{"title":"Fluid Differential Agitators","authors":"S. Asiri","doi":"10.5281/zenodo.1062668","DOIUrl":null,"url":null,"abstract":"This research is to design and implement a new kind of agitators called differential agitator. The Differential Agitator is an electromechanic set consists of two shafts. The first shaft is the bearing axis while the second shaft is the axis of the quartet upper bearing impellers group and the triple lower group which are called as agitating group. The agitating group is located inside a cylindrical container equipped especially to contain square directors for the liquid entrance and square directors called fixing group for the liquid exit. The fixing group is installed containing the agitating group inside any tank whether from upper or lower position. The agitating process occurs through the agitating group bearing causing a lower pressure over the upper group leading to withdrawing the liquid from the square directors of the liquid entering and consequently the liquid moves to the denser place under the quartet upper group. Then, the liquid moves to the so high pressure area under the agitating group causing the liquid to exit from the square directors in the bottom of the container. For improving efficiency, parametric study and shape optimization has been carried out. A numerical analysis, manufacturing and laboratory experiments were conducted to design and implement the differential agitator. Knowing the material prosperities and the loading conditions, the FEM using ANSYS11 was used to get the optimum design of the geometrical parameters of the differential agitator elements while the experimental test was performed to validate the advantages of the differential agitators to give a high agitation performance of lime in the water as an example. In addition, the experimental work has been done to express the internal container shape in the agitation efficiency. The study ended up with conclusions to maximize agitator performance and optimize the geometrical parameters to be used for manufacturing the differential agitator. Keywords—Differential Agitators, Parametric Optimization, Shape Optimization, Agitation, FEM, ANSYS11.","PeriodicalId":23701,"journal":{"name":"World Academy of Science, Engineering and Technology, International Journal of Chemical, Molecular, Nuclear, Materials and Metallurgical Engineering","volume":"84 1","pages":"360-370"},"PeriodicalIF":0.0000,"publicationDate":"2013-06-21","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"3","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"World Academy of Science, Engineering and Technology, International Journal of Chemical, Molecular, Nuclear, Materials and Metallurgical Engineering","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.5281/zenodo.1062668","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 3

Abstract

This research is to design and implement a new kind of agitators called differential agitator. The Differential Agitator is an electromechanic set consists of two shafts. The first shaft is the bearing axis while the second shaft is the axis of the quartet upper bearing impellers group and the triple lower group which are called as agitating group. The agitating group is located inside a cylindrical container equipped especially to contain square directors for the liquid entrance and square directors called fixing group for the liquid exit. The fixing group is installed containing the agitating group inside any tank whether from upper or lower position. The agitating process occurs through the agitating group bearing causing a lower pressure over the upper group leading to withdrawing the liquid from the square directors of the liquid entering and consequently the liquid moves to the denser place under the quartet upper group. Then, the liquid moves to the so high pressure area under the agitating group causing the liquid to exit from the square directors in the bottom of the container. For improving efficiency, parametric study and shape optimization has been carried out. A numerical analysis, manufacturing and laboratory experiments were conducted to design and implement the differential agitator. Knowing the material prosperities and the loading conditions, the FEM using ANSYS11 was used to get the optimum design of the geometrical parameters of the differential agitator elements while the experimental test was performed to validate the advantages of the differential agitators to give a high agitation performance of lime in the water as an example. In addition, the experimental work has been done to express the internal container shape in the agitation efficiency. The study ended up with conclusions to maximize agitator performance and optimize the geometrical parameters to be used for manufacturing the differential agitator. Keywords—Differential Agitators, Parametric Optimization, Shape Optimization, Agitation, FEM, ANSYS11.
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流体差动搅拌器
本文的研究是设计并实现一种新型的搅拌器——差动式搅拌器。差动搅拌器是由两个轴组成的机电装置。第一个轴是轴承轴,第二个轴是四个上轴承叶轮组和三个下轴承叶轮组的轴,称为搅拌组。搅拌组位于圆柱形容器内,该圆柱形容器特别装有用于液体入口的方形导向器和用于液体出口的称为固定组的方形导向器。固定组包含搅拌组安装在任何罐内,无论从上或下位置安装。搅拌过程通过搅拌组轴承发生,在上部组上产生较低的压力,导致液体从液体进入的方形方向中抽出,因此液体移动到四重奏上部组下较致密的地方。然后,液体移动到搅拌组下的30高压区域,使液体从容器底部的方形导流器流出。为了提高效率,进行了参数化研究和形状优化。通过数值分析、制造和室内实验,设计和实现了差动搅拌器。在了解物料状况和加载条件的基础上,采用ansys有限元软件对差动搅拌器进行了几何参数的优化设计,并以水中石灰的高搅拌性能为例,验证了差动搅拌器的优势。此外,还对容器内部形状对搅拌效率的影响进行了实验研究。最后得出了最大限度地提高搅拌器性能和优化制造差动搅拌器的几何参数的结论。关键词:差动搅拌器,参数优化,形状优化,搅拌,有限元,ANSYS11。
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