JP7486711B2 - WC-based cemented carbide and coated cutting tool using same - Google Patents

Description

The present invention relates to a WC-based cemented carbide and a coated cutting tool using the same.

Conventionally, cutting tools that use a WC-based cemented carbide substrate with high rigidity and hardness and coated with a ceramic hard coating with excellent wear resistance and oxidation resistance have been widely used in cutting metal materials. In a situation where the load on cutting tools increases with the hardness and high efficiency of workpiece materials, there is a demand for improving the heat resistance and chipping resistance of not only the hard coating but also the cemented carbide substrate. For example, Patent Documents 1 and 2 propose improving the chipping resistance of WC-Co-based cemented carbide with a composite addition of chromium (Cr) and tantalum (Ta) by homogenizing the structure.

JP 2017-88999 A JP 2013-244588 A

In recent years, there has been a demand for further cost reduction and shorter delivery times in the field of mold machining, and in cutting processes, efforts are being made to increase efficiency by increasing cutting speeds and using high feed conditions.
However, through investigations by the inventors, it has been confirmed that even when the conventionally proposed coated cutting tools using cemented carbide as a base material are used, chipping and plastic deformation still occur in high-speed cutting of steel and the like, particularly in high-speed cutting of mild steel, and therefore the tool life is insufficient.
Therefore, the inventors set out to provide a WC-based cemented carbide that does not cause chipping or plastic deformation as a substrate even when performing high-speed cutting of steel or the like, particularly when performing high-speed cutting of mild steel, and a coated cutting tool using the WC-based cemented carbide.

The inventors have found that by adjusting the content of Co constituting the binder phase, the content of Cr dissolved in the binder phase, and the content of Ta dissolved in the binder phase or dispersed in the structure to form the main component phase in the WC cemented carbide that serves as the base material of the coated cutting tool within predetermined ranges, and further specifying the range of the average grain size of particles having a specific circle equivalent grain size among the remaining WC grains, and the range of the ratio (D90/D10) of the grain size (D90) at which the integrated value of the area ratio in the grain size distribution of the circle equivalent grain size is 90% to the grain size (D10) at which the integrated value of the area ratio is 10%, and specifying that the main component phase of Ta is dispersed in the structure, it is possible to solve the problems of chipping and plastic deformation that occur in the base material when high-speed cutting of steel, etc., particularly high-speed cutting of mild steel, is performed.
The inventors have also discovered that by providing a hard coating having a TiCN coating on the surface of the substrate, the hard coating having at least a columnar structure and a predetermined average width on the surface side and including the maximum film thickness, and by providing an Al ₂ O ₃ coating on the upper layer of the TiCN coating, a coated cutting tool having even better chipping resistance and plastic deformation resistance can be obtained when performing high-speed machining of mild steel.

The present invention has been made based on the above findings,
"(1) A WC-based cemented carbide containing, by mass%, 8.5% to 9.5% Co, 0.3% to 1.0% Cr, and 1.0% to 3.0% Ta as metallic elements, with the balance being WC, non-metallic elements present in solid solution or in combination with the metallic elements, and unavoidable impurities,
The average grain size of WC grains having a circle-equivalent grain size of 0.4 μm or more is 1.0 μm or more and 2.0 μm or less,
D90/D10, which is the ratio of a particle size D90 at which the integrated value of the area ratio in the particle size distribution of the average particle size is 90% to a particle size D10 at which the integrated value of the area ratio is 10%, is less than 3.2;
A WC-based cemented carbide characterized in that a phase mainly composed of Ta is dispersed in the structure.
(2) A coated cutting tool having a substrate made of the WC-based cemented carbide according to (1) above and a hard coating layer on the surface thereof.
(3) The coated cutting tool according to (2), wherein the hard coating layer includes at least a TiCN coating layer, the TiCN coating layer is made of a columnar structure having columnar grains, the columnar grains have an average width of 1.0 μm or less on a surface side, and the TiCN coating layer is the coating layer having the thickest thickness in the hard coating.
(4) The coated cutting tool according to (3), wherein the hard coating layer has an Al ₂ O ₃ coating layer on the TiCN coating layer.

The present invention provides a WC cemented carbide substrate with excellent durability for high-speed machining of mild steel, and a coated cutting tool using the same.

1 is an electron microscope photograph (2,000x) of the structure of a polished cross section of the WC cemented carbide substrate of Example 1. 1 is an electron microscope photograph (2,000x) of the structure of a polished cross section of the WC cemented carbide substrate of Comparative Example 3.

The inventors arrived at the present invention by specifically discovering the composition and structure of a WC-based cemented carbide, as well as the composition and structure of a hard coating, that can significantly improve tool life in high-speed machining of steel and the like, for example, in high-speed machining of mild steel. The details are described below.

[1] Composition of WC-based cemented carbide <Co content>
Co is a binder phase that binds together WC particles, which are a hard phase, and is an element that imparts high toughness to the WC-based cemented carbide.
In the present invention, in order to reproduce excellent durability in the high-speed machining of mild steel, the Co content needs to be controlled within a narrow range, and Co is added as a metallic element in an amount of 8.5 mass % or more and 9.5 mass % or less (hereinafter, "mass %" will be simply abbreviated as "%").
If the Co content is less than 8.5%, the toughness of the cemented carbide is reduced. In addition, the structure is easily non-uniform, and chipping is easily generated during high-speed machining of mild steel. On the other hand, if the Co content exceeds 9.5%, even if the grain size distribution of the WC particles described later is made uniform, the hardness and plastic deformation resistance are reduced, and therefore the durability of the tool is significantly reduced during high-speed machining of mild steel.
Therefore, the Co content is specified to be 8.5% or more and 9.5% or less.

<Cr Content>
Cr is an element that dissolves in Co and suppresses the grain growth of WC grains during the sintering process to make the structure uniform, and is added in an amount of 0.3% to 1.0% as a metallic element.
If the Cr content is less than 0.3%, the grain growth of the WC grains is not suppressed, the grain size distribution of the WC grains becomes non-uniform, and chipping is likely to occur. In addition, the non-uniform grain size distribution of the WC grains also makes the distribution of Co non-uniform, and chipping is likely to occur.
On the other hand, if the Cr content exceeds 1.0%, coarse carbides mainly composed of Cr are precipitated, reducing the toughness of the cemented carbide.
Therefore, the Cr content is set to 0.3% or more and 1.0% or less, preferably 0.5% or more, and more preferably 0.8% or less.

<Ta Content>
Ta dissolves in Co to suppress the grain growth of WC grains and homogenize the structure. In addition, Ta is added in an amount of 1.0% to 3.0% as a metallic element because it can improve heat resistance by dispersing a phase mainly composed of Ta in the structure.
If the Ta content is less than 1.0%, the particle size distribution of the WC particles becomes non-uniform, and the amount of the phase mainly composed of Ta dispersed in the structure is small, resulting in a decrease in heat resistance.On the other hand, if the Ta content exceeds 3.0%, the amount of the phase mainly composed of Ta becomes too large, resulting in a decrease in the toughness of the cemented carbide.
Therefore, the Ta content is set to 1.0% or more and 3.0% or less, preferably 2.5% or less, and more preferably 2.0% or less.

<Non-metallic elements that exist as solid solutions or compounds with metallic elements and unavoidable impurities>
The balance of the WC-based cemented carbide is made up of WC as the main component, nonmetallic elements present as solid solutions or compounds with the metallic elements (Co, Cr, Ta), and unavoidable impurities.
The non-metallic elements present as solid solutions or compounds with metallic elements are C, N, etc., and are present in amounts that cannot be confirmed as free components by optical microscope observation.
Furthermore, the raw material powder may contain trace amounts of Fe, Ni, Nb, Al, etc. as unavoidable impurities during the mixing and sintering process.

[2] Structure of WC-based cemented carbide <Average grain size of WC particles>
There is a trade-off between the hardness and toughness of WC-based cemented carbide, with an increase in hardness tending to decrease the toughness, and conversely, a decrease in hardness tending to increase the toughness.
If the Co content of the WC-based cemented carbide is the same, the hardness and toughness are determined almost entirely by the average grain size of the WC grains.
The average grain size of WC grains referred to here means the average grain size of grains equivalent to a circle (also called the "circle equivalent diameter").
In particular, with regard to WC grains, if fine grains having a circle-equivalent grain size of less than 0.4 μm are included, the uniformity of the structure cannot be accurately evaluated, for example, using D90/D10, which will be described later, so the average grain size of grains having a circle-equivalent grain size of 0.4 μm or more is specified.
In high-speed machining of mild steel, if the average grain size of WC grains is too fine, toughness decreases and chipping occurs, whereas if the average grain size of WC grains is too coarse, hardness decreases and wear resistance decreases.
Therefore, in the present invention, the average grain size of WC grains having a circle-equivalent grain size of 0.4 μm or more is specified to be 1.0 μm or more and 2.0 μm or less, preferably 1.2 μm or more, and more preferably 1.8 μm or less.
Specifically, the sample is mirror-finished and the average circle-equivalent grain size of WC grains with a circle-equivalent grain size of 0.4 μm or more within an area of 60 μm length × 30 μm width (1,800 ^μm2 ) is determined, thereby enabling the average grain size of the WC grains to be evaluated with high precision.
The average grain size of the WC grains can be measured by using the EBSD (Electron Back Scatter Diffraction) method.
Since the measurement of WC grains smaller than 0.4 μm includes noise, as described above, the grain size of the WC grains to be measured was evaluated by defining it as the average grain size of the circle-equivalent diameter of WC grains of 0.4 μm or more. The area ratio of grains with an equivalent diameter of less than 0.4 μm to the whole grains was 5% or less.

<D90/D10 of WC particles>
Here, D90/D10 refers to the ratio of the particle size D10 where the integrated value of the area ratio is 10% to the particle size D90 where the integrated value of the area ratio is 90% in the particle size distribution of the WC average particle size.
In the present invention, in addition to controlling the composition range described above, it is important to homogenize the micro-level structure. As described above, the WC-based cemented carbide of the present invention is set to have a specific average grain size in order to ensure high levels of hardness and toughness in high-speed cutting of mild steel. However, even if the average grain size is about the same, if the grain size distribution is wide, the micro-level structure becomes non-uniform, and chipping is likely to occur.
Therefore, in the present invention, as an index for evaluating the uniformity of WC grains at the micro level, the ratio of the grain size D10 at which the integrated value of the area ratio in the grain size distribution of the average grain size is 10% to the grain size D90 at which the integrated value of the area ratio is 90%, that is, D90/D10, is used. If all grains have the same grain size, D90 and D10 will be the same grain size, and the value of D90/D10 will be the minimum value of 1. In a structure with a wide grain size distribution, the value of D90 is large for large grains, while the value of D10 is small for small grains, so the value of D90/D10 exceeds 1 and becomes large. In contrast, a small value of D90/D10 indicates a structure with a sharper grain size distribution and a more uniform grain size distribution.
However, as mentioned above, when extremely fine WC particles are taken into consideration, the number of fine WC particles is large, so that the WC particles of the target size of 1.0 μm to 2.0 μm cannot be accurately evaluated, and the uniformity of the structure cannot be accurately evaluated by D90/D10. Therefore, it was confirmed that the uniformity of the structure can be accurately evaluated by evaluating the ratio of D10 to D90 for WC particles with a circle-equivalent diameter of 0.4 μm or more, without considering the extremely fine WC particles with a circle-equivalent diameter of less than 0.4 μm that are uniformly dispersed in the structure. Then, it was found that the effect of suppressing the occurrence of chipping can be fully exhibited in high-speed cutting of mild steel by setting the average diameter of WC particles with a circle-equivalent diameter of 0.4 μm or more to 1.0 μm to 2.0 μm, and specifying D90/D10, which is the ratio of the diameter D90 at a cumulative value of 90% of the area ratio in the particle size distribution of the average diameter, to the diameter D10 at a cumulative value of 10% of the area ratio, to less than 3.2.
It is preferable that D90/D10 is 3.0 or less, and it is further preferable that D90/D10 is 2.8 or less.

<Coarse WC particles and aggregates (macro defects)>
The above describes the case where WC particles or WC aggregates with an equivalent circle diameter exceeding 10 μm are not generated. However, there are also cases where WC particles or WC aggregates with an equivalent circle diameter exceeding 10 μm, and even WC particles or WC aggregates with an equivalent circle diameter exceeding 30 μm (macrodefects) are generated in part of the structure. Therefore, below, a method for measuring the average grain size when these coarse WC particles or WC aggregates are generated will be described.
In particular, since chipping is more likely to occur when there are many macro defects, it is preferable to specify that for WC grains or WC aggregates with an equivalent circle diameter exceeding 30 μm, the number be 8 or less in an area of ^350,000 μm (500 μm × 700 μm) when observed by optical microscope structure, and furthermore, that the number be 5 or less, and that for WC grains or WC aggregates with an equivalent circle diameter exceeding 10 μm, the number be 8 or less.
With these conditions satisfied, a location having an average structure free of macro defects, WC grains with an equivalent circle diameter exceeding 10 μm, and WC aggregates is selected to measure the average grain size.
Specifically, the sample is mirror-finished and the average circular grain size of WC grains with a circular grain size of 0.4 μm or more within an area of ^1,800 μm2 (60 μm long × 30 μm wide) that is free of macro defects, WC grains with a circular equivalent diameter exceeding 10 μm, and WC agglomerates can be determined, thereby enabling the average grain size of WC grains to be evaluated with high accuracy.

<Ta phase structure (d90/d10)>
In the present invention, the phase mainly composed of Ta dispersed in the structure can be confirmed by optical microscope observation. The phase mainly composed of Ta contains W in the second largest amount after Ta, and exists mainly as carbides and carbonitrides. If the average grain size of the phase mainly composed of Ta dispersed in the structure is too small, the heat resistance of the cemented carbide is reduced, whereas if it is too large, the toughness is reduced.
Therefore, it is preferable that the phase containing Ta as a main component dispersed in the structure has an average circle-equivalent grain size of 1.0 μm to 3.0 μm.
The phase mainly composed of Ta contains 60 mass% or more of Ta as a metal element and 1 to 30 mass% of W. In addition, in the particle size distribution of the phase mainly composed of Ta, when the particle size at which the integrated value of the area ratio is 90% is d90 and the particle size at which the integrated value of the area ratio is 10% is d10, it is preferable that d90/d10 is less than 6.0. Furthermore, it is preferable that d90/d10 is 5.0 or less.

[3] Coated cutting tool using WC-based cemented carbide as a substrate <Formation of hard coating layer>
By coating a cutting tool having the above-mentioned WC-based cemented carbide as a substrate with a hard film by physical vapor deposition or chemical vapor deposition, a coated cutting tool having even greater durability can be obtained.
In a coated cutting tool applied to high-speed machining of mild steel, it is preferable that the hard coating contains at least a TiCN coating, the TiCN coating has a columnar structure, the average width of the columnar grains on the surface side is 1 μm or less, and the film thickness of the TiCN coating is a maximum thickness. In particular, by making the TiCN coating having a fine grain structure the maximum thickness, it becomes easier to suppress the coating destruction.
In order to obtain the desired effect of the TiCN film, the film thickness is preferably 5.0 μm or more. On the other hand, if the film thickness is too large, peeling of the film is likely to occur, so the film thickness is preferably 8.0 μm or less.
In addition, it is preferable to provide an Al ₂ O ₃ film, which has excellent heat resistance and wear resistance, on the upper layer of the TiCN film, and the film thickness thereof is preferably 1.0 μm or more and 4.0 μm or less.
The coated cutting tool of the present invention having such a coating structure is preferably used for milling mild steel of HRC 40 or less, since it exhibits particularly excellent durability, and furthermore, it is preferably used at a cutting speed of 200 m/min.

[4] Manufacturing Method of WC-Based Cemented Carbide Hereinafter, an example of a manufacturing method of a WC-based cemented carbide having a microstructure according to the present invention will be described, but the manufacturing method of the present invention is not limited to the manufacturing method described below.
<Raw material powder mixing process>
Since it is effective to prevent the WC raw material powder from being excessively pulverized, in the raw material powder mixing step, it is preferable to first mix all the raw material powders other than the WC raw material powder together, and then add and mix the WC raw material powder.
As an example of mixing conditions, when an attritor is used, the mixing time of the WC raw material powder is preferably 0.5 to 5 hours. The mixing time of raw material powders other than the WC raw material powder is preferably 2 to 5 times the mixing time of the WC raw material powder. In order to homogenize the structure and prevent excessive pulverization, the rotation speed of the attritor is preferably 80 to 200 rpm.
In addition, if the carbonization temperature during production of the WC raw material powder used is low and the powder is formed by agglomeration of fine powder, the WC particles will be over-pulverized in the mixing process, resulting in a non-uniform structure. Therefore, it is preferable that the WC raw material powder used be a high-temperature carbonized raw material that has been carbonized at 1900°C to 2200°C.
On the other hand, even if the carbonization temperature during production of the raw material powder is high and the fine powder has little agglomeration, if the average particle size is 5 μm or more, the particle size distribution will widen due to grinding and the structure will become non-uniform. In that case, it is preferable to use a WC raw material powder having an average particle size of 2.0 μm or more and 4.0 μm or less as measured by the Fischer method and having little agglomeration of the fine powder.
<Manufacturing process of sintered body>
In the sintering step, the sintering temperature is maintained within the range of 1350° C. to 1450° C. for about one hour, whereby a WC-based cemented carbide having excellent properties can be obtained.

The present invention will be described in detail below with reference to examples, but the present invention is not limited to the following examples.

In Example 1, a specific method for producing a WC-based cemented carbide substrate is shown, and the relationship between the component composition, structure, and physical properties of the obtained WC-based cemented carbide substrate is shown.
For each sample, the average particle size of the WC raw material powder, the mixing method, and the mixing ratio of each raw material powder were changed to prepare WC-based cemented carbide substrates as examples of the present invention and comparative examples (see Tables 1 and 2).
First, in Examples 1, 2, 4, and 5 of the present invention, the WC raw material powder used was, as a rule, a WC raw material powder having little agglomeration of fine powder that had been carbonized at a high temperature of about 2000°C. In Example 3 of the present invention, a WC raw material powder having little agglomeration and a large average particle size was used, although the carbonization temperature was less than 2000°C.
Next, in Examples 1 to 5 of the present invention, WC powder (average particle size 2.5 to 8.6 μm), Co powder (average particle size 1.2 μm), Cr ₃ C ₂ powder (average particle size 1.0 μm), TaC powder (average particle size 1.5 μm) and carbon powder were prepared, and 2 mass% of paraffin wax and ethyl alcohol (water content less than 10%) based on the total mass of all these raw material powders, and all other raw material powders except for WC powder were charged into a small attritor, and mixed for 4 hours at a rotation speed of 192 rpm, and then the WC powder was charged and mixed for another 1 hour to prepare a WC mixed slurry.
The average particle size of the powder is a representative value measured by the Fischer method.
The WC mixed slurry was then dried in a static dryer and granulated in a pan granulator. The granulated powder was used to mold a molded body for the base material of a milling insert (WDNT140520-B, with a breaker). The molded body was then heated and held at a sintering temperature of 1400°C for 60 minutes, and then forcibly cooled from the sintering temperature with nitrogen gas to produce a sintered body made of a WC-based cemented carbide with a medium carbon composition.
In contrast, in Comparative Example 1, the WC raw material powder used was a WC raw material powder that had been carbonized at a high temperature of about 2000°C and had little aggregation of fine powder, but did not contain Ta-containing powder. In Comparative Examples 2 and 3, the WC raw material powder was carbonized at a high temperature, but one with a large particle size was used, and a sintered body made of a WC-based cemented carbide was produced using the same manufacturing method as in the present invention.
In addition, in Comparative Example 4, the WC raw material powder was carbonized at high temperature, but a powder with a large particle size was used, and all the raw material powders including the WC powder were charged at the same time and mixed for 3 hours to produce a sintered body made of a WC-based cemented carbide using the WC mixed slurry.
In Comparative Example 5, like Invention Example 2, a WC raw material powder having an average particle size of 2.5 μm was used as the WC raw material powder. However, unlike Invention Examples 1 to 5, in which raw materials other than the WC raw material powder were mixed for a long period of time, the WC raw material powder was added, and further mixing was not carried out. Instead, like Comparative Example 4, all raw material powders including the WC powder were added at the same time, and after mixing for several hours, a sintered body made of a WC-based cemented carbide was produced.
Table 1 shows the WC raw material powders used in the production of each sample and the mixing method thereof.

Next, the sintered body was mirror-finished to obtain a sample, and the structure was observed using an EPMA (JXA-8530F manufactured by JEOL). Then, the cross-sectional area of each WC grain in the range of 30 μm × 60 μm was measured using the EBSD (Electron Back Scatter Diffraction) method, and the circle-equivalent grain size was calculated from the value. This was measured at three locations, and for WC grains with a circle-equivalent grain size of 0.4 μm or more, the average grain size, the grain size D90 at which the integrated value of the area ratio in the grain size distribution of the average grain size is 90%, the grain size D10 at which the integrated value of the area ratio is 10%, and the ratio D90/D10 of the grain size D10 to the grain size D90 were calculated, and are shown in Table 2.
The area ratio of particles with a circular equivalent diameter of less than 0.4 μm, which were not included in the calculation due to noise, was about 1 to 2%.
Table 3 shows the physical properties (coercive force (Hc), saturation magnetization (4πσ), hardness (HRA)) of the produced WC cemented carbide.
Conventional examples 1 and 2 are commercially available inserts of the same shape that are used in milling of mild steel.

As is clear from Table 2, Examples 1 to 5 of the present invention, which had the prescribed component composition and were produced under the production conditions shown in Table 1, had the desired average grain size and a sharp and uniform grain size distribution (D90/D10 value) in the WC phase structure. As shown in Table 3, Examples 1 to 5 of the present invention had a hardness in the range of 90.0 to 91.0 HRA, a coercive force in the range of 180 to 220 (Oe), and a saturation magnetization in the range of 11 to 12.
In Inventive Examples 1 to 5, a phase mainly composed of Ta having an average circle-equivalent grain size of 1.0 μm or more and 3.0 μm or less was dispersed in the structure, and the composition of the phase mainly composed of Ta was a carbide of 60 to 80 mass % Ta and 10 to 30 mass % W. In Inventive Example 1, when the grain size distribution of the phase mainly composed of Ta was such that the grain size at which the integrated value of the area ratio was 90% was d90 and the grain size at which the integrated value of the area ratio was 10% was d10, d90 was 6.0 to 8.0 μm, d10 was 1.5 to 2.0 μm, and d90/d10 was 4.6 to 5.2.
It is presumed that in invention examples 1, 2, 4, and 5, a uniform structure was obtained by using WC raw material powder with an average particle size of about 2 to 3 μm that had been subjected to high-temperature carbonization and mixing without excessive pulverization. Also, in invention example 3, although WC raw material powder that had been subjected to high-temperature carbonization was used, raw material powder with a large average particle size was used and mixed without excessive pulverization, and it is presumed that a uniform structure was obtained like the other invention examples.
In contrast, in Comparative Examples 2 and 3, which used WC raw material powder with an average particle size of about 5.0 to 6.0 μm that had been subjected to high-temperature carbonization, the WC phase structure had a high D90/D10 value and a wide particle size distribution, so the hardness value was somewhat low. In Comparative Examples 4 and 5, the WC raw material powder was over-pulverized, so the average particle size became small, but many coarse defects with an average particle size exceeding 10.0 μm occurred, so stable characteristics could not be obtained in terms of hardness and magnetic properties.
1 and 2 show electron microscope photographs of the structure of Example 1 of the present invention and Comparative Example 3. From Fig. 1, it can be seen that the structure of Example 1 of the present invention is a homogeneous grain structure made up of WC grains having a uniform grain size. On the other hand, from Fig. 2, it can be seen that the structure of Comparative Example 3 is a mixed grain structure in which coarse grains are present among many fine WC grains.

In Example 2, cutting evaluation tests were conducted in high-speed machining of mild steel for Inventive Example Tools 1 to 3, which were inventive example tools 1 to 3 with hard coatings formed thereon, Comparative Examples 2 to 4, and Conventional Example Tools 1 and 2, which were in comparative example tools 2 to 4 with the same hard coatings formed thereon as Inventive Example Tools 1 to 3, and Conventional Example Tools 1 and 2.
The inserts for the cutting tests were hard-coated by chemical vapor deposition.
First, the surface side of the columnar grains having a columnar structure was coated with 6.0 μm of TiCN having an average width of 0.5 μm to 0.7 μm, and then coated with 3.0 μm of Al ₂ O _3. After coating with the hard film, wet blasting treatment was performed.
It was confirmed that the comparative example tools 2 to 4 and the conventional example tools 1 and 2 had the same coating structure as the inventive example tools 1 to 3 and had the same degree of residual compressive stress.
The cutting conditions are shown below, and the results of the cutting test are shown in Table 4. The tool life of the insert for the cutting test was defined as the machining time (min) until the maximum wear width of the flank exceeded 0.3 mm, or until chipping (fracture) occurred and its width exceeded 0.3 mm.
(Condition) Dry machining Tool: High speed, high feed tool Cutter model number: ASRT5063R-4
・Insert model number: WDNT140520-B
Number of teeth: 1
・Cutting material: SCM440 (32HRC)
Cutting method: dry milling Cutting depth: axial direction, 1.0 mm, radial direction, 43 mm
Cutting speed: 250 m/min
・Feed per blade: 1.5 mm/blade ・Protrusion: 100 mm

The inventive example tools 1 to 3 exhibited a stable wear pattern and had the longest tool life.
Comparative Example Tools 2 and 3 had a large D90/D10 ratio, and therefore chipping occurred, causing the tool to reach the end of its life early.
Comparative Example Tool 4 had a small average grain size, and chipping occurred, causing the tool to reach the end of its life early.
Conventional example tool 1 had a high Co content and did not contain Ta, so a phase mainly composed of Ta was not dispersed in the structure, and the heat resistance was lower and the tool life was shorter than that of the inventive example.
Conventional tool 2 had a high Co content and underwent plastic deformation, reaching the end of its tool life early.

In Example 3, cutting evaluation tests were conducted in high-speed machining of mild steel under longer overhang conditions than in Example 2 for Inventive Example Tools 2, 4, and 5, which were formed with hard coatings as Inventive Example Tools 2, 4, and 5, and for Comparative Example Tool 1 and Conventional Example Tool 1, which were formed with the same hard coatings as Inventive Example Tools 2, 4, and 5, as Comparative Example 1 and Conventional Example Tool 1.
The inserts for the cutting test were coated by chemical vapor deposition with the same hard coating as in Example 2. First, TiCN having a columnar structure and an average width of 0.5 μm to 0.7 μm on the surface side of the columnar grains was coated with a thickness of 6.0 μm, and then Al ₂ O ₃ was coated with a thickness of 3.0 μm. After coating with the hard coating, wet blasting was performed.
The cutting conditions are shown below, and the results of the cutting test are shown in Table 5. The tool life of the insert for the cutting test was defined as the machining time (min) until the maximum wear width of the flank exceeded 0.3 mm, or until chipping (fracture) occurred and its width exceeded 0.3 mm.
(Condition) Dry machining Tool: High speed, high feed tool Cutter model number: ASRT5063R-4
・Insert model number: WDNT140520-B
Number of teeth: 1
・Cutting material: SCM440 (32HRC)
Cutting method: dry milling Cutting depth: axial direction, 1.0 mm, radial direction, 43 mm
Cutting speed: 250 m/min
・Feed per blade: 1.5 mm/blade ・Protrusion: 200 mm

All of the invention tools 2, 4 and 5 exhibited excellent tool life. In particular, the invention tool 5, which had a low Ta content, tended to have stable tool damage.
The tool of Comparative Example 1 did not contain Ta, and therefore had a shorter tool life than the tools of Inventive Examples 2, 4 and 5.
The tool of Conventional Example 1 had a high Co content and reached the end of its tool life early.

The WC-based cemented carbide according to the present invention and a coated cutting tool using the same as a substrate are extremely useful because they have excellent chipping resistance and plastic deformation resistance when cutting steel and the like, particularly when cutting mild steel at high speed.

Claims (4)

A WC-based cemented carbide containing, by mass%, as metallic elements, Co of 8.5% or more and 9.5% or less, Cr of 0.3% or more and 1.0% or less, and Ta of 1.0% or more and 3.0% or less, with the balance being WC, non-metallic elements present as solid solutions or compounds with the metallic elements, and unavoidable impurities,
The average grain size of WC grains having a circle-equivalent grain size of 0.4 μm or more is 1.0 μm or more and 2.0 μm or less,
D90/D10, which is the ratio of a particle size D90 at which the integrated value of the area ratio in the particle size distribution of the average particle size is 90% to a particle size D10 at which the integrated value of the area ratio is 10%, is less than 3.2;
A WC-based cemented carbide characterized in that a phase mainly composed of Ta is dispersed in the structure. A coated cutting tool having a hard coating layer on the surface thereof, the WC-based cemented carbide according to claim 1 being used as a substrate. The coated cutting tool according to claim 2, characterized in that the hard coating layer includes at least a TiCN coating layer, the TiCN coating layer is made of a columnar structure having columnar grains, the average width of the columnar grains on the surface side is 1.0 μm or less, and the coating layer has the thickest thickness in the hard coating. The coated cutting tool according to claim 3, wherein the hard coating layer has _{an Al2O3 coating} layer on top of the TiCN coating layer.