Wear Mechanisms and Wear Model of Carbide Tools during Dry Drilling of CFRP/TiAl6V4 Stacks

Wear Mechanisms and Wear Model of Carbide Tools during Dry Drilling of CFRP/TiAl6V4 Stacks

The present contribution on tool wear during the drilling of carbon fiber composite materials (CFRP)/Ti stacks intends to determine (i) if the adhesion of titanium to carbide is mechanical or chemical, (ii) the possible diffusion path, (iii) if the titanium is the only element involved in the adhesi...

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Main Authors: Unai Alonso Pinillos, Severo Raúl Fernández Vidal, Madalina Calamaz, Franck Andrés Girot Mata
Format: Article
Language:English
Published: MDPI AG 2019-09-01
Series:Materials
Subjects:
carbide wear
CFRP
titanium alloy
abrasion
metal adhesion
Online Access:https://www.mdpi.com/1996-1944/12/18/2843
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spelling doaj-a04dccb3a8bb46519f60bfa945d2b4772020-11-25T01:46:07ZengMDPI AGMaterials1996-19442019-09-011218284310.3390/ma12182843ma12182843Wear Mechanisms and Wear Model of Carbide Tools during Dry Drilling of CFRP/TiAl6V4 StacksUnai Alonso Pinillos0Severo Raúl Fernández Vidal1Madalina Calamaz2Franck Andrés Girot Mata3Department of Mechanical Engineering, University of the Basque Country (UPV/EHU), 48013 Bilbao, SpainDepartment of Mechanical Engineering & Industrial Design, Faculty of Engineering, University of Cadiz, Av. Universidad de Cadiz 10, E-11519 Puerto Real-Cadiz, SpainArts et Métiers, I2M, UMR 5295, Esplanade des Arts et Métiers, F-33405 Talence CEDEX, FranceDepartment of Mechanical Engineering, University of the Basque Country (UPV/EHU), 48013 Bilbao, SpainThe present contribution on tool wear during the drilling of carbon fiber composite materials (CFRP)/Ti stacks intends to determine (i) if the adhesion of titanium to carbide is mechanical or chemical, (ii) the possible diffusion path, (iii) if the titanium is the only element involved in the adhesion and (iv) the role of the CFRP in this wear. The overall tool wear is not the sum of the wear in each material and there is a multiplicative effect between them. It has been pointed out that the maximum temperature reached during drilling is higher than 180 °C, 400 °C and 750 °C respectively in the CFRP and Ti plates alone and in the Ti part of the stack. As tungsten carbide CW is not in equilibrium with titanium above 250 °C, the diffusion path is CW/(Ti,W)C/Ti as confirmed by Auger analysis. For temperatures above 500 °C, (Ti,W)C becomes very sensitive to oxidation allowing a friable oxycarbide (Ti,C,O) to form, which explains the erosion of the tool. The CW is therefore the weakest link in the drilling of CFRP/Ti stacks. Improving the performance of the tool involves the use of a coating, the development of a tool material having low chemical affinity with Ti and/or the use of cryogenic lubricant.https://www.mdpi.com/1996-1944/12/18/2843carbide wearCFRPtitanium alloyabrasionmetal adhesion
collection DOAJ
language English
format Article
sources DOAJ
author Unai Alonso Pinillos
Severo Raúl Fernández Vidal
Madalina Calamaz
Franck Andrés Girot Mata
spellingShingle Unai Alonso Pinillos
Severo Raúl Fernández Vidal
Madalina Calamaz
Franck Andrés Girot Mata
Wear Mechanisms and Wear Model of Carbide Tools during Dry Drilling of CFRP/TiAl6V4 Stacks
Materials
carbide wear
CFRP
titanium alloy
abrasion
metal adhesion
author_facet Unai Alonso Pinillos
Severo Raúl Fernández Vidal
Madalina Calamaz
Franck Andrés Girot Mata
author_sort Unai Alonso Pinillos
title Wear Mechanisms and Wear Model of Carbide Tools during Dry Drilling of CFRP/TiAl6V4 Stacks
title_short Wear Mechanisms and Wear Model of Carbide Tools during Dry Drilling of CFRP/TiAl6V4 Stacks
title_full Wear Mechanisms and Wear Model of Carbide Tools during Dry Drilling of CFRP/TiAl6V4 Stacks
title_fullStr Wear Mechanisms and Wear Model of Carbide Tools during Dry Drilling of CFRP/TiAl6V4 Stacks
title_full_unstemmed Wear Mechanisms and Wear Model of Carbide Tools during Dry Drilling of CFRP/TiAl6V4 Stacks
title_sort wear mechanisms and wear model of carbide tools during dry drilling of cfrp/tial6v4 stacks
publisher MDPI AG
series Materials
issn 1996-1944
publishDate 2019-09-01
description The present contribution on tool wear during the drilling of carbon fiber composite materials (CFRP)/Ti stacks intends to determine (i) if the adhesion of titanium to carbide is mechanical or chemical, (ii) the possible diffusion path, (iii) if the titanium is the only element involved in the adhesion and (iv) the role of the CFRP in this wear. The overall tool wear is not the sum of the wear in each material and there is a multiplicative effect between them. It has been pointed out that the maximum temperature reached during drilling is higher than 180 °C, 400 °C and 750 °C respectively in the CFRP and Ti plates alone and in the Ti part of the stack. As tungsten carbide CW is not in equilibrium with titanium above 250 °C, the diffusion path is CW/(Ti,W)C/Ti as confirmed by Auger analysis. For temperatures above 500 °C, (Ti,W)C becomes very sensitive to oxidation allowing a friable oxycarbide (Ti,C,O) to form, which explains the erosion of the tool. The CW is therefore the weakest link in the drilling of CFRP/Ti stacks. Improving the performance of the tool involves the use of a coating, the development of a tool material having low chemical affinity with Ti and/or the use of cryogenic lubricant.
topic carbide wear
CFRP
titanium alloy
abrasion
metal adhesion
url https://www.mdpi.com/1996-1944/12/18/2843
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