TY - JOUR
T1 - Supercritical carbon dioxide and minimum quantity lubrication in pendular surface grinding – A feasibility study
AU - Arafat, Robar
AU - Madanchi, Nadine
AU - Thiede, Sebastian
AU - Herrmann, Christoph
AU - Skerlos, Steven J.
N1 - Publisher Copyright:
© 2021 Elsevier Ltd
PY - 2021/5/10
Y1 - 2021/5/10
N2 - Economic and environmental disadvantages of conventional cutting fluids based on mineral oil drive the research for alternative methods such as dry cutting, cutting with alternative cutting fluids and/or minimum quantity lubrication. Oil-in-air minimum quantity lubrication is a frequently discussed method in literature. However, this technique only provides lubrication without sufficient cooling and is therefore often combined with cryogenic fluids such as liquid nitrogen. In recent research, the use of minimum quantity lubrication combined with supercritical carbon dioxide is used. This research focus on processes with geometrically defined cutting edges. The relevant literature can therefore not describe the use of minimum quantity lubrication combined with supercritical carbon dioxide in cutting-fluid-intense processes such as grinding. Regarding this research gap, a conducted feasibility study is presented in this paper as first approach to understand the potentials and barriers using supercritical carbon dioxide in surface grinding processes. In a novel MQL-scCO2 grinding application, the research includes the evaluation of a nozzle application, grinding forces, surface roughnesses, cutting power and the grinding wheel clogging using supercritical carbon dioxide in grinding. It was found that the use of supercritical carbon dioxide in combination with minimum quantity lubrication overall leads to lower or similar forces and cutting power compared to conventional cooling lubrication with emulsion. It was also determined that, in its current state of development, the surface roughness increases. Hence, further research is needed, specifically in the topics of an optimized nozzle construction, thermal analysis and dressing characteristics. A simplified evaluation of energy performance indicators shows a potential to cleaner production compared to a conventional system.
AB - Economic and environmental disadvantages of conventional cutting fluids based on mineral oil drive the research for alternative methods such as dry cutting, cutting with alternative cutting fluids and/or minimum quantity lubrication. Oil-in-air minimum quantity lubrication is a frequently discussed method in literature. However, this technique only provides lubrication without sufficient cooling and is therefore often combined with cryogenic fluids such as liquid nitrogen. In recent research, the use of minimum quantity lubrication combined with supercritical carbon dioxide is used. This research focus on processes with geometrically defined cutting edges. The relevant literature can therefore not describe the use of minimum quantity lubrication combined with supercritical carbon dioxide in cutting-fluid-intense processes such as grinding. Regarding this research gap, a conducted feasibility study is presented in this paper as first approach to understand the potentials and barriers using supercritical carbon dioxide in surface grinding processes. In a novel MQL-scCO2 grinding application, the research includes the evaluation of a nozzle application, grinding forces, surface roughnesses, cutting power and the grinding wheel clogging using supercritical carbon dioxide in grinding. It was found that the use of supercritical carbon dioxide in combination with minimum quantity lubrication overall leads to lower or similar forces and cutting power compared to conventional cooling lubrication with emulsion. It was also determined that, in its current state of development, the surface roughness increases. Hence, further research is needed, specifically in the topics of an optimized nozzle construction, thermal analysis and dressing characteristics. A simplified evaluation of energy performance indicators shows a potential to cleaner production compared to a conventional system.
KW - Cutting fluid
KW - Grinding
KW - Minimum quantity lubrication (MQL)
KW - Supercritical carbon dioxide (scCO)
KW - Sustainable manufacturing
UR - http://www.scopus.com/inward/record.url?scp=85102137189&partnerID=8YFLogxK
U2 - 10.1016/j.jclepro.2021.126560
DO - 10.1016/j.jclepro.2021.126560
M3 - Article
AN - SCOPUS:85102137189
SN - 0959-6526
VL - 296
JO - Journal of cleaner production
JF - Journal of cleaner production
M1 - 126560
ER -