Improving endmilling surface finish by workpiece rotation and adaptive toolpath spacing

Vijayaraghavan, Athulan; Hoover, Aaron M.; Hartnett, Jeffrey; Dornfeld, David

doi:10.1016/j.ijmachtools.2008.07.015

Cited by 31 publications

(13 citation statements)

References 27 publications

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“…To extend the present result to application of highperformance manufacturing with various methods delivering different external loads of mechanical, thermal, chemical nature or a combination of them [25][26][27], the surface integrity change induced by stress field, stain field, temperature field, etc. should be considered accordingly with respect to the specific external loads.…”

Section: Discussionmentioning

confidence: 92%

Inverse surface integrity problem in ultrasonic impact-treated AISI 304 stainless steel components

Wang

Zhu

Lei

et al. 2016

Int J Adv Manuf Technol

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The inverse problem for surface integrity is still not solved in practice during high-performance component manufacturing, i.e., it is not possible selecting an appropriate process as well as process parameters in advance according to the given surface integrity required for the high performance. The desired surface integrity is usually created by trial and error based on an iterative approach due to lack of quantitative correlations between the loads of a process and the surface integrity variations during manufacturing. The inverse surface integrity problem is studied for manufacturing AISI 304 stainless steel components by employing an ultrasonic impact treatment (UIT) to achieve an enhanced fatigue performance. The correlations are explored between the process loads of mechanical impact, corresponding material loading within the treated component and surface integrity change in the surface layer due to surface modification. Based on experimental and numerical studies, such correlations of UIT process are identified primarily as the quantitative correlation between external mechanical load and material loading of strain and stress, and that between material loading and changes in surface integrity parameters such as residual stress and microhardness due to surface modification. It is demonstrated that a knowledge-based solution of the inverse surface integrity problem is possibly achieved by establishing the correlations to derive process parameters from a given surface integrity for manufacturing of high-performance components.

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Section: Discussionmentioning

confidence: 92%

Inverse surface integrity problem in ultrasonic impact-treated AISI 304 stainless steel components

Wang

Zhu

Lei

et al. 2016

Int J Adv Manuf Technol

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show abstract

“…Recent developments by Quinsat and Sabourin [12] and Vijayaraghavan et al [13] sought to find an optimal orientation for the parallel intersection planes in order to generate iso-planar tool paths with minimal overall tool path length for a given sculptured surface. The optimal orientation was determined by analyzing local parameters of the surface which influenced the material removal rate or by a metric of the mean scallop height resulting from a particular plane orientation.…”

Section: Surface Topology Based Methodsmentioning

confidence: 99%

Preferred feed direction field: A new tool path generation method for efficient sculptured surface machining

Kumazawa

Feng

Fard

2015

Computer-Aided Design

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“…The second selection utilizes a ball nose tool to cater for non-flat surfaces. Based on previous studies, the capabilities of this tool in handling sculptured surfaces are proven and high-quality surface finish can be produced (Chen, Huang, & Chen, 2005;Chen & Shi, 2008;Vijayaraghavan, Hoover, Hartnett, & Dornfeld, 2008). Moreover, this tool can be easily guided to engage with part surfaces and produces simpler NC code for machining (Chen & Shi, 2008).…”

Section: Cutting Tools and Surface Classificationmentioning

confidence: 99%

End mill tools integration in CNC machining for rapid manufacturing processes: simulation studies

Zahid

Case

Watts

2015

Production & Manufacturing Research

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Computer numerical controlled (CNC) machining has been recognized as a manufacturing process that is capable of producing metal parts with high precision and reliable quality, whereas many additive manufacturing methods are less capable in these respects. The introduction of a new layer-removal methodology that utilizes an indexing device to clamp the workpiece can be used to extend CNC applications into the realm of rapid manufacturing (CNC-RM) processes. This study aims to improve the implementation of CNC machining for RM by formulating a distinct approach to integrate end mill tools during finishing processes. A main objective is to enhance process efficiency by minimizing the staircasing effect of layer removal so as to improve the quality of machined parts. In order to achieve this, different types of end mill tools are introduced to cater for specific part surfaces during finishing operations. Virtual machining simulations are executed to verify the method and the implications. The findings indicate the advantages of the approach in terms of cutting time and excess volume left on the parts. It is shown that using different tools for finishing operations will improve the capabilities of CNC machining for rapid manufacturing applications.

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Improving endmilling surface finish by workpiece rotation and adaptive toolpath spacing

Cited by 31 publications

References 27 publications

Inverse surface integrity problem in ultrasonic impact-treated AISI 304 stainless steel components

Inverse surface integrity problem in ultrasonic impact-treated AISI 304 stainless steel components

Preferred feed direction field: A new tool path generation method for efficient sculptured surface machining

End mill tools integration in CNC machining for rapid manufacturing processes: simulation studies

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