Patent Application
20240263282
The present disclosure relates to a cemented carbide and a cutting tool using the same.
Conventionally, a cemented carbide including a tungsten carbide (WC) particle and a binder phase including cobalt as a main component has been used as a material for a cutting tool (PTL 1 and PTL 2).
The cemented carbide according to the present disclosure is a cemented carbide comprising a plurality of tungsten carbide particles and a binder phase, wherein
With the expansion of 5G (5th generation mobile communication system), the demand for a semiconductor package substrate is increasing. A semiconductor package substrate is subjected to drill working using a small-diameter drill. From the viewpoint of cost reduction, there is an increasing demand for high-efficiency working of a semiconductor package substrate.
Therefore, an object of the present disclosure is to provide a cemented carbide that can prolong the tool life, particularly even when used as a material for a cutting tool for high-efficiency working of a semiconductor package substrate, and a cutting tool including the same.
According to the present disclosure, it is possible to provide a cemented carbide that can prolong the tool life, particularly even when used as a material for a cutting tool for high-efficiency working of a semiconductor package substrate, and a cutting tool including the same.
First, aspects of the present disclosure will be listed and described.
According to the present disclosure, it is possible to provide a cemented carbide that can prolong the tool life, particularly even when used as a material for a cutting tool for high-efficiency working of a semiconductor package substrate, and a cutting tool including the same.
The cutting tool according to the present disclosure can have a long tool life, particularly even when used for high-efficiency working of a semiconductor package substrate.
With reference to the drawings, specific examples of the cemented carbide and the cutting tool according to the present disclosure will be described below. In the drawings of the present disclosure, the same reference signs represent the same portions or equivalent portions. In addition, a dimensional relationship such as length, width, thickness, or depth is appropriately changed for clarity and simplification of the drawings, and does not necessarily represent an actual dimensional relationship.
As used in the present disclosure, the expression of a range in the format “A to B” means the upper limit and the lower limit of the range (that is, A or more and B or less), and when no unit is written in A and a unit is only written in B, the unit for A and the unit for B are the same.
As used in the present disclosure, when a compound or the like is represented by a chemical formula, if the atomic ratio is not particularly limited, the chemical formula shall include all conventionally known atomic ratios, and should not necessarily be limited only to those within the stoichiometric range.
As used in the present disclosure, when one or more numerical values are written as each of the lower limit and the upper limit of a numerical range, a combination of any one numerical value written as the lower limit and any one numerical value written as the upper limit shall also be disclosed. For example, when a1 or more, b1 or more, and c1 or more are written as the lower limit, and a2 or less, b2 or less, and c2 or less are written as the upper limit, a1 or more and a2 or less, a1 or more and b2 or less, a1 or more and c2 or less, b1 or more and a2 or less, b1 or more and b2 or less, b1 or more and c2 or less, c1 or more and a2 or less, c1 or more and b2 or less, and c1 or more and c2 or less shall be disclosed.
The cemented carbide according to one embodiment of the present disclosure (hereinafter also referred to as “Embodiment 1”) is
a cemented carbide comprising a plurality of tungsten carbide particles and a binder phase, wherein
The cemented carbide of Embodiment 1 can provide a cemented carbide that can prolong the tool life, particularly even when used as a material for a cutting tool for high-efficiency working of a semiconductor package substrate, and a cutting tool including the same. Although the reason for this is not clear, it is presumed as follows.
The cemented carbide of Embodiment 1 includes a plurality of tungsten carbide particles (hereinafter also referred to as “WC particles”) and a binder phase, and the total content of the WC particles and binder phase in the cemented carbide is 80% by volume or more. According to this, the cemented carbide has high hardness and strength, and a cutting tool using the cemented carbide can have excellent wear resistance and breakage resistance.
The cemented carbide of Embodiment 1 includes 0.1% by volume or more and 20% by volume or less of the binder phase, and the binder phase includes 50% by mass or more of cobalt. According to this, the cemented carbide has high hardness and strength, and a cutting tool using the cemented carbide can have excellent wear resistance and breakage resistance.
The cemented carbide of Embodiment 1 includes at least one first element selected from the group consisting of boron, aluminum, silicon, iron, nickel, germanium, ruthenium, rhenium, osmium, iridium, and platinum, and the cemented carbide includes a total of 0.01 atomic % or more and 10 atomic % or less of the first element. According to this, the heat resistance and the rigidity of the cemented carbide are improved.
In the cemented carbide of Embodiment 1, the first element is segregated in the first interface region between the tungsten carbide particles adjacent to each other, and the first element is present at a C site of tungsten carbide in the first interface region. According to this, in the cemented carbide, the interface strength between the tungsten carbide particles is improved, and falling-off of the tungsten carbide particles is suppressed during high-efficiency working of a semiconductor package substrate.
Therefore, a cutting tool using the cemented carbide as a material can have a long tool life. Further, the cutting tool also has improved hole position accuracy.
As shown in
The cemented carbide of Embodiment 1 can consist of a plurality of tungsten carbide particles and a binder phase. The cemented carbide of the present embodiment can include a different phase in addition to the tungsten carbide particles and the binder phase. Examples of the composition of the different phase include TiCN.
The cemented carbide of Embodiment 1 can consist of the tungsten carbide particles, the binder phase, and a different phase. Any content of the different phase in the cemented carbide is allowed as long as it does not impair the effect of the present disclosure. For example, the content of the different phase in the cemented carbide may be 0% by volume or more and 20% by volume or less, 0% by volume or more and 18% by volume or less, or 0% by volume or more and 16% by volume or less. In this case, the total content of the WC particles and the binder phase in the cemented carbide may be 80% by volume or more and less than 100% by volume, 82% by volume or more and less than 100% by volume, or 84% by volume or more and less than 100% by volume.
The cemented carbide of Embodiment 1 can include an impurity. Examples of the impurity include calcium (Ca) and sulfur (S). Any content of the impurity in the cemented carbide is allowed as long as it does not impair the effect of the present disclosure. For example, the content of the impurity in the cemented carbide is preferably 0% by mass or more and less than 0.1% by mass. The content of the impurity in the cemented carbide is measured by ICP emission spectroscopy (Inductively Coupled Plasma Emission Spectroscopy (measuring apparatus: “ICPS-8100” (trademark) of Shimadzu Corporation)).
The lower limit of the content of the tungsten carbide particles in the cemented carbide of Embodiment 1 may be 60% by volume or more, 62% by volume or more, 64% by volume or more, or 68% by volume or more. The upper limit of the content of the tungsten carbide particles in the cemented carbide may be 99.9% by volume or less, 99.2% by volume or less, 99% by volume or less, 98% by volume or less, 96% by volume or less, or 94% by volume or less. The content of the tungsten carbide particles in the cemented carbide may be 60% by volume or more and 99.9% by volume or less, 60% by volume or more and 99.2% by volume or less, 64% by volume or more and 96% by volume or less, or 68% by volume or more and 94% by volume or less.
The cemented carbide of Embodiment 1 includes 0.1% by volume or more and 20% by volume or less of the binder phase. From the viewpoint of improving toughness, the lower limit of the content of the binder phase in the cemented carbide is 0.1% by volume or more, and may be 1% by volume or more, 2% by volume or more, 3% by volume or more, 4% by volume or more, or 8% by volume or more. From the viewpoint of improving hardness, the upper limit of the content of the binder phase in the cemented carbide is 20% by volume or less, and may be 19% by volume or less, 18% by volume or less, 17% by volume or less, 16% by volume or less, or 15% by volume or less. The content of the binder phase in the cemented carbide may be 0.1% by volume or more and 18% by volume or less, 1% by volume or more and 18% by volume or less, 3% by volume or more and 17% by volume or less, 4% by volume or more and 16% by volume or less, or 8% by volume or more and 15% by volume or less. When the content of the binder phase in the cemented carbide is 18% by volume or less, the hardness of the cemented carbide is further improved, and the wear resistance is further improved, and thus the tool life of a cutting tool using the cemented carbide as a material is further improved. The Rockwell hardness (HRC) of the cemented carbide of the present embodiment may be, for example, 90 or more and 95 or less, or 91 or more and 95 or less.
The method for measuring the content (% by volume) of the tungsten carbide particles in the cemented carbide and the content (% by volume) of the binder phase in the cemented carbide is as follows.
When the cemented carbide includes a different phase in addition to the WC particles and the binder phase, the content of the different phase in the cemented carbide can be obtained by subtracting the content (% by volume) of the tungsten carbide particles and the content (% by volume) of the binder phase measured by the above procedure from the entire cemented carbide (100% by volume).
As long as the applicant has carried out the measurement, it has been confirmed that as long as the measurement is carried out on the same sample, even if the cut-out location of the cross section of the cemented carbide, the photographing region described in (C1) above, and the measurement field of view described in (G1) above are arbitrarily set to measure the content of the tungsten carbide particles and the content of the binder phase in the cemented carbide a plurality of times according to the above procedure, there is little variation in the measurement results, and that even if the cut-out location of the cross section of the cemented carbide, the photographing region, and the measurement field of view are arbitrarily set, it will not be contrived.
In Embodiment 1, the tungsten carbide particles include at least any of “pure WC particles (also including WC containing no impurity element and WC in which the content of an impurity element is below the detection limit)” and “WC particles inside which an impurity element is intentionally or unavoidably contained as long as the effect of the present disclosure is not impaired.” The content of an impurity in the tungsten carbide particles (when two or more elements constitute the impurity, the total concentration of the elements) is less than 0.1% by mass. The content of the impurity element in the tungsten carbide particles is measured by ICP emission spectrometry.
In Embodiment 1, the average particle diameter of the tungsten carbide particles is not particularly limited. The average particle diameter of the tungsten carbide particles can be, for example, 0.1 μm or more and 3.5 μm or less. It has been confirmed that the cemented carbide of Embodiment 1 can have a long tool life regardless of the average particle diameter of the tungsten carbide particles.
In Embodiment 1, the binder phase includes 50% by mass or more of cobalt. This can impart excellent toughness to the cemented carbide. The lower limit of the cobalt content of the binder phase may be 52% by mass or more, 57% by mass or more, 60% by mass or more, or 63% by mass or more. The upper limit of the cobalt content of the binder phase may be 100% by mass or less, less than 100% by mass, 99% by mass or less, 98% by mass or less, 95% by mass or less, or 90% by mass or less. The cobalt content of the binder phase may be 50% by mass or more and less than 100% by mass, 60% by mass or more and 99% by mass or less, or 63% by mass or more and 98% by mass or less.
The method for measuring the content of cobalt in the binder phase is as follows. In the same manner as in (A1) to (F1) of the method for measuring the content of the tungsten carbide particles, the content of the binder phase, and the content of a hard phase particle in the cemented carbide, the region in which the binder phase is present is identified on an image after binarization processing. The region in which the binder phase is present is analyzed by using SEM-EDX to measure the cobalt content of the binder phase.
As long as the applicant has carried out the measurement, it has been confirmed that as long as the measurement is carried out on the same sample, even if the cut-out location of the cross section of the cemented carbide and the photographing region described in (C1) above are arbitrarily set to measure the content of cobalt in the binder phase a plurality of times according to the above procedure, there is little variation in the measurement results, and that even if the cut-out location of the cross section of the cemented carbide and the photographing region are arbitrarily set, it will not be contrived.
In Embodiment 1, the binder phase can include, in addition to cobalt, at least one first element selected from the group consisting of boron, aluminum, silicon, iron, nickel, germanium, ruthenium, rhenium, osmium, iridium, and platinum. The binder phase can further include chromium (Cr) or the like in addition to cobalt and the first element. The binder phase can consist of cobalt and the first element. The binder phase can consist of cobalt, the first element, and chromium. The binder phase can consist of cobalt, the first element, chromium, and an unavoidable impurity. Examples of the unavoidable impurity include manganese (Mn), magnesium (Mg), calcium (Ca), and sulfur (S).
The cemented carbide of Embodiment 1 includes at least one first element selected from the group consisting of boron, aluminum, silicon, iron, nickel, germanium, ruthenium, rhenium, osmium, iridium, and platinum, and the cemented carbide includes a total of 0.01 atomic % or more and 10 atomic % or less of the first element. From the viewpoint of improving the tool life, the lower limit of the content of the first element in the cemented carbide is 0.01 atomic % or more, and may be 0.1 atomic % or more, 0.9 atomic % or more, 2 atomic % or more, 2.5 atomic % or more, 5 atomic % or more, or 5.2 atomic % or more. From the viewpoint of maintaining strength, the upper limit of the content of the first element in the cemented carbide is 10 atomic % or less, and may be 9 atomic % or less, 8.4 atomic % or less, 8 atomic % or less, 7.8 atomic % or less, 7 atomic % or less, 5 atomic % or less, or 4.5 atomic % or less. The content of the first element in the cemented carbide may be 0.1 atomic % or more and 5 atomic % or less, or 2 atomic % or more and 4.5 atomic % or less.
The content, based on the number of atoms, of the first element in the cemented carbide is measured by ICP (Inductively Coupled Plasma) emission spectroscopy (measuring apparatus: “ICPS-8100” (trademark) of Shimadzu Corporation).
In the cemented carbide of Embodiment 1, the first element is segregated in the first interface region between the tungsten carbide particles adjacent to each other, and the first element is present at a C site of tungsten carbide in the first interface region. According to this, the interface strength between the tungsten carbide particles and the interface strength between the tungsten carbide particles and the binder phase are improved, and the cemented carbide can have excellent wear resistance and breakage resistance.
In the present disclosure, a method for confirming that the first element is segregated in the first interface region between the tungsten carbide particles adjacent to each other in the cemented carbide will be described with reference to
The cemented carbide is sliced into a thickness of 30 to 100 nm by using an argon ion slicer (“Cryo Ion Slicer IB-09060BCIS” (trademark) manufactured by JEOL Ltd.) under conditions of an acceleration voltage of 6 kV and a finish acceleration voltage of 2 kV to make a sample for measurement. Next, the sample for measurement is observed at a magnification of 200000 times by using a TEM (Transmission Electron Microscopy) (“JEM-ARM300F2” (trademark) manufactured by JEOL Ltd.) under a condition of an acceleration voltage of 200 V to obtain a first image (not shown).
On the first image, the tungsten carbide particles are observed as white regions, the binder phase is observed as a black region, and the interface is observed as a black region. On the first image, the interface between the tungsten carbide particles is arbitrarily selected. In the present disclosure, tungsten carbide particles adjacent to each other forming an interface are also referred to as a first tungsten carbide particle and a second tungsten carbide particle.
Next, the selected interface is positioned such that it passes through the vicinity of the center of the image, the observation magnification is adjusted such that the field of view size is 5 nm×5 nm, and observation is carried out to obtain a second image (not shown). On the second image, the extension direction in which the interface extends is confirmed. Line analysis is carried out in a direction perpendicular to the extension direction and going from the first tungsten carbide particle to the second tungsten carbide particle to obtain a graph of the distributions of cobalt, tungsten, and the first element measured (hereinafter also referred to as a first graph). When the cemented carbide includes two or more types of first elements, the distribution of each element is measured. Here, the term direction perpendicular to the extension direction of the interface means the direction along a straight line that intersects the tangent to the extension direction at an angle of 900±5°. The measurement conditions for obtaining the second image are an acceleration voltage of 200 kV, a camera length of 10 cm, a pixel count of 128×128 pixels, and a dwell time of 0.02 to 3 s/pixel.
The peak position of cobalt is identified in the first graph. In the present disclosure, the peak position of cobalt is referred to as the first interface. The first interface is formed by the first tungsten carbide particle and the second tungsten carbide particle adjacent to each other. In the first graph of
In the first graph, a first A region in which the distance from the first interface approaching the first tungsten carbide particle is within 1.2 nm, and a first B region in which the distance from the first interface approaching the second tungsten carbide particle is within 1.2 nm are identified. In the present disclosure, the region consisting of the first A region and the first B region is the first interface region. In the first graph of
In the first graph, a second A region in which the distance from the first interface approaching the first tungsten carbide particle is 1.50 nm or more and 3.50 nm or less, and a second B region in which the distance from the first interface approaching the second tungsten carbide particle is 1.50 nm or more and 3.50 nm or less are identified. In the first graph of
Based on the first graph, the average B of the NET intensity in a baseline region consisting of the second A region and the second B region of the first element is calculated. In the first graph, the maximum value A of the NET intensity in the first interface region of the first element is measured. When the proportion A/B of the maximum value A to the average B is 3 or more, it is confirmed that the first element is segregated in the first interface region between the tungsten carbide particles adjacent to each other in the cemented carbide. In the first graph of
In the cemented carbide, the first images of 5 fields of view that do not overlap each other are arbitrarily obtained, the above analysis is repeatedly carried out based on each of the first images, and when the segregation of the first element in the first interface region is confirmed in 4 or more fields of view, it is determined that the first element is segregated in the first interface region between the tungsten carbide particles adjacent to each other in the cemented carbide.
In the present disclosure, a method for confirming that the first element is present at a C site of tungsten carbide in the first interface region will be described with reference to
The first graph is normalized to obtain a second graph. The normalization method is based on the first graph (see
In at least a part of the second graph after normalization, peaks of tungsten are periodically present along the X axis. The average period of the peaks of tungsten is determined based on the portion in which the period is clearly found. Based on the average period, peak positions P3 of tungsten are entered on the second graph. In the present disclosure, peak positions P3 correspond to the positions of W sites. In the present disclosure, a C site is present between adjacent peak positions P3.
Peak positions P1 of the first element are identified in the first interface region in the second graph. When peak positions P1 of the first element and peak positions P3 of tungsten are different in at least a part of the first interface region in the second graph, it is confirmed that the first element is present at a C site of tungsten carbide in the first interface region.
As long as the applicant has carried out the measurement, it has been confirmed that as long as the measurement is carried out on the same sample, even if the cut-out location of the cross section of the cemented carbide is arbitrarily set and the first image is arbitrarily obtained on the cross section to confirm the presence or absence of segregation of the first element in the first interface region and the position of the first element in the first interface region a plurality of times by changing the line analysis region according to the above procedure, there is little variation in the measurement results, and that even if the cut-out location of the cross section of the cemented carbide, the first image, and the line analysis region are arbitrarily set, it will not be contrived. Therefore, as long as the cemented carbide is subjected to the above confirmation method, and it is confirmed that the first element is segregated in the first interface region and that the first element is present at a C site of tungsten carbide in the first interface region, it is presumed that the interface strength between the tungsten carbide particles in the cemented carbide is improved.
The position of the C site of tungsten carbide will be described by using HAADF (high-angle annular dark field) images of the cross section of the cemented carbide. HAADF images of a cross section of a cemented carbide including tungsten carbide particles and cobalt as the binder phase are shown in
In the cemented carbide of the present disclosure, the first element can also be present in the above different phase and cobalt.
The cemented carbide of the present embodiment can be manufactured by carrying out a raw material powder preparing step, a mixing step, a compacting step, a sintering step, and a cooling step in presented order. Hereinafter, each step will be described.
The preparing step is a step for preparing raw material powders of materials that constitute a cemented carbide material. Examples of the raw material powders include a tungsten carbide powder (hereinafter also referred to as a “WC powder”), a cobalt (Co) powder, and a first metal element-containing powder. Examples of the first metal element-containing powder include a boron (B) powder, an aluminum (Al) powder, a silicon (Si) powder, an iron (Fe) powder, a nickel (Ni) powder, a germanium (Ge) powder, a ruthenium (Ru) powder, a rhenium (Re) powder, an osmium (Os) powder, an iridium (Ir) powder, and a platinum (Ot) powder, and an alloy powder of the first metal element and cobalt. As these raw material powders, commercially available ones can be used. The average particle diameter of these raw material powders is not particularly limited, and can be, for example, 0.1 to 3.0 μm. The term average particle diameter of a raw material powder means the average particle diameter measured by the FSSS (Fisher Sub-Sieve Sizer) method. The average particle diameter is measured by using “Sub-Sieve Sizer Model 95” (trademark) manufactured by Fisher Scientific. The distribution of the particle diameter of the WC powder is measured by using a particle size distribution measuring apparatus (trade name: MT3300EX) manufactured by Microtrac.
The mixing step is mixing raw material powders prepared in the preparing step at predetermined proportions. A mixed powder in which raw material powders are mixed is obtained by the mixing step. The mixing proportions of raw material powders are appropriately adjusted according to the intended composition of the cemented carbide.
The mixing of each raw material powder is carried out with a ball mill. The mixing conditions can be, for example, a media diameter of φ6 mm, a rotation speed of 120 rpm, a filling percentage of 40%, and a mixing time of 8 hours.
After the mixing step, the mixed powder may be granulated as needed. By granulating the mixed powder, it is easy to fill a die or a mold with the mixed powder during the compacting step described later. A known granulation method can be applied to the granulation, and for example, a commercially available granulator such as a spray dryer can be used.
The compacting step is a step for compacting the mixed powder obtained in the mixing step into a shape for a cutting tool (for example, a round bar shape) to obtain a compact. As the compacting method and the compacting conditions in the compacting step, a general method and general conditions may be adopted, and these are not particularly limited.
The sintering step is a step for obtaining a cemented carbide intermediate by sintering the compact obtained through the compacting step by a sinter HIP (Hot Isostatic Pressing) treatment that can simultaneously carry out sintering and pressurization.
The sintering conditions can be, for example, a temperature of 1320 to 1340° C., a pressure of 7 MPa, and a sintering time of 240 minutes. Ar gas can be used as the atmosphere during the sintering.
The cooling step is cooling the cemented carbide intermediate after the sintering step. For example, the cemented carbide can be obtained by quenching the cemented carbide intermediate in Ar gas under a condition of a pressure of 100 to 400 MPaG.
The mixing conditions in the present embodiment are different in media diameter and mixing time from general cemented carbide raw material mixing conditions. The sintering conditions in the present embodiment are different in pressure and sintering time from general cemented carbide sintering conditions. It is presumed that thereby, homogeneity and diffusion of atoms can be promoted, and it is possible to obtain the cemented carbide of the present disclosure wherein the first element is segregated in the first interface region between the tungsten carbide particles adjacent to each other, and the first element is present at a C site of tungsten carbide in the first interface region. It has been newly found as a result of extensive studies by the present inventors that the cemented carbide of the present disclosure can be realized by such mixing conditions and sintering conditions. The mixing conditions and the sintering conditions used in the present embodiment would reduce production efficiency and thus were not adopted by those skilled in the art.
The cutting tool of the present embodiment includes a cutting edge formed from the cemented carbide of Embodiment 1. In the present disclosure, the term cutting edge means a portion involved in cutting. More specifically, the term cutting edge means a region surrounded by a cutting edge ridgeline and a virtual plane having a distance of 2 mm from the cutting edge ridgeline to the cemented carbide side.
Examples of the cutting tool include a cutting bit, a drill, an end mill, an indexable cutting insert for milling working, an indexable cutting insert for turning working, a metal saw, a gear cutting tool, a reamer, and a tap. In particular, as shown in
The cemented carbide of the present embodiment may constitute the whole of each of these tools, or a part thereof. Here, the term “constituting a part” refers to, for example, a mode of forming a cutting edge portion by brazing the cemented carbide of the present embodiment at a predetermined position of an arbitrary base material.
The cutting tool of the present embodiment may further include a hard film that coats at least a part of the surface of the base material formed from the cemented carbide. For example, diamond-like carbon or diamond can be used as the hard film.
The cutting tool of the present embodiment can be obtained by compacting the cemented carbide of Embodiment 1 into a desired shape.
The present embodiment will be described more specifically with reference to Examples. However, the present embodiment is not limited by these Examples.
A cemented carbide of each sample was made by the following procedure.
A WC powder (average particle diameter of 0.3 μm), a Co powder (average particle diameter of 1.0 μm), a Re powder (average particle diameter of 1.0 μm), a B powder (average particle diameter of 1.0 μm), an Al powder (average particle diameter of 1.0 μm), a Si powder (average particle diameter of 1.0 μm), an Fe powder (average particle diameter of 1.0 μm), a Ni powder (average particle diameter of 1.0 μm), a Ge powder (average particle diameter of 1.0 μm), a Ru Powder (average particle diameter of 1.0 μm), an Os powder (average particle diameter of 1.0 μm), an Ir powder (average particle diameter of 1.0 μm), and a Pt powder (average particle diameter of 1.0 μm) were prepared at the proportions described in the “Raw material powders” column of Table 1 and mixed in a ball mill to obtain mixed powders. For example, in sample 1, the WC powder, the Co powder, and the Re powder were prepared at a mass ratio of 91.9:7.8:0.3 and mixed in a ball mill to obtain a mixed powder. The mixing conditions are as described in the “Mixing conditions” column of Table 1. For example, in sample 1, a ball mill was used, the media diameter was φ6 mm, the rotation speed was 120 rpm, the filling percentage was 40%, and the mixing time was 8 hours.
Next, the mixed powders were each pressed to fabricate a round bar-shaped compact. Next, the compact was sintered in Ar gas at the temperature, time, and pressure described in the “Sintering conditions” column of Table 1 to obtain a cemented carbide intermediate. Next, the cemented carbide intermediate was quenched in Ar gas under a condition of a pressure of 200 MPaG to obtain the cemented carbide of each sample.
A round bar formed from the cemented carbide obtained was worked to fabricate a drill for working a printed circuit board (PCB (Printed Circuit Board) drill) having an edge diameter of 90.2 mm.
<Content (% by volume) of Tungsten Carbide Particles in Cemented Carbide and Content (% by Volume) of Binder Phase in Cemented Carbide>
The content (% by volume) of the tungsten carbide particles in the cemented carbide and the content (% by volume) of the binder phase in the cemented carbide of each sample were measured. A specific measuring method is as described in Embodiment 1. Results thereof are shown in the “WC particle content” and “Binder phase content” columns of “Cemented carbide” of Table 2. Further, the sum of the content of the tungsten carbide particles and the content of the binder phase in the cemented carbide is shown in the “WC particle+binder phase content” column of “Cemented carbide” of Table 2.
In the cemented carbide of each sample, the cobalt content of the binder phase was measured. A specific measuring method is as described in Embodiment 1. Results thereof are shown in the “Co content of binder phase” column of “Cemented carbide” of Table 2.
In the cemented carbide of each sample, the type of the first element included in the cemented carbide and the total content (atomic %) of the first element in the cemented carbide were measured. A specific measuring method is as described in Embodiment 1. Results thereof are shown in the “Type” and “Content” columns of “First element” of “Cemented carbide” of Table 2. When the number of types of the first element is one, the “Content” of “First element” means the content of the one type of the first element. When the number of types of the first element is two, the “Content” of “First element” means the total content of the two types of the first element.
<Presence or Absence of Segregation of First Element in First Interface Region and the Site in which First Element was Present>
In the cemented carbide of each sample, the presence or absence of segregation of the first element in the first interface region between the tungsten carbide particles adjacent to each other and the site at which the first element was present were confirmed. A specific confirming method is as described in Embodiment 1. Results thereof are shown in the “Segregation of first element” and “Site at which first element was present” columns in “First interface region” of “Cemented carbide” of Table 2.
The Rockwell hardness (HRC) of the cemented carbide of each sample was measured according to “JIS Z 2245:2016 Rockwell hardness test—test method.” The measurement conditions are room temperature (23° C.±5° C.), a test force of 60N, and a holding time of 4 seconds. Results thereof are shown in the “Rockwell hardness” column of Table 2.
By using a PCB drill of each sample, a commercially available printed circuit board for a semiconductor package was subjected to drill working to evaluate the hole position accuracy. The drill working conditions were a rotation speed of 160 krpm, a feed speed of 3.2 m/min, and a drawing speed of 25 m/min. The number of drilled holes (the number of hits) when the hole position accuracy (ave+3σ (μm)) exceeded 50 μm was measured. Results thereof are shown in the “Cutting test” column of Table 2. The values in Table 2 are values obtained by rounding down the actual numbers of drilled holes to the nearest hundred. For example, when the actual number of drilled holes was 4650, 4600 was entered in the “Cutting test” column. A larger number of drilled holes shows a higher hole position accuracy of the cutting tool and a longer tool life thereof.
The cemented carbides and cutting tools of sample 1 to sample 20 correspond to Examples. The cemented carbides and cutting tools of sample 1-1 to sample 1-9 correspond to Comparative Examples. It was confirmed that the cutting tools of sample 1 to sample 20 (Examples) had a longer tool life than the cutting tools of sample 1-1 to sample 1-9 (Comparative Examples). It is presumed that this is because the cemented carbides of sample 1 to sample 19 have excellent wear resistance and breakage resistance.
The embodiments and the Examples of the present disclosure have been described as above, and it is also planned from the beginning to appropriately combine the configurations of the embodiments and the Examples described above and to modify these in various ways.
The embodiments and the Examples disclosed this time should be considered to be illustrative in all respects and non-limiting. The scope of the present invention is defined by the Claims, not by the above embodiments and Examples, and is intended to include all modifications within the meaning and scope equivalent to the Claims.
1 tungsten carbide particle, 2 binder phase, 3 cemented carbide, 10 cutting tool, 11 cutting edge
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2023/003933 | 2/7/2023 | WO |
