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DYNAMIC PERFORMANCE ANALYSIS OF LATHE SPINDLE USING ANSYS

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Publicado no:International Journal of Advanced Engineering and Science vol. 13, no. 2 (Dec 2024), p. 1
Autor principal: Alam, Farhan
Outros Autores: Gadpale, Vikas
Publicado em:
Educational Research Multimedia & Publications
Assuntos:
Finite element method
Failure
Support systems
Spindles
Performance evaluation
Investigations
Material properties
Turning (machining)
Manufacturers
Materials selection
Breakdowns
Lathes
Manufacturing
Critical components
Composite materials
Stress distribution
Efficiency
Structural behavior
Design analysis
Computer program integrity
Design improvements
Structural integrity
Milling (machining)
Maintenance costs
Three dimensional models
Impact analysis
Mathematical models
Design optimization
Design parameters
Downtime
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Resumo:The lathe spindle is a critical component of machining systems, playing a pivotal role in achieving precision and accuracy in manufacturing processes. This research paper presents a comprehensive investigation into the behavior and performance of lathe spindle components through finite element analysis (FEA) utilizing ANSYS software. The primary objective is to assess the structural integrity and stress distribution in the spindle system under varying operational conditions and design parameters. The study begins by developing a three-dimensional model of a typical lathe spindle, incorporating details of the spindle material and its supporting structure. The geometry and material properties of the spindle, as well as the support mechanism, are precisely defined. This model serves as the basis for a series of simulations and parametric analyses. The FEA simulations are conducted to explore the Von Mises stress distribution in the spindle system during different machining operations. Various loading conditions, such as turning, drilling, and milling, are applied to the spindle to mimic real-world scenarios. The results provide insights into stress concentrations, critical regions, and potential failure points within the spindle components. Furthermore, a parametric study is conducted to evaluate the influence of material properties and support design on spindle performance. Different materials, including various alloys and composite materials, are considered. The study investigates how alterations in material properties affect stress levels and overall structural behavior. Additionally, the design of the spindle support system is analyzed to assess its impact on stress distribution. The findings of this research paper are instrumental for enhancing the design and performance of lathe spindles in machining applications. By gaining a deeper understanding of stress distribution and structural behavior, manufacturers can make informed decisions regarding material selection and spindle support design. This research contributes to the optimization of lathe spindle systems, which directly translates into improved machining precision, reduced downtime, and enhanced productivity.
ISSN:2304-7712
2304-7720
Fonte:Advanced Technologies & Aerospace Database