Adaptation of Fracture Mechanics Methods for Quality Assessment of Tungsten Carbide Cutting Inserts

Adaptation of Fracture Mechanics Methods for Quality Assessment of Tungsten Carbide Cutting Inserts

Tungsten carbide (WC) is well known as one of the hardest materials widely used in machining, cutting and drilling, especially for cutting tools production. Knowing fracture toughness grants the opportunity to prevent catastrophic wear of a tool. Moreover, fracture toughness of WC-based materials ma...

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Main Authors: Sylwester Samborski, Jerzy Józwik, Jakub Skoczylas, Mariusz Kłonica
Format: Article
Language:English
Published: MDPI AG 2021-06-01
Series:Materials
Subjects:
tungsten carbide
fracture toughness
Charpy impact test
three-point bending test
fractography
Online Access:https://www.mdpi.com/1996-1944/14/13/3441
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spelling doaj-f56add5957ee4304a0e1177e7b1456182021-07-15T15:40:02ZengMDPI AGMaterials1996-19442021-06-01143441344110.3390/ma14133441Adaptation of Fracture Mechanics Methods for Quality Assessment of Tungsten Carbide Cutting InsertsSylwester Samborski0Jerzy Józwik1Jakub Skoczylas2Mariusz Kłonica3Faculty of Mechanical Engineering, Lublin University of Technology, Nadbystrzycka 36, 20-618 Lublin, PolandFaculty of Mechanical Engineering, Lublin University of Technology, Nadbystrzycka 36, 20-618 Lublin, PolandFaculty of Mechanical Engineering, Lublin University of Technology, Nadbystrzycka 36, 20-618 Lublin, PolandFaculty of Mechanical Engineering, Lublin University of Technology, Nadbystrzycka 36, 20-618 Lublin, PolandTungsten carbide (WC) is well known as one of the hardest materials widely used in machining, cutting and drilling, especially for cutting tools production. Knowing fracture toughness grants the opportunity to prevent catastrophic wear of a tool. Moreover, fracture toughness of WC-based materials may vary because of different material compositions, as well as a different way of production. Hence, each material should be treated individually. In this paper, SM25T (HW) tungsten carbide (HW—uncoated grade, TNMR 401060 SM25T, manufactured by Baildonit company, Katowice, Poland) was taken into consideration. Sintered carbides—designated as S—are designed to be applied for machining steel, cast steel and malleable cast iron. Fracture mechanics methods were adapted to make a quality assessment of WC cutting inserts. Both quasi-statical three-point bending tests, as well as Charpy dynamic impact tests, were performed to calculate static and dynamic fracture toughness (<i>K</i><sub>IC</sub> and <i>K</i><sub>ID</sub>, respectively). In addition, a special emphasis was placed on the microscopic analysis of fracture surfaces after impact tests to discuss material irregularities, such as porosity, cracks and so-called “river patterns”. There is a lack of scientific works in this field of study. However, cutting engineers are interested in obtaining the experimental results of that kind. Although there are a few standardized methods that may be used to determine fracture toughness of hard metals, none of them is expected to be the most reliable. Moreover, there is a lack of scientific works in the field of determining static and dynamic fracture toughness of WC by the presented method. The proposed examination solution can be then successfully used to calculate toughness properties of WC-based materials, as the results obtained seem to be with a good agreement with other works.https://www.mdpi.com/1996-1944/14/13/3441tungsten carbidefracture toughnessCharpy impact testthree-point bending testfractography
collection DOAJ
language English
format Article
sources DOAJ
author Sylwester Samborski
Jerzy Józwik
Jakub Skoczylas
Mariusz Kłonica
spellingShingle Sylwester Samborski
Jerzy Józwik
Jakub Skoczylas
Mariusz Kłonica
Adaptation of Fracture Mechanics Methods for Quality Assessment of Tungsten Carbide Cutting Inserts
Materials
tungsten carbide
fracture toughness
Charpy impact test
three-point bending test
fractography
author_facet Sylwester Samborski
Jerzy Józwik
Jakub Skoczylas
Mariusz Kłonica
author_sort Sylwester Samborski
title Adaptation of Fracture Mechanics Methods for Quality Assessment of Tungsten Carbide Cutting Inserts
title_short Adaptation of Fracture Mechanics Methods for Quality Assessment of Tungsten Carbide Cutting Inserts
title_full Adaptation of Fracture Mechanics Methods for Quality Assessment of Tungsten Carbide Cutting Inserts
title_fullStr Adaptation of Fracture Mechanics Methods for Quality Assessment of Tungsten Carbide Cutting Inserts
title_full_unstemmed Adaptation of Fracture Mechanics Methods for Quality Assessment of Tungsten Carbide Cutting Inserts
title_sort adaptation of fracture mechanics methods for quality assessment of tungsten carbide cutting inserts
publisher MDPI AG
series Materials
issn 1996-1944
publishDate 2021-06-01
description Tungsten carbide (WC) is well known as one of the hardest materials widely used in machining, cutting and drilling, especially for cutting tools production. Knowing fracture toughness grants the opportunity to prevent catastrophic wear of a tool. Moreover, fracture toughness of WC-based materials may vary because of different material compositions, as well as a different way of production. Hence, each material should be treated individually. In this paper, SM25T (HW) tungsten carbide (HW—uncoated grade, TNMR 401060 SM25T, manufactured by Baildonit company, Katowice, Poland) was taken into consideration. Sintered carbides—designated as S—are designed to be applied for machining steel, cast steel and malleable cast iron. Fracture mechanics methods were adapted to make a quality assessment of WC cutting inserts. Both quasi-statical three-point bending tests, as well as Charpy dynamic impact tests, were performed to calculate static and dynamic fracture toughness (<i>K</i><sub>IC</sub> and <i>K</i><sub>ID</sub>, respectively). In addition, a special emphasis was placed on the microscopic analysis of fracture surfaces after impact tests to discuss material irregularities, such as porosity, cracks and so-called “river patterns”. There is a lack of scientific works in this field of study. However, cutting engineers are interested in obtaining the experimental results of that kind. Although there are a few standardized methods that may be used to determine fracture toughness of hard metals, none of them is expected to be the most reliable. Moreover, there is a lack of scientific works in the field of determining static and dynamic fracture toughness of WC by the presented method. The proposed examination solution can be then successfully used to calculate toughness properties of WC-based materials, as the results obtained seem to be with a good agreement with other works.
topic tungsten carbide
fracture toughness
Charpy impact test
three-point bending test
fractography
url https://www.mdpi.com/1996-1944/14/13/3441
work_keys_str_mv AT sylwestersamborski adaptationoffracturemechanicsmethodsforqualityassessmentoftungstencarbidecuttinginserts
AT jerzyjozwik adaptationoffracturemechanicsmethodsforqualityassessmentoftungstencarbidecuttinginserts
AT jakubskoczylas adaptationoffracturemechanicsmethodsforqualityassessmentoftungstencarbidecuttinginserts
AT mariuszkłonica adaptationoffracturemechanicsmethodsforqualityassessmentoftungstencarbidecuttinginserts
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