Abstract
Abstract The development of thin-film sensors for temperature and wear measurement in machining operations is presented in this work. A functional thin-film system, consisting of an Al2O3 insulation layer, a chromium sensor layer structured by photolithography and an Al2O3 wear-protection and insulation layer, is deposited by physical vapor deposition (PVD) processes onto the surface of cemented carbide cutting inserts. First specimen of the sensors are successfully fabricated and tested in laboratory experiments as well as in machining operations to demonstrate their functionality. These tool-integrated sensors can be used as an in-process monitoring device to determine the temperatures on the rake face at or close to the tool-chip contact area and to measure the progress of the flank-wear land width. The knowledge of these important process parameters opens up the possibility to develop new in-process control mechanisms in order to modify and improve the surface integrity of manufactured components. Thereby, their performance and lifetime can be enhanced.
Highlights
The development of thin-film sensors for temperature and wear measurement in machining operations is presented in this work
A functional thin-film system, consisting of an Al2O3 insulation layer, a chromium sensor layer structured by photolithography and an Al2O3 wear-protection and insulation layer, is deposited by physical vapor deposition (PVD) processes onto the surface of cemented carbide cutting inserts
First specimen of the sensors are successfully fabricated and tested in laboratory experiments as well as in machining operations to demonstrate their functionality. These tool-integrated sensors can be used as an in-process monitoring device to determine the temperatures on the rake face at or close to the tool-chip contact area and to measure the progress of the flank-wear land width
Summary
Cutting tool temperature and wear measurements during machining still present a challenge to the manufacturing industries. In the case of coated tools, due to abrasive wear and the reduction of coating material, the thermal properties of the cutting tool change, which modifies the heat flux of the process. This results in greater heat transfer to the cutting tool affecting the wear mechanism and the surface integrity of the workpiece [4]. Tool integrated thin-film sensors for measuring temperature at the tool-chip contact area, crater and flank tool wear are presented.
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