Modeling of Vibration Condition in Flat Surface Grinding Process
Joint Authors
Jin, Wuyin
Gasagara, Amon
Uwimbabazi, Angelique
Source
Issue
Vol. 2020, Issue 2020 (31 Dec. 2020), pp.1-12, 12 p.
Publisher
Hindawi Publishing Corporation
Publication Date
2020-02-10
Country of Publication
Egypt
No. of Pages
12
Main Subjects
Abstract EN
This article presents a new model of the flat surface grinding process vibration conditions.
The study establishes a particular analysis and comparison between the influence of the normal and tangential components of grinding forces on the vibration conditions of the process.
The bifurcation diagrams are used to examine the process vibration conditions for the depth of cut and the cutting speed as the bifurcation parameters.
The workpiece is considered to be rigid and the grinding wheel is modeled as a nonlinear two-degrees-of-freedom mass-spring-damper oscillator.
To verify the model, experiments are carried out to analyze in the frequency domain the normal and tangential dynamic grinding forces.
The results of the process model simulation show that the vibration condition is more affected by the normal component than the tangential component of the grinding forces.
The results of the tested experimental conditions indicate that the cutting speed of 30 m/s can permit grinding at the depth of cut up to 0.02 mm without sacrificing the process of vibration behavior.
American Psychological Association (APA)
Gasagara, Amon& Jin, Wuyin& Uwimbabazi, Angelique. 2020. Modeling of Vibration Condition in Flat Surface Grinding Process. Shock and Vibration،Vol. 2020, no. 2020, pp.1-12.
https://search.emarefa.net/detail/BIM-1209790
Modern Language Association (MLA)
Gasagara, Amon…[et al.]. Modeling of Vibration Condition in Flat Surface Grinding Process. Shock and Vibration No. 2020 (2020), pp.1-12.
https://search.emarefa.net/detail/BIM-1209790
American Medical Association (AMA)
Gasagara, Amon& Jin, Wuyin& Uwimbabazi, Angelique. Modeling of Vibration Condition in Flat Surface Grinding Process. Shock and Vibration. 2020. Vol. 2020, no. 2020, pp.1-12.
https://search.emarefa.net/detail/BIM-1209790
Data Type
Journal Articles
Language
English
Notes
Includes bibliographical references
Record ID
BIM-1209790