Relationship Between Tool Temperature Distribution and Stagnation Point Behavior for Different Process Factors in Machining Operations

Jan Eric Ståhl; Maria Strömberg Bylund; Per Alm; Vyacheslav Kryzhanivskyy

doi:10.3233/ATDE240155

Relationship Between Tool Temperature Distribution and Stagnation Point Behavior for Different Process Factors in Machining Operations

Jan Eric Ståhl, Maria Strömberg Bylund, Per Alm, Vyacheslav Kryzhanivskyy

Research output: Chapter in Book/Report/Conference proceeding › Paper in conference proceeding › peer-review

Abstract

Metal cutting is physically defined by a tool separating a chip by developing a stagnation point after the work material has passed a shear plane. This distinguishes the method group metal cutting or machining from shearing and wedging processes. The development of the stagnation point is central to the functioning of a metal cutting process. The stagnation point and its behavior has a great influence on the different load conditions of the tool as it controls both the temperature distribution and the mechanical load distribution around the tool's edge-line. This publication shows that there is a temperature drop at the stagnation point where the shear stress changes sign, which means that the shear stress at this point assumes the value zero. Furthermore, it is demonstrated that there is a correlation between the position of the temperature dip, its size and the selected cutting data as well as tool geometry and current work material. The knowledge of the interaction between the position of the stagnation point and the tool coating type in combination with the tool's micro- and macro-geometry will be of importance for the development of high-performance tools optimized for different machining applications.

Original language	English
Title of host publication	Moving Integrated Product Development to Service Clouds in the Global Economy - Proceedings of the 21st ISPE Inc. International Conference on Concurrent Engineering, CE 2014
Editors	Joel Andersson, Shrikant Joshi, Lennart Malmskold, Fabian Hanning
Publisher	IOS Press
Pages	69-89
Number of pages	21
ISBN (Electronic)	9781643685106
DOIs	https://doi.org/10.3233/ATDE240155
Publication status	Published - 2024 Apr
Event	11th Swedish Production Symposium, SPS2024 - Trollhattan, Sweden Duration: 2024 Apr 23 → 2024 Apr 26

Publication series

Name	Advances in Transdisciplinary Engineering
Volume	52
ISSN (Print)	2352-751X
ISSN (Electronic)	2352-7528

Conference

Conference	11th Swedish Production Symposium, SPS2024
Country/Territory	Sweden
City	Trollhattan
Period	2024/04/23 → 2024/04/26

Subject classification (UKÄ)

Manufacturing, Surface and Joining Technology

Free keywords

FEM
IR technology
Load pattern
Machining
Minimum chip thickness
Stagnation point
Stagnation zone
Temperature distribution
Thermal load
Tool Protection Layer
TPL

Access to Document

10.3233/ATDE240155

Cite this

Ståhl, J. E., Bylund, M. S., Alm, P., & Kryzhanivskyy, V. (2024). Relationship Between Tool Temperature Distribution and Stagnation Point Behavior for Different Process Factors in Machining Operations. In J. Andersson, S. Joshi, L. Malmskold, & F. Hanning (Eds.), Moving Integrated Product Development to Service Clouds in the Global Economy - Proceedings of the 21st ISPE Inc. International Conference on Concurrent Engineering, CE 2014 (pp. 69-89). (Advances in Transdisciplinary Engineering; Vol. 52). IOS Press. https://doi.org/10.3233/ATDE240155

Ståhl, Jan Eric ; Bylund, Maria Strömberg ; Alm, Per et al. / Relationship Between Tool Temperature Distribution and Stagnation Point Behavior for Different Process Factors in Machining Operations. Moving Integrated Product Development to Service Clouds in the Global Economy - Proceedings of the 21st ISPE Inc. International Conference on Concurrent Engineering, CE 2014. editor / Joel Andersson ; Shrikant Joshi ; Lennart Malmskold ; Fabian Hanning. IOS Press, 2024. pp. 69-89 (Advances in Transdisciplinary Engineering).

@inproceedings{e11e7dc9b1504f6bb704d604553f411c,

title = "Relationship Between Tool Temperature Distribution and Stagnation Point Behavior for Different Process Factors in Machining Operations",

abstract = "Metal cutting is physically defined by a tool separating a chip by developing a stagnation point after the work material has passed a shear plane. This distinguishes the method group metal cutting or machining from shearing and wedging processes. The development of the stagnation point is central to the functioning of a metal cutting process. The stagnation point and its behavior has a great influence on the different load conditions of the tool as it controls both the temperature distribution and the mechanical load distribution around the tool's edge-line. This publication shows that there is a temperature drop at the stagnation point where the shear stress changes sign, which means that the shear stress at this point assumes the value zero. Furthermore, it is demonstrated that there is a correlation between the position of the temperature dip, its size and the selected cutting data as well as tool geometry and current work material. The knowledge of the interaction between the position of the stagnation point and the tool coating type in combination with the tool's micro- and macro-geometry will be of importance for the development of high-performance tools optimized for different machining applications.",

keywords = "FEM, IR technology, Load pattern, Machining, Minimum chip thickness, Stagnation point, Stagnation zone, Temperature distribution, Thermal load, Tool Protection Layer, TPL",

author = "St{\aa}hl, {Jan Eric} and Bylund, {Maria Str{\"o}mberg} and Per Alm and Vyacheslav Kryzhanivskyy",

year = "2024",

month = apr,

doi = "10.3233/ATDE240155",

language = "English",

series = "Advances in Transdisciplinary Engineering",

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pages = "69--89",

editor = "Joel Andersson and Shrikant Joshi and Lennart Malmskold and Fabian Hanning",

booktitle = "Moving Integrated Product Development to Service Clouds in the Global Economy - Proceedings of the 21st ISPE Inc. International Conference on Concurrent Engineering, CE 2014",

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note = "11th Swedish Production Symposium, SPS2024 ; Conference date: 23-04-2024 Through 26-04-2024",

}

Ståhl, JE, Bylund, MS, Alm, P & Kryzhanivskyy, V 2024, Relationship Between Tool Temperature Distribution and Stagnation Point Behavior for Different Process Factors in Machining Operations. in J Andersson, S Joshi, L Malmskold & F Hanning (eds), Moving Integrated Product Development to Service Clouds in the Global Economy - Proceedings of the 21st ISPE Inc. International Conference on Concurrent Engineering, CE 2014. Advances in Transdisciplinary Engineering, vol. 52, IOS Press, pp. 69-89, 11th Swedish Production Symposium, SPS2024, Trollhattan, Sweden, 2024/04/23. https://doi.org/10.3233/ATDE240155

Relationship Between Tool Temperature Distribution and Stagnation Point Behavior for Different Process Factors in Machining Operations. / Ståhl, Jan Eric; Bylund, Maria Strömberg; Alm, Per et al.
Moving Integrated Product Development to Service Clouds in the Global Economy - Proceedings of the 21st ISPE Inc. International Conference on Concurrent Engineering, CE 2014. ed. / Joel Andersson; Shrikant Joshi; Lennart Malmskold; Fabian Hanning. IOS Press, 2024. p. 69-89 (Advances in Transdisciplinary Engineering; Vol. 52).

Research output: Chapter in Book/Report/Conference proceeding › Paper in conference proceeding › peer-review

TY - GEN

T1 - Relationship Between Tool Temperature Distribution and Stagnation Point Behavior for Different Process Factors in Machining Operations

AU - Ståhl, Jan Eric

AU - Bylund, Maria Strömberg

AU - Alm, Per

AU - Kryzhanivskyy, Vyacheslav

PY - 2024/4

Y1 - 2024/4

N2 - Metal cutting is physically defined by a tool separating a chip by developing a stagnation point after the work material has passed a shear plane. This distinguishes the method group metal cutting or machining from shearing and wedging processes. The development of the stagnation point is central to the functioning of a metal cutting process. The stagnation point and its behavior has a great influence on the different load conditions of the tool as it controls both the temperature distribution and the mechanical load distribution around the tool's edge-line. This publication shows that there is a temperature drop at the stagnation point where the shear stress changes sign, which means that the shear stress at this point assumes the value zero. Furthermore, it is demonstrated that there is a correlation between the position of the temperature dip, its size and the selected cutting data as well as tool geometry and current work material. The knowledge of the interaction between the position of the stagnation point and the tool coating type in combination with the tool's micro- and macro-geometry will be of importance for the development of high-performance tools optimized for different machining applications.

AB - Metal cutting is physically defined by a tool separating a chip by developing a stagnation point after the work material has passed a shear plane. This distinguishes the method group metal cutting or machining from shearing and wedging processes. The development of the stagnation point is central to the functioning of a metal cutting process. The stagnation point and its behavior has a great influence on the different load conditions of the tool as it controls both the temperature distribution and the mechanical load distribution around the tool's edge-line. This publication shows that there is a temperature drop at the stagnation point where the shear stress changes sign, which means that the shear stress at this point assumes the value zero. Furthermore, it is demonstrated that there is a correlation between the position of the temperature dip, its size and the selected cutting data as well as tool geometry and current work material. The knowledge of the interaction between the position of the stagnation point and the tool coating type in combination with the tool's micro- and macro-geometry will be of importance for the development of high-performance tools optimized for different machining applications.

KW - FEM

KW - IR technology

KW - Load pattern

KW - Machining

KW - Minimum chip thickness

KW - Stagnation point

KW - Stagnation zone

KW - Temperature distribution

KW - Thermal load

KW - Tool Protection Layer

KW - TPL

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DO - 10.3233/ATDE240155

M3 - Paper in conference proceeding

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EP - 89

BT - Moving Integrated Product Development to Service Clouds in the Global Economy - Proceedings of the 21st ISPE Inc. International Conference on Concurrent Engineering, CE 2014

A2 - Andersson, Joel

A2 - Joshi, Shrikant

A2 - Malmskold, Lennart

A2 - Hanning, Fabian

PB - IOS Press

T2 - 11th Swedish Production Symposium, SPS2024

Y2 - 23 April 2024 through 26 April 2024

ER -

Ståhl JE, Bylund MS, Alm P, Kryzhanivskyy V. Relationship Between Tool Temperature Distribution and Stagnation Point Behavior for Different Process Factors in Machining Operations. In Andersson J, Joshi S, Malmskold L, Hanning F, editors, Moving Integrated Product Development to Service Clouds in the Global Economy - Proceedings of the 21st ISPE Inc. International Conference on Concurrent Engineering, CE 2014. IOS Press. 2024. p. 69-89. (Advances in Transdisciplinary Engineering). doi: 10.3233/ATDE240155

Relationship Between Tool Temperature Distribution and Stagnation Point Behavior for Different Process Factors in Machining Operations

Abstract

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Conference

Subject classification (UKÄ)

Free keywords

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