Assessment of the Heat Transfer Conditions in the Cavity of a Rotating Circular Saw

Jan Stegmann; Moritz Baumert; Stephan Kabelac; Christian Menze; Johannes Ramme; Hans Christian Möhring

doi:10.3390/en17133189

Details

Original language	English
Article number	3189
Number of pages	15
Journal	ENERGIES
Volume	17
Issue number	13
Publication status	Published - 28 Jun 2024

Abstract

To improve machining processes concerning the usage of lubricants, knowledge of the thermo-mechanical and thermo-fluid interactions at the cutting zone is of great importance. This study focuses on the description of the convective heat transfer which occurs during circular sawing when the lubricant is provided via an internal coolant supply. The highly complex flow field inside the cavity of the sawing process is separated into two distinct flow forms, an impingement and a channel flow. With the aid of experimental and numerical studies, the heat transfer characteristics of these two flow forms have been examined for water and a lubricant used in the circular sawing process. Studies have been conducted over a wide range of Reynolds numbers (impingement flow: (Formula presented.), channel flow: (Formula presented.)). Additionally, the variation in the inlet temperature of the fluid, as well as the variation in heating power, has been studied. Overall, the impingement flow yields a significantly higher heat transfer than the channel flow with Nußelt-numbers ranging from 120 to 230, whereas the Nußelt-numbers in the case of the channel flow range from 20 to 160. For both flow forms, the use of the lubricant results in a better heat transfer compared with the usage of water. With the aid of these studies, correlations to describe the heat transfer have been derived. The provided correlations are to be used in a coupled numerical model of the chip formation process which also includes the effects of the heat transfer to the coolant lubricant.

Keywords

circular sawing, cutting gap, heat transfer, impingement flow, internal coolant supply, lubricant

ASJC Scopus subject areas

Energy(all)
Renewable Energy, Sustainability and the Environment
Energy(all)
Fuel Technology
Engineering(all)
Engineering (miscellaneous)
Energy(all)
Energy Engineering and Power Technology
Energy(all)
Energy (miscellaneous)
Mathematics(all)
Control and Optimization
Engineering(all)
Electrical and Electronic Engineering

Sustainable Development Goals

SDG 7 - Affordable and Clean Energy

Cite this

Assessment of the Heat Transfer Conditions in the Cavity of a Rotating Circular Saw. / Stegmann, Jan; Baumert, Moritz; Kabelac, Stephan et al.
In: ENERGIES, Vol. 17, No. 13, 3189, 28.06.2024.

Research output: Contribution to journal › Article › Research › peer review

Stegmann, J, Baumert, M, Kabelac, S, Menze, C, Ramme, J & Möhring, HC 2024, 'Assessment of the Heat Transfer Conditions in the Cavity of a Rotating Circular Saw', ENERGIES, vol. 17, no. 13, 3189. https://doi.org/10.3390/en17133189

Stegmann, J., Baumert, M., Kabelac, S., Menze, C., Ramme, J., & Möhring, H. C. (2024). Assessment of the Heat Transfer Conditions in the Cavity of a Rotating Circular Saw. ENERGIES, 17(13), Article 3189. https://doi.org/10.3390/en17133189

Stegmann J, Baumert M, Kabelac S, Menze C, Ramme J, Möhring HC. Assessment of the Heat Transfer Conditions in the Cavity of a Rotating Circular Saw. ENERGIES. 2024 Jun 28;17(13):3189. doi: 10.3390/en17133189

Stegmann, Jan ; Baumert, Moritz ; Kabelac, Stephan et al. / Assessment of the Heat Transfer Conditions in the Cavity of a Rotating Circular Saw. In: ENERGIES. 2024 ; Vol. 17, No. 13.

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abstract = "To improve machining processes concerning the usage of lubricants, knowledge of the thermo-mechanical and thermo-fluid interactions at the cutting zone is of great importance. This study focuses on the description of the convective heat transfer which occurs during circular sawing when the lubricant is provided via an internal coolant supply. The highly complex flow field inside the cavity of the sawing process is separated into two distinct flow forms, an impingement and a channel flow. With the aid of experimental and numerical studies, the heat transfer characteristics of these two flow forms have been examined for water and a lubricant used in the circular sawing process. Studies have been conducted over a wide range of Reynolds numbers (impingement flow: (Formula presented.), channel flow: (Formula presented.)). Additionally, the variation in the inlet temperature of the fluid, as well as the variation in heating power, has been studied. Overall, the impingement flow yields a significantly higher heat transfer than the channel flow with Nu{\ss}elt-numbers ranging from 120 to 230, whereas the Nu{\ss}elt-numbers in the case of the channel flow range from 20 to 160. For both flow forms, the use of the lubricant results in a better heat transfer compared with the usage of water. With the aid of these studies, correlations to describe the heat transfer have been derived. The provided correlations are to be used in a coupled numerical model of the chip formation process which also includes the effects of the heat transfer to the coolant lubricant.",

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Research@Leibniz University