices are formed by fractal-like divisions of the walls protruded into the nasal lumen. Since the fractal structures are characterized by their fractal dimensions D, the relationships between the hydrodynamic properties and fractal dimensions of the porous structures of the upper respiratory tract of some Arctic animals has been studied. The dimensions D of the cross sections of the tract have been calculated by the counting box method. The porosities of the samples, the tortuosity of the pores, and the equivalent hydraulic diameter Dh of the channel have been calculated. Sierpinski fractals of various types have been used as models of porous structures, for which the above listed parameters, as well as hydraulic resistance to a stationary flow, have also been computed. A number of statistical dependencies between the calculated parameters were revealed, but the absence of their correlations with D was shown. It was obtained, the structures with different porosities and hydraulic resistance Dh can have the same values ​​of D. Therefore, the choice of an adequate model based on only D value introduces significant errors in the calculations of air heating along the upper respiratory tract. The statistical dependences inherent in the natural samples studied can be obtained only on the basis of multifractal models in which the number and shape of the channels, as well as the scale of their decrease, change in a certain way at each generation.
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北极动物上呼吸道多孔结构分形与水力特性关系的研究
动物和人类的呼吸管道是由具有复杂几何形状的弯曲管呈现的。这种结构的开放区域充满了由管道入口和出口之间的压降控制的流动空气。由薄壁形成的复杂结构在体温T=36-39℃下由持续的血液流动加热,用于快速有效地将吸入的空气加热到体温,并将其润湿至100%的湿度。北极动物拥有最有效的鼻导管,允许在长度仅为L=8-15的导管期间将吸入的空气从T=-30-60℃加热到T=38-39℃。一些北极动物的鼻导管的详细几何形状已经在开放数据库中发现的动物头部的计算机断层扫描(CT)上进行了研究,并发表在文献中。一些切片上的高度多孔结构是由突出到鼻腔的壁的分形分裂形成的。由于分形结构具有分形维数D的特征,本文研究了北极动物上呼吸道多孔结构的水动力特性与分形维数的关系。用计数盒法计算了气道横截面的尺寸D。计算了试样的孔隙率、孔隙的弯曲度和沟道的等效水力直径Dh。各种类型的Sierpinski分形已被用作多孔结构的模型,并计算了上述参数以及对静流的水力阻力。揭示了计算参数之间的一些统计依赖关系,但显示了它们与D的相关性缺失。结果表明,不同孔隙率和水力阻力Dh的结构可以具有相同的D值。因此,仅根据D值选择合适的模型会给上呼吸道空气加热计算带来较大误差。所研究的自然样本中固有的统计依赖性只能基于多重分形模型来获得,在多重分形模型中,每一代河道的数量和形状及其减少的规模都以一定的方式变化。
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