Study on the Properties of Coated Cutters on Functionally Graded WC-Co/Ni-Zr Substrates with FCC Phase Enriched Surfaces
by
Shidi Li
1, 
Xiangyuan Xue
1,
Jiaxing Chen
1,
Tengxuan Lu
1,
Zhe Zhao
1,
Xin Deng
1,*,
Zhongliang Lu
2,3,
Zhongping Wang
4,
Zhangxu Li
4 and
Zhi Qu
5 1
School of Electromechanical Engineering, Guangdong University of Technology, Guangzhou 510006, China
2
State Key Laboratory for Manufacturing Systems Engineering, Xi’an Jiaotong University, Xi’an 710049, China
3
Guangdong Xi’an Jiaotong University Academy, Foshan 528300, China
4
Heyuan Fuma Cemented Carbide Co., Ltd., Heyuan 517583, China
5
Guangdong Jin Ci San Wei Tech-Ltd., Foshan 528225, China
*
Author to whom correspondence should be addressed.
Crystals 2021, 11(12), 1538; https://doi.org/10.3390/cryst11121538
Submission received: 20 November 2021
/
Revised: 4 December 2021
/
Accepted: 6 December 2021
/
Published: 9 December 2021
(This article belongs to the Special Issue Additive Manufacturing (AM) for Advanced Materials and Structures: Green and Intelligent Development Trend)
Abstract
:Currently, the research on mechanical behavior and cutting performance of functionally graded carbides is quite limited, which limits the rapid development of high-performance cemented carbide cutting tools. Based on WC-Co-Zr and WC-Ni-Zr, this study synthesized two kinds of cemented carbide cutters, i.e., the cemented carbide cutters with homogeneous microstructure and functionally graded carbide (FGC) cutters with FCC phase ZrN-enriched surfaces. Furthermore, TiAlN coating has been investigated on these carbide cutters. Mechanical behavior, friction, wear performance, and cutting behavior have been investigated for these coated carbides and their corresponding substrates. It was found that, as compared with coated cutters on WC-Co/Ni-Zr carbide substrates with homogeneous microstructures, the coated cutters on WC-Co/Ni-Zr FGC substrates with FCC phase-enriched surfaces show higher wear resistance and cutting life, and the wear mechanism during cutting is mainly adhesion wear.
1. Introduction
Cemented carbides, as ceramic matrix composites consisting of carbide matrix (mainly WC, TiC, and TaC, etc.) and metal binders, have been widely used as cutting tools, molds, and mining and petroleum drilling tools due to their high hardness, strength, wear resistance, excellent oxidation resistance, and thermal stability [1,2,3,4,5,6,7]. With the rapid development of the modern manufacturing industry, more crucial requirements, such as simultaneously high wear resistance and high toughness, are being put forward on the performance of cemented carbides [8,9]. In order to obtain better properties, current development on cemented carbides is mainly focused on functionally graded carbides (FGCs) and cemented carbide coatings [10,11,12,13,14]. The FGCs shows gradient microstructures from surface to internal portion, which provides both higher wear resistance (surface) and toughness (internal portion) and hence better overall performance than conventional carbide with homogeneous microstructure [15,16,17,18,19]. The FGCs mainly include dual-phase FGC [20,21], the FGCs with binder phase-enriched surfaces [22,23], and the FGCs with face center cubic (FCC) phase-enriched surfaces [24]. The main preparation method of the FGC with an FCC phase-enriched surface is the nitriding method [25], which converts N in the sintering atmosphere and the elements (such as Ti, Zr, etc.) in carbides into nitride or carbon–nitride compounds of face-centered cubic crystals by thermal–chemical coupling, and then obtains the functionally graded carbide with FCC phase-enriched surface [26].
At present, there are quite limited study on the cutting performance of the FGCs with FCC phase-enriched surface, especially on the cutting performance of coated cutters on FGC substrates with FCC phase-enriched surface. This paper focuses on the microstructure, mechanical properties, and cutting properties of coated cutters on FGC substrates with FCC phase-enriched surface. The high-performance carbide cutters investigated in this study has potential applications in future additive/subtractive hybrid manufacturing.
2. Materials and Methods
The composition, gradient structure, and coating types of WC-Co/Ni-Zr cemented carbide are shown in Table 1. The feedstock powders of WC, Co, Ni, Zr, and others with an average particle size of 1 μm were weighed according to the composition in Table 1 and then put into a planetary ball mill with 2 wt.% paraffin wax and an appropriate amount of n-heptane and mixed for 24 h. The wet powder mixture slurry was dried in a rotary evaporator, and then pressed at 300 MPa into 18 mm × 18 mm × 6 mm cutter billets. Afterwards, the cutter billets were dewaxed in a tube furnace at 400–550 °C in an argon atmosphere. The dewaxed cutter billets were sinter-hipped in a two-step process. Firstly, the dewaxed parts were sintered at 1450 °C for 30 min in an argon atmosphere at the pressure of 6 MPa. After furnace cooling, the pre-sintered parts were machined into a cutter shape of 12.5 mm × 12.5 mm × 5 mm and then polished. Secondly, all the machined parts were further sintered at 1450 °C in a nitrogen atmosphere at a pressure of 6 MPa for 60 min to prepare the functionally graded cemented carbides (FGCs) with FCC phase-enriched surface. The dewaxing and sintering processes are shown in Figure 1. Two-step sintering is critical to the mechanical and frictional properties of FGCs. The first step of sintering with high pressure Argon results in the full density of carbides and the second step of sintering with high pressure nitrogen leads to the formation of gradient microstructure of FGCs. Upon two-step sintering, the FGCs achieve the high wear resistance of surface and the high toughness of the inner portion.
In order to analyze the difference in properties between FGCs and conventional cemented carbides with homogeneous microstructure, the same WC-Co-Zr and WC-Ni-Zr parts were sintered in one-step sinter-hip process at 1450 °C for 90 min with 6 MPa argon atmosphere to prepare the conventional cemented carbide with homogeneous microstructure. Finally, TiAlN coating was deposited on the above the FGCs and the conventional carbides with homogeneous microstructure by PVD method.
Zeiss Merlin high-resolution field emission electron microscope and energy spectrometer (Zeiss, Oberkochen, Germany) were used for microstructure and composition analysis. Nanoindentation was used to measure the coating hardness with a load of 10 mN. The bonding strength between coating and carbide substrate was measured by the RST3 Large Load Scratcher [27,28]. The UMT-TriboLab friction and wear tester (Bruker, Billerica, MA, USA) was used to test the wear resistance, friction, and wear performance of carbides. The GCr15 ball was used for the friction test of uncoated carbides with a load of 50 N, the Si3N4 ceramic ball was used for the friction test of coated cutters with a load of 10 N, and both friction tests had a turning radius of 4 mm and a speed of 400 r/min. The ETC3650h CNC lathe (SMTCL, Shenyang, China) was used for cutting test and an HT250, a gray cast iron with yield strength of 250 MPa, was used as the workpiece. The cutting speed was 200 m/min, the back cutting depth was 0.3 mm, and the feed rate was 0.1 mm/r.
3. Results and Discussion
3.1. Functionally Graded Cemented Carbides
3.1.1. Microstructure of FGCs
Figure 2 and Figure 3 show the microstructure and EDS element distribution of WC-Co-Zr and WC-Ni-Zr FGCs, respectively. The gradient layer thickness of WC-Co-Zr is significantly lower than that of WC-Ni-Zr. Both carbide surfaces contained mainly Zr and N, and the FCC phase ZrN was formed during the high-pressure nitriding process [15]. Figure 4 shows the XRD of both FC-5 and FN-1, which confirms the formation of FCC phase ZrN during high pressure nitriding process.
3.1.2. Friction and Wear Properties of FGCs
Figure 5 shows the friction coefficient curves of four cemented carbides. The curves can be divided into two stages: the running-in wear stage and the normal friction stage. The curves C and D in Figure 5 represent friction coefficient curves of two FGCs with FCC phase-enriched surfaces (FC5-2, FN1-2). Compared with the carbides with homogeneous microstructure, i.e., A (FC5-1) and B (FN1-1), the friction coefficient curves of the FGCs show abrupt drop in the normal friction stage, which is due to the complete wearing off of the ZrN surface layer and the exposure of the inner part of FGCs. Figure 2 and Figure 3 show that the thickness of the surface gradient layer of WC-Ni-Zr is significantly thicker than that of WC-Co-Zr, so it takes a longer time before the mutation of friction coefficient for WC-Ni-Zr, as compared with that for WC-Co-Zr. Figure 5 also shows that quite different from the friction behavior of conventional carbides, the formation of ZrN on the FGC surface can effectively reduce the friction coefficient.
Figure 6 shows the comparison of wear rates of four cemented carbides. It can be seen that the wear rate of the FGCs is significantly lower than that of conventional carbides with homogeneous microstructure, indicating that a ZrN layer formed on the surface of the FGCs can significantly improve the wear resistance. Further, the wear rate of the WC-Co-Zr FGCs is slightly lower than that of the WC-Ni-Zr FGCs.
3.2. Coated Cutters with FGC and Conventional Carbide Substrates
3.2.1. Microstructure of Coated Cutters
Figure 7 shows the cross-sectional microstructures of four coated carbides. Two types of coated cutters on conventional carbide substrates with homogeneous microstructure have no cracks around the interface between the coating and the substrate, but there are some micro-cracks for the coated cutters on the WC-Ni-Zr FGC substrate (FN1-4).
3.2.2. Bonding Strength between Carbide Substrate and Coating
Figure 8 shows the bonding strength and scratch morphology of the coated cutters. It shows that for WC-Co-Zr, the bonding strength between coating and the FGC substrate is about 15% higher than that between coating and the conventional carbide substrate. However, for WC-Ni-Zr carbide, bonding strength shows the opposite trend, mainly due to the obvious microcracks between the FGC substrate and the coating. The average hardness of the coatings, measured by nanoindentation, is 32.17 GPa.
3.2.3. Friction and Wear Performance of Coated Carbides
Figure 9 is the friction coefficient curves of four coated carbides. It can be observed that for both coated WC-Co-Zr with either conventional carbide substrate (curve A) or FGC substrate (curve B), the friction coefficient shows substantial fluctuation, and the friction coefficient of coated WC-Co-Zr with FGC substrate is noticeably lower than that of coated WC-Co-Zr with conventional carbide substrate. For coated WC-Ni-Zr, the friction coefficient corresponding to FGC substrate (curve C) is quite similar to that corresponding to conventional carbide substrate, while the former has wider fluctuation, which is mainly caused by the apparent more micro-cracks of the former, as shown in Figure 7d.
Figure 10 shows the wear rates of four coated carbides. The coated WC-Co-Zr with FGC substrate shows the lowest wear rate, while the coated WC-Ni-Zr with FGC substrate have the highest wear rate due to the existence of micro-cracks.
3.3. Cutting Performance of Coated Carbide Cutters
3.3.1. Carbide Cutters
The wear and cutting behavior of FGCs is quite different from those of conventional carbides [17,29]. In this study, both the FGCs and conventional carbides listed in Table 1 were used as the cutters and HT250 was used as the workpiece for cutting experiments. The cutting test parameters are shown in Section 1.
3.3.2. Cutting Life
According to ISO-3685, the criterion for cutter failure is average wear of 0.3 mm on flank face of cutters. Figure 11 and Figure 12 show the dimension of wear vs. time on the flank face of four carbide cutters during cutting test of HT250. It can be seen that the cutting life of WC-Co-Zr is significantly higher than that of WC-Ni-Zr. For WC-Co-Zr, the cutting life of uncoated FGC cutter is about 1.23 times that of conventional carbide cutter with homogeneous microstructure, and the cutting life of the coated cutter with FGC substrate is 1.11 times that of the coated cutter with conventional carbide substrate. While for WC-Ni-Zr, the corresponding cutting life improvement of uncoated and coated FGC vs. conventional carbide is 1.54 times and 1.19 times, respectively.
3.3.3. Wear Mechanism Analysis
The wear of flank face is commonly used to assess the failure modes of carbide cutters and can be classified as adhesive wear, diffusion wear, abrasive wear, and oxidation wear [30,31,32].
Figure 13 shows the flank face of WC-Co-Zr cutters after the cutting test. The failure modes are mainly adhesive wear, a certain degree of spalling of coating, and abrasive wear of the cutter tip. Table 2 is the EDS results at Point 1 and Point 2 on the flank face in Figure 13. EDS analysis shows that the gray region (Point 1) is the adhesive material (HT250), and the bright region (Point 2) is the exposed carbide substrate after the coating is worn off. The low content of oxygen indicates limited oxidation wear at the high cutting temperature. Furthermore, it can be seen in Figure 13 that there is much less adhesion on flank face of the coated cutters than that on flank face of the uncoated cutters.
Figure 14 shows the morphology of flank face of WC-Ni-Zr after cutting test. The wear modes of WC-Ni-Zr cutters also include mainly adhesive wear, which is the main wear mode of cemented carbide cutters at low and medium cutting speeds [30]. The spalling of coating also occurs and is more severe than that for WC-Co-Zr cutters. Table 3 shows the EDS analysis of the points in Figure 14. Compared with the WC-Co-Zr, the oxidation wear for WC-Ni-Zr is more serious.
4. Conclusions
In this study, WC-Co/Ni-Zr cemented carbides with homogeneous microstructure (conventional carbides) and the corresponding FGCs with ZrN (face centered cubic phase)-enriched surfaces were successfully synthesized using a high-pressure nitriding process. TiAlN coatings were prepared on these carbide substrates by a PVD process, and the mechanical and friction behaviors and cutting test were carried out on these coated and uncoated carbides. It was found that for WC-Co-Zr, friction coefficient and wear rate of coated and uncoated FGCs were, respectively, 20% and 17% lower than those of coated and uncoated conventional carbides and for WC-Ni-Zr; uncoated FGC also shows 14% lower friction coefficient and 26% lower wear rate than uncoated conventional carbide, while the coated FGC shows wider fluctuation of friction coefficient and 5% higher wear rate as compared with coated conventional carbide. For WC-Co-Zr, the bonding strength between the coating and the FGC substrate is 18% higher than that between the coating and the conventional carbide substrate, while for WC-Ni-Zr, the bonding strength between the coating and the FGC substrate, due to micro-cracks, is 10% lower than that between the coating and the conventional carbide substrate. The cutting tests showed that the cutting life of WC-Co-Zr cutters is about 85% higher than that of WC-Ni-Zr cutters, and the coated FGCs show 16% higher cutting life than the coated conventional carbides, followed by the uncoated FGCs, and the uncoated conventional carbides. The cutting test for HT250 shows the main wear mechanism is adhesive wear for all the carbide cutters.
Author Contributions
Conceptualization, X.D. and Z.L. (Zhongliang Lu); methodology, S.L.; investigation, X.X., J.C. and T.L.; formal analysis, Z.Z.; data curation, Z.L. (Zhangxu Li); resources, Z.W.; writing—original draft preparation, S.L.; writing—review and editing, X.D. and Z.L. (Zhongliang Lu); supervision, Z.Q.; project administration, X.D. and Z.Q.; funding acquisition, Z.L. (Zhongliang Lu), X.D., Z.W. and Z.Q. All authors have read and agreed to the published version of the manuscript.
Funding
This research was funded by Science and Technology Project of Guangdong Province, China (Grant No. 2017B090911006), Jihua Laboratory Project (Grant No. X190061UZ190), Foshan Science and Technology Innovation Team project (FS0AA-KJ919-4402-0023), and Heyuan Science and Technology Project (Grant No. HEKE 000781).
Institutional Review Board Statement
Not applicable.
Informed Consent Statement
Not applicable.
Data Availability Statement
Not applicable.
Conflicts of Interest
The authors declare no conflict of interest.
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Figure 1.
Dewaxing and two-step sinter-hip process for FGCs.
Figure 2.
Microstructure and EDS element mapping of FC5-2, (a) microstructure, and (b–f) respective element mappings of Zr, W, Co, N, and C.
Figure 2.
Microstructure and EDS element mapping of FC5-2, (a) microstructure, and (b–f) respective element mappings of Zr, W, Co, N, and C.
Figure 3.
Microstructure and EDS element mapping of FN1-2, (a) microstructure, and (b–f) respective element mappings of Zr, W, N, Ni, and C.
Figure 3.
Microstructure and EDS element mapping of FN1-2, (a) microstructure, and (b–f) respective element mappings of Zr, W, N, Ni, and C.
Figure 4.
XRD of the surfaces of (a) FC5-2 and (b) FN1-2.
Figure 5.
The friction testing curves for both FGCs and conventional carbides.
Figure 6.
Wear rates of FGCs and conventional carbides.
Figure 7.
Cross-sectional microstructures of four coated cutters on FGC and conventional carbide substrates, (a) FC5-3, (b) FC5-4, (c) FN1-3, and (d) FN1-4.
Figure 7.
Cross-sectional microstructures of four coated cutters on FGC and conventional carbide substrates, (a) FC5-3, (b) FC5-4, (c) FN1-3, and (d) FN1-4.
Figure 8.
Bonding between carbide substrates and coatings, (a) bonding strength, and (b) scratching tests.
Figure 8.
Bonding between carbide substrates and coatings, (a) bonding strength, and (b) scratching tests.
Figure 9.
Friction coefficient curves of four coated carbides.
Figure 10.
Wear rate of four coated carbides.
Figure 11.
The flank wear VB vs. cutting time for WC-Co-Zr.
Figure 12.
The flank wear VB vs. cutting time for WC-Ni-Zr.
Figure 13.
Morphology of flank wear for WC-Co-Zr cutters, (a) FC5-1, (b) FC5-2, (c) FC5-3, and (d) FC5-4.
Figure 13.
Morphology of flank wear for WC-Co-Zr cutters, (a) FC5-1, (b) FC5-2, (c) FC5-3, and (d) FC5-4.
Figure 14.
Morphology of flank wear for WC-Ni-Zr cutters, (a) FN1-1, (b) FN1-2, (c) FN1-3, and (d) FN1-4.
Figure 14.
Morphology of flank wear for WC-Ni-Zr cutters, (a) FN1-1, (b) FN1-2, (c) FN1-3, and (d) FN1-4.
Table 1.
The composition, microstructure, and coating type of WC-Co/Ni-Zr cemented carbides.
| Carbides No. | Composition (wt.%) | Sintering Process | Microstructure | Coating |
|---|---|---|---|---|
| FC5-1 | WC-10Co-5Zr-0.5VC-2W | One-step/Ar | Homogeneous | Nothing |
| FC5-2 | WC-10Co-5Zr-0.5VC-2W | Two step /(Ar+N2) | Gradient | Nothing |
| FC5-3 | WC-10Co-5Zr-0.5VC-2W | One-step/Ar | Homogeneous | TiAlN |
| FC5-4 | WC-10Co-5Zr-0.5VC-2W | Two step /(Ar+N2) | Gradient | TiAlN |
| FN1-1 | WC-10Ni-5Zr-0.5VC | One-step/Ar | Homogeneous | Nothing |
| FN1-2 | WC-10Ni-5Zr-0.5VC | Two step /(Ar+N2) | Gradient | Nothing |
| FN1-3 | WC-10Ni-5Zr-0.5VC | One-step/Ar | Homogeneous | TiAlN |
| FN1-4 | WC-10Ni-5Zr-0.5VC | Two step /(Ar+N2) | Gradient | TiAlN |
Table 2.
The EDS results of Points 1 and 2 in Figure 12.
Table 2.
The EDS results of Points 1 and 2 in Figure 12.
| Area | Element Mass Fraction/% | |||||||
|---|---|---|---|---|---|---|---|---|
| C | O | Si | Zr | W | Fe | Mn | Co | |
| Point 1 | 7.06 | 1.77 | 2.27 | - | - | 88.91 | - | - |
| Point 2 | 11.5 | 1.98 | - | 11.58 | 71.41 | 2.78 | - | 1.2 |
Table 3.
The EDS results of Points 1 and 2 in Figure 13.
Table 3.
The EDS results of Points 1 and 2 in Figure 13.
| Area | Element Mass Fraction/% | |||||||
|---|---|---|---|---|---|---|---|---|
| C | O | Si | Zr | W | Fe | Mn | Co | |
| Point 1 | 7.03 | 1.97 | 0.18 | - | - | 89.12 | - | - |
| Point 2 | 9.63 | 2.62 | - | - | 76.72 | 9 | - | 2.02 |
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Li, S.; Xue, X.; Chen, J.; Lu, T.; Zhao, Z.; Deng, X.; Lu, Z.; Wang, Z.; Li, Z.; Qu, Z. Study on the Properties of Coated Cutters on Functionally Graded WC-Co/Ni-Zr Substrates with FCC Phase Enriched Surfaces. Crystals 2021, 11, 1538. https://doi.org/10.3390/cryst11121538
AMA Style
Li S, Xue X, Chen J, Lu T, Zhao Z, Deng X, Lu Z, Wang Z, Li Z, Qu Z. Study on the Properties of Coated Cutters on Functionally Graded WC-Co/Ni-Zr Substrates with FCC Phase Enriched Surfaces. Crystals. 2021; 11(12):1538. https://doi.org/10.3390/cryst11121538
Chicago/Turabian StyleLi, Shidi, Xiangyuan Xue, Jiaxing Chen, Tengxuan Lu, Zhe Zhao, Xin Deng, Zhongliang Lu, Zhongping Wang, Zhangxu Li, and Zhi Qu. 2021. "Study on the Properties of Coated Cutters on Functionally Graded WC-Co/Ni-Zr Substrates with FCC Phase Enriched Surfaces" Crystals 11, no. 12: 1538. https://doi.org/10.3390/cryst11121538
APA StyleLi, S., Xue, X., Chen, J., Lu, T., Zhao, Z., Deng, X., Lu, Z., Wang, Z., Li, Z., & Qu, Z. (2021). Study on the Properties of Coated Cutters on Functionally Graded WC-Co/Ni-Zr Substrates with FCC Phase Enriched Surfaces. Crystals, 11(12), 1538. https://doi.org/10.3390/cryst11121538
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