Determination of damping coefficient of shock impulse for rocks grinding process

Q2 Social Sciences
Yuri Dmitrak, V. Atrushkevich, L. Adamova
{"title":"Determination of damping coefficient of shock impulse for rocks grinding process","authors":"Yuri Dmitrak, V. Atrushkevich, L. Adamova","doi":"10.21177/1998-4502-2022-14-4-702-710","DOIUrl":null,"url":null,"abstract":"Introduction. The physical properties of rocks, which determine the choice of the type of mill, as well as its operating parameters, are considered. The importance of studying the damping properties of the crushed material and their influence on the energy intensity of the grinding process is noted. Research methods and materials. The differential equation of motion of the crack wall, previously obtained by the authors of the article, is applied when it is exposed to a shock wave with amplitude σ and duration τ. The classical theory of damped oscillations of the system is used to determine the damping decrement of the shock pulse amplitude. A series of experimental studies was carried out on a laboratory sample of a drum mill to determine the magnitude of the shock pulse damping coefficient. Rocks from various deposits in Russia with strictly defined strength characteristics were used as the crushed material. Research results. Dependences of the amplitude of the shock pulse on time are constructed for the grinding of granite raw materials, carbonate rocks and soft rocks (gypsum) in a drum mill. The following conclusions were drawn: 1. When grinding strong and very hard rocks in a drum mill, a strong impact occurs (with a large amplitude and duration of the shock pulse) and with its weak damping when propagating in the rock. 2. When grinding carbonate rocks, doubling the angular velocity of rotation of the grinding chamber leads to an increase in the amplitude of the shock pulse by about 1.5 times. 3. The duration of shock wave propagation in both cases is approximately equal. 4. The frequency of grinding media collisions increases significantly. This indicates a sharp increase in the energy intensity of the grinding process. 5. When grinding soft rocks in a drum mill, almost half of the input energy is spent on overcoming the damping properties of the material, and small, frequent pulses, which consume half of all energy, are not able to grind the material to the desired size. Discussion. Based on the conducted studies, graphs of dependencies between the main parameters of the drum mill were constructed. The dependences of the duration of the shock pulse on the average diameter of the particles of the crushed material are constructed. The analysis of these dependences made it possible to conclude that the duration of the shock pulse is in a parabolic dependence on the value of the average particle diameter of the crushed material. The dependences of the damping coefficient on the damping decrement of the shock pulse amplitude are constructed. The analysis of these dependences allowed us to conclude that the shock pulse damping coefficient increases almost linearly with an increase in the damping decrement of the shock pulse amplitude. The dependences of the damping coefficient of the shock pulse on the average diameter of the particles of the crushed material are constructed. The analysis of these dependences allowed us to conclude that the shock pulse damping coefficient is in a quadratic dependence on the value of the average particle diameter of the crushed material. Conclusion. In this article, based on the classical theory of damped oscillations of such system, the principle of determining the damping coefficient of the shock pulse propagating from the grinding body deep into the grinding load of the drum mill is scientifically substantiated. Resume. Experimental determination of the value of the damping factor of the shock pulse, along with the use of the energy criterion for the destruction of the rock, makes it possible to calculate the amount of energy required to destroy the rock particles to a given size. Suggestions for practical application and direction for future research: The results of the research can be used at the enterprises of the mining sector of the industry to improve the efficiency of processing mineral resources and reduce the energy intensity of the process of grinding rocks in drum mills.","PeriodicalId":37608,"journal":{"name":"Sustainable Development of Mountain Territories","volume":" ","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2022-12-30","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Sustainable Development of Mountain Territories","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.21177/1998-4502-2022-14-4-702-710","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"Social Sciences","Score":null,"Total":0}
引用次数: 0

Abstract

Introduction. The physical properties of rocks, which determine the choice of the type of mill, as well as its operating parameters, are considered. The importance of studying the damping properties of the crushed material and their influence on the energy intensity of the grinding process is noted. Research methods and materials. The differential equation of motion of the crack wall, previously obtained by the authors of the article, is applied when it is exposed to a shock wave with amplitude σ and duration τ. The classical theory of damped oscillations of the system is used to determine the damping decrement of the shock pulse amplitude. A series of experimental studies was carried out on a laboratory sample of a drum mill to determine the magnitude of the shock pulse damping coefficient. Rocks from various deposits in Russia with strictly defined strength characteristics were used as the crushed material. Research results. Dependences of the amplitude of the shock pulse on time are constructed for the grinding of granite raw materials, carbonate rocks and soft rocks (gypsum) in a drum mill. The following conclusions were drawn: 1. When grinding strong and very hard rocks in a drum mill, a strong impact occurs (with a large amplitude and duration of the shock pulse) and with its weak damping when propagating in the rock. 2. When grinding carbonate rocks, doubling the angular velocity of rotation of the grinding chamber leads to an increase in the amplitude of the shock pulse by about 1.5 times. 3. The duration of shock wave propagation in both cases is approximately equal. 4. The frequency of grinding media collisions increases significantly. This indicates a sharp increase in the energy intensity of the grinding process. 5. When grinding soft rocks in a drum mill, almost half of the input energy is spent on overcoming the damping properties of the material, and small, frequent pulses, which consume half of all energy, are not able to grind the material to the desired size. Discussion. Based on the conducted studies, graphs of dependencies between the main parameters of the drum mill were constructed. The dependences of the duration of the shock pulse on the average diameter of the particles of the crushed material are constructed. The analysis of these dependences made it possible to conclude that the duration of the shock pulse is in a parabolic dependence on the value of the average particle diameter of the crushed material. The dependences of the damping coefficient on the damping decrement of the shock pulse amplitude are constructed. The analysis of these dependences allowed us to conclude that the shock pulse damping coefficient increases almost linearly with an increase in the damping decrement of the shock pulse amplitude. The dependences of the damping coefficient of the shock pulse on the average diameter of the particles of the crushed material are constructed. The analysis of these dependences allowed us to conclude that the shock pulse damping coefficient is in a quadratic dependence on the value of the average particle diameter of the crushed material. Conclusion. In this article, based on the classical theory of damped oscillations of such system, the principle of determining the damping coefficient of the shock pulse propagating from the grinding body deep into the grinding load of the drum mill is scientifically substantiated. Resume. Experimental determination of the value of the damping factor of the shock pulse, along with the use of the energy criterion for the destruction of the rock, makes it possible to calculate the amount of energy required to destroy the rock particles to a given size. Suggestions for practical application and direction for future research: The results of the research can be used at the enterprises of the mining sector of the industry to improve the efficiency of processing mineral resources and reduce the energy intensity of the process of grinding rocks in drum mills.
岩石磨削过程冲击冲击阻尼系数的确定
介绍岩石的物理特性决定了磨机类型的选择及其操作参数。指出了研究破碎材料的阻尼特性及其对研磨过程能量强度的影响的重要性。研究方法和材料。当裂纹壁暴露于振幅为σ、持续时间为τ的冲击波时,应用本文作者先前获得的裂纹壁运动微分方程。利用系统阻尼振荡的经典理论来确定冲击脉冲振幅的阻尼衰减率。在转鼓磨机的实验室样品上进行了一系列实验研究,以确定冲击脉冲阻尼系数的大小。来自俄罗斯各种矿床的具有严格定义的强度特征的岩石被用作破碎材料。研究结果。建立了在滚筒磨机中研磨花岗岩原料、碳酸盐岩和软岩(石膏)的冲击脉冲振幅随时间的依赖关系。得出以下结论:1。当在滚筒磨机中研磨坚硬的岩石时,会发生强烈的冲击(冲击脉冲的振幅和持续时间较大),并且在岩石中传播时阻尼较弱。2.当研磨碳酸盐岩时,研磨室的旋转角速度加倍导致冲击脉冲的幅度增加约1.5倍。3.在这两种情况下,冲击波传播的持续时间大致相等。4.研磨介质碰撞的频率显著增加。这表明研磨过程的能量强度急剧增加。5.当在滚筒磨机中研磨软岩石时,几乎一半的输入能量用于克服材料的阻尼特性,并且消耗一半能量的小而频繁的脉冲不能将材料研磨到期望的尺寸。讨论基于所进行的研究,构建了滚筒磨主要参数之间的依赖关系图。构造了冲击脉冲持续时间与破碎材料颗粒平均直径的关系。对这些相关性的分析可以得出结论,冲击脉冲的持续时间与破碎材料的平均粒径值呈抛物线相关性。建立了阻尼系数与冲击脉冲振幅阻尼衰减率的关系式。对这些相关性的分析使我们得出结论,冲击脉冲阻尼系数几乎随着冲击脉冲振幅阻尼衰减的增加而线性增加。构造了冲击脉冲阻尼系数与破碎材料颗粒平均直径的关系式。对这些相关性的分析使我们得出结论,冲击脉冲阻尼系数与破碎材料的平均粒径值呈二次相关性。结论本文以该系统阻尼振荡的经典理论为基础,科学地证实了确定冲击脉冲从研磨体传播到滚筒磨机研磨载荷深处的阻尼系数的原理。简历通过实验确定冲击脉冲的阻尼因子值,以及使用破坏岩石的能量标准,可以计算将岩石颗粒破坏到给定尺寸所需的能量。实际应用建议和未来研究方向:研究结果可用于该行业采矿部门的企业,以提高矿产资源的加工效率,降低滚筒磨机磨石过程的能源强度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
求助全文
约1分钟内获得全文 求助全文
来源期刊
Sustainable Development of Mountain Territories
Sustainable Development of Mountain Territories Social Sciences-Sociology and Political Science
CiteScore
2.40
自引率
0.00%
发文量
36
期刊介绍: International scientific journal "Sustainable development of mountain territories" covers fundamental and applied regional, national and international research and provides a platform to publish original full papers and related reviews in the following areas: engineering science and Earth science in the field of sustainable development of mountain territories. Main objectives of international scientific journal "Sustainable development of mountain territories" are: raising the level of professional scientific workers, teachers of higher educational institutions and scientific organizations; presentation of research results in the field of sustainable development of mountain areas on the technical aspects and Earth sciences, informing readers about the results of Russian and international scientific forums; improved review and editing of the articles submitted for publication; ensuring wide dissemination for the published articles in the international academic environment; encouraging dissemination and indexing of scientific works in various foreign key citation databases.
×
引用
GB/T 7714-2015
复制
MLA
复制
APA
复制
导出至
BibTeX EndNote RefMan NoteFirst NoteExpress
×
提示
您的信息不完整,为了账户安全,请先补充。
现在去补充
×
提示
您因"违规操作"
具体请查看互助需知
我知道了
×
提示
确定
请完成安全验证×
copy
已复制链接
快去分享给好友吧!
我知道了
右上角分享
点击右上角分享
0
联系我们:info@booksci.cn Book学术提供免费学术资源搜索服务,方便国内外学者检索中英文文献。致力于提供最便捷和优质的服务体验。 Copyright © 2023 布克学术 All rights reserved.
京ICP备2023020795号-1
ghs 京公网安备 11010802042870号
Book学术文献互助
Book学术文献互助群
群 号:481959085
Book学术官方微信