Theory of grain mixture particle motion during aspiration separation

Q2 Agricultural and Biological Sciences

Agronomy research Pub Date : 2020-01-01 DOI:10.15159/AR.20.057

V. Bulgakov, S. Kiurchev, S. Ivanovs, J. Olt, S. Nikolaenko, I. Holovach, V. Adamchuk

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引用次数: 7

Abstract

The practice of separating grain mixtures with the use of the difference in the aerodynamic properties of their components has proved that the process of separating mixtures in the aspiration separator is the most promising one with regard to the improvement of quality and intensification of production. The authors have developed a new improved design of aspiration seed separators, in which the work process of separating seed material is performed with the use of vibration processes. In this seed material separator, the constant force air flow that acts on the sail members on the central pipe of the separator, when seeds are fed for processing, generates self-excited oscillations in the pipe, which produces centrifugal forces of inertia in the seed feeding system. As a result of the mentioned effect, the propelling force in the process under study substantially increases, accelerating the seeds of different fractions, which differ in their masses, to different velocities. The motion paths of the seed particles change accordingly, heavier particles moving closer to the vertical axis of the aspiration channel, which provides for increasing the efficiency of separation of the seeds of different fractions from each other. In this paper, a new mathematical model is developed for the motion of a seed mixture material particle process of vibration and aspiration separation has indicated that the separation of the motion paths of the medium and heavy fractions takes place within the range of 20 40 mm; the flying speed of the particles is equal to 3.2 8.0 m s 1, respectively; and their acceleration is equal to 1.8 3.3 m s 2, which provides the necessary conditions for the accurate and high quality separation into the required fractions. In view of the found differences between the kinematic characteristics of the separated fractions of the grain mixture, the diameter of the pipeline for the medium fraction is to be within the range of 90 100 mm, for the heavy fraction 50 70 mm.

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吸选过程中颗粒混合运动理论

利用颗粒混合物组分气动特性的差异进行颗粒混合物分离的实践证明，在抽吸分离机中分离混合物是提高质量和集约化生产最有前途的一种方法。作者开发了一种新的改进设计的吸气式种子分离器，其中种子物料的分离工作过程是利用振动过程进行的。在本种料分离器中，当种子被喂入加工时，恒力气流作用于分离器中央管道上的风帆构件，在管道中产生自激振荡，从而在喂种系统中产生惯性离心力。由于上述效应，所研究的过程中的推进力大大增加，使质量不同的不同馏分的种子加速到不同的速度。种子颗粒的运动路径也随之改变，较重的颗粒更靠近抽吸通道的垂直轴，从而提高了不同馏分的种子相互分离的效率。本文建立了一种新的种子混合物料振动与抽吸分离过程的数学模型，表明在20 ~ 40 mm范围内，中、重馏分的运动路径发生分离;颗粒的飞行速度分别为3.2 8.0 m s 1;它们的加速度为1.8 3.3 m s 2，为准确、高质量地分离成所需组分提供了必要条件。考虑到已发现的颗粒混合物分离馏分的运动特性差异，中馏分的管道直径应在90 - 100mm范围内，重馏分的管道直径应在50 - 70mm范围内。

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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来源期刊

Agronomy research Agricultural and Biological Sciences-Agronomy and Crop Science

CiteScore

2.10

自引率

0.00%

发文量

审稿时长

7 weeks

期刊介绍： Agronomy Research is a peer-reviewed international Journal intended for publication of broad-spectrum original articles, reviews and short communications on actual problems of modern biosystems engineering including crop and animal science, genetics, economics, farm- and production engineering, environmental aspects, agro-ecology, renewable energy and bioenergy etc. in the temperate regions of the world.