JP5185032B2 - Cutting tools - Google Patents

Description

  The present invention relates to a cutting tool having both a cemented carbide layer and a cermet layer. In particular, the present invention relates to a cutting tool that is excellent in impact resistance and obtains a good finished surface gloss.

  Conventionally, cemented carbide in which ceramic particles (hard phase) such as Ti compounds such as WC (tungsten carbide) and TiCN (titanium carbonitride) are bonded to the base material of a cutting tool with an iron group metal (binding phase) such as Co or Ni. Alloys and cermets are used.

  In general, cermet has a high hardness because a Ti compound such as TiCN is mainly used as a hard phase, but is considered to have lower toughness than a cemented carbide containing WC as a main hard phase. Therefore, a cutting tool having a base material made of cermet has a narrow application range and is mainly used for low-load finishing. In contrast, Patent Document 1 discloses that the fracture resistance is improved by adjusting the W concentration in the cermet. Patent Documents 2 and 3 propose composite materials in which cermet and cemented carbide are laminated and joined. Patent Document 2 discloses a bonding material in which a cemented carbide and a cermet are separately manufactured, and the bonded surfaces of both are ground and the surface roughness is reduced, and then the laminated material is heated and integrated. Yes. Patent Document 3 discloses a cemented carbide member obtained by stacking separately manufactured sintered bodies and joining them by an electric heating method, or by stacking separately manufactured press-formed bodies and sintering them.

JP 2005-272877 JP-A-6-240308 Japanese Unexamined Patent Publication No. 7-207398

  There is a limit to the improvement of toughness by adjusting the W concentration described in Patent Document 1, and it is difficult to greatly improve the performance. On the other hand, when the bonding materials described in Patent Documents 2 and 3 are used for cutting, impact resistance can be improved by providing a cemented carbide having excellent toughness. However, these bonding materials have a high ratio of cemented carbide. For example, when a bonding material in which a cemented carbide alloy and a cermet are halved is used for a cutting tool, the cutting edge is only cermet or only cemented carbide. Cemented carbide is more reactive with steel than cermet. Therefore, if the ratio of the cemented carbide in the contact surface with the workpiece (work material) is high, it is difficult to obtain a good finished surface gloss, which is an advantage of cermet, particularly in steel cutting.

  Then, one of the objectives of this invention is providing the cutting tool which is excellent in impact resistance and can obtain favorable finished surface gloss.

  The present invention achieves the above object by providing a thin cemented carbide layer on the cermet layer. Specifically, the cutting tool of the present invention comprises a base material in which at least one cemented carbide layer and at least one cermet layer are laminated, and at least part of the surface side of the base material, in particular, a cutting blade. And the cemented carbide layer is arrange | positioned in at least one part of the rake face side connected to a cutting blade. When the thickness of the portion with the largest thickness in the laminating direction of this substrate is h1, and the thickness of the portion with the largest thickness in the laminating direction of the cemented carbide layer present in the cutting edge portion is h2, h2 / h1 satisfies 0.002 or more and 0.02 or less. The above-mentioned “cutting edge portion” refers to a cutting edge of the base material and a region in the vicinity thereof, and is a region from the flank face to the rake face direction up to 1000 μm.

  The cutting tool of the present invention is provided with a cemented carbide layer that is tougher than the cermet layer on the cermet layer at a part of the cutting blade and the rake face that comes into contact with the workpiece, chips, etc. Even when subjected to an impact due to, it is difficult for defects to occur, the impact resistance can be improved, and the toughness is excellent. Therefore, the tool of the present invention can also be used in fields where application is difficult due to chipping or the like with a cermet tool. Further, in the tool of the present invention, the ratio of the cermet on the laminated surface (the surface where the laminated state can be seen) can be increased particularly by making the cemented carbide layer provided in the cutting edge portion thinner than the entire thickness. Therefore, by using the tool of the present invention so that the laminated surface is in contact with the workpiece, a finished surface gloss equivalent to that of cermet can be obtained. As described above, the tool of the present invention can obtain good finished surface gloss while having high toughness. Hereinafter, the present invention will be described in detail.

〔Cutting tools〕
<Laminated structure>
The tool of the present invention includes a base material composed of a laminate (composite material) in which a cemented carbide layer and a cermet layer are laminated and integrated. The tool of the present invention may further include a coating film as described later, or as will be described later. A cemented carbide layer is provided on at least a part of the surface side of the base material, in particular, the cutting edge and at least a part of the rake face connected to the cutting edge. The entire rake face may be substantially formed of a cemented carbide layer. The tool of the present invention is generally superior in impact resistance compared to a cermet tool by providing a cemented carbide layer with higher toughness than cermet on the rake face side where chips are easy to contact. Can be effectively suppressed. In particular, the chipping resistance can be improved by providing a cemented carbide layer on the cutting edge. The tool of the present invention may have a partially laminated structure, but if the whole has a laminated structure, the productivity is good. The specific form is a two-layer structure in which one cermet layer and one cemented carbide layer are laminated, one cermet layer as an inner layer, and a pair of cemented carbide layers sandwiching both sides of the inner layer. Three-layer structure, an inner structure with one cermet layer as the inner layer, and an internal structure (two cross-sections) with a cemented carbide layer covering the entire outer surface, one outer surface with one cermet layer as the central layer And a concentric structure (two-layer cross section) in which a cemented carbide layer is disposed so as to surround a part of the cermet layer and a part of the cermet layer is exposed. The molded body of the inner structure or the concentric structure is, for example, a concentric mold, specifically, a columnar inner mold, a frame-shaped outer mold disposed on the outer periphery of the inner mold, and an outer mold. It can be formed by using one having a frame-shaped mold body arranged on the outer periphery of the mold. In the case of an internal structure or a concentric structure, the cermet layer is exposed at the portion that contacts the workpiece. The two-layer structure or the three-layer structure is preferable because a cermet layer is easily present in a portion in contact with the workpiece. The cutting edge refers to an intersection line (ridge line) between the rake face and the flank face.

<Join method>
The cemented carbide layer and the cermet layer are prepared by mixing the raw material powders constituting each layer, and then using a granulator or the like to form granulated powder. The granulated powder is sequentially supplied to a mold and laminated, and added in this state. A laminated press-molded body is produced by pressing, and the molded body is sintered to be integrally joined. That is, rather than laminating a sintered body or a press-molded body as in the prior art, the tool of the present invention is produced in a laminated state at the raw material powder stage before molding. The manufacturing methods disclosed in Patent Documents 2 and 3 are manufactured by joining the surface after grinding the surface after manufacturing the sintered body, or by separately manufacturing the press-molded body and the sintered body. There are many processes. In particular, it is considered difficult to produce a thin press-molded body or sintered body such as a cemented carbide layer in the tool of the present invention, and to adhere the molded bodies and the sintered bodies together without any gaps. Therefore, the bonding materials disclosed in Patent Documents 2 and 3 are thought to flatten the boundary (bonding interface) between the cemented carbide and the cermet by performing surface grinding or die molding. In such a shape, peeling due to a difference in characteristics such as a thermal expansion coefficient between the two tends to occur. When both are separated, both the characteristics of the cemented carbide and the characteristics of the cermet cannot be fully utilized. In addition, if there is a gap between the sintered bodies or between the molded bodies, a binder phase pool is likely to be generated in the gap. Therefore, in order to prevent the binder phase pool, the conventional technique flattens the bonding surface. It is thought that. On the other hand, since the tool of the present invention can be manufactured by increasing the number of times of powder feeding in one mold with respect to the manufacturing process of a normal cemented carbide or cermet, a series of processes commonly used for powder metallurgy Therefore, it can be easily manufactured with high productivity without greatly deviating from the above. Further, in manufacturing the tool of the present invention, there is almost no increase in process costs other than the pressing step, which is economically preferable. Furthermore, by sintering the molded body in which the raw material powders are laminated, a composite material (base material) that is difficult to peel off both layers and has excellent bondability can be obtained.

<Boundary shape>
The present invention tool is formed by laminating the raw material powder (granulated powder) as described above, and then sintering, resulting in the boundary between the cemented carbide layer and the cermet layer (bonding interface) due to the raw material powder. As a result, microscopic irregularities appear. It is thought that it is hard to peel off because both layers engage with each other by this unevenness. Further, since the tool of the present invention has a thin cemented carbide layer, the shape of the cemented carbide layer easily follows the shape of the punch (is easily transferred). Therefore, when a punch with unevenness such as a chip breaker protrusion or groove is used on the pressing surface, the boundary has unevenness along the punch, making it easier to engage both layers, and the bonding properties of both layers It is thought that it is raised.

<Cemented carbide layer thickness>
The tool of the present invention is characterized in that the cemented carbide layer is thin and the volume ratio of the cermet layer is large (greater than 50%). Specifically, the thickness of the thickest portion in the stacking direction of both layers of the tool of the present invention is h1, and the thickness of the thickest portion in the stacking direction of the cemented carbide layer present in the cutting edge portion When h2 is h2, h2 / h1 satisfies 0.002 or more and 0.02 or less. In particular, h2 / h1 preferably satisfies 0.002 or more and 0.01 or less. Since the cemented carbide layer present in the cutting edge portion is thin, the cutting blade and the ratio of the cermet layer in the contact surface with the workpiece in the vicinity thereof increase, so that the tool of the present invention is steel cutting, Finished surface gloss equivalent to that of a cermet tool can be obtained. In addition, the cemented carbide layer on the tool surface has a compressive stress based on the difference in thermal expansion coefficient between the cemented carbide and the cermet, but this compressive stress is reduced because the thickness of the cemented carbide layer is thin. It tends to grow. A certain amount of compressive stress is expected to contribute to the improvement of fracture resistance. The tool of the present invention is excellent in toughness and fracture resistance as described above, and thus has a wider range of application than conventional cermet tools having low fracture resistance and toughness. In addition, the tool of the present invention mainly composed of a cermet layer can be used. By using such a tool of the present invention, the use amount of W, which is a rare metal (clerk number: 0.006), in which supply risk occurs is reduced, and within a range where performance degradation does not occur, the number of clarks: 0.46. Increasing the number of cermet layers mainly composed of Ti compounds can contribute to resource saving. Since the price of W has soared in recent years, it is economically preferable to reduce the amount of W used.

The measurement of h1 and h2 is performed using, for example, a microscope observation image of the cross section of the cutting tool. FIG. 1 is a schematic cross-sectional explanatory diagram for explaining a method for measuring the thickness of a tool and a cemented carbide layer and the cutting edge throughput, (I) is a two-layer tool, and (II) is a three-layer tool. (III) is an enlarged view of the cutting edge portion. FIG. 1 shows a polygonal column-shaped cutting tool (chip). In (I), the upper surface corresponds to a rake surface, and in (II), the upper and lower surfaces correspond to a rake surface, and a part of the protrusion and a part of the recess constitute a chip breaker. Further, in FIG. 1, the cemented carbide layer, the unevenness of the boundary, the chip breaker, and the cutting edge portion are highlighted (the same applies to FIG. 2 described later). As shown in FIG. 1 (I), the cutting tool (base material) 100 is arranged so that the lamination direction of the cemented carbide layer 101 and the cermet layer 102 is orthogonal to the reference plane S, and in this state the cemented carbide layer 101 a boundary 103 between the cermet layer 102 over the entire existing measures the length l _f to the surface 101f of the cemented carbide layer 100 from the reference plane S, in the stacking direction of the cutting tool 100 the length l _f The thickness is T. As shown in FIG. 1 (II), when there is a part where the cutting tool 100 is not in contact with the reference surface S, the part that is not in contact is from the reference surface S to the reference surface S of the outer surface of the cutting tool 100. The length l _fu to the opposite surface is measured, and the difference between the lengths l _f and l _fu at the same position: l _f −l _fu is the thickness T. The maximum value T _max of the thickness T is set to h1. Further, the length l from the reference plane S to the boundary and the length l _f at the same position are measured over the entire area of the boundary 103 in the above-described arrangement state, and the difference: l _f −l is determined as the cemented carbide layer 101. The thickness t in the stacking direction of The maximum value t _max of the thickness t near the cutting edge portion 100c (in the vicinity of the corner in FIGS. 1 (I) and 1 (II) (the region from the flank face to the rake face direction of 1000 μm)) is set to h2. When cutting edge processing such as honing is performed on the cutting edge portion as shown in FIG. 1 (III), the cutting edge portion 100c is within the range where the cutting edge processing has been performed (the ridgeline 200 connecting the flank 201 and the rake face 202). , Including the range from the flank 201 to the intersection 203 of the ridgeline 200 and the rake face 202 (blade edge processing width w)). If the entire surface of the cutting tool 100 is in contact with the reference plane S as shown in FIG. 1 (I), h1 may be obtained by measuring the surface 101f of the cemented carbide layer 101 with a measuring instrument such as a height gauge.

  The specific value of the thickness h2 of the cemented carbide layer is preferably 10 μm or more and 100 μm or less, more preferably 10 μm or more and 50 μm. If it is less than 10μm, it does not play the role of a tough layer and is likely to be damaged during cutting, and if it exceeds 100μm, the proportion of the cemented carbide layer in the contact surface with the workpiece increases, especially when cutting steel. In this case, it is difficult to obtain a good finished surface gloss. In particular, when the thickness is 50 μm or less, it is considered that the compressive stress existing in the cemented carbide layer is increased, and the effect of improving toughness is further increased.

  The thickness of the cemented carbide layer may be uniform over the entire cutting edge portion or may be uniform over the entire substrate. For example, the thickness may be uniform over the entire rake face. Also, the thickness of the cemented carbide layer may be different, that is, the thickness may be partially different. For example, the thickness of the cemented carbide layer present at a specific location on the rake face may be increased or decreased. In particular, the tool of the present invention is a polygonal-blade blade-tip-exchangeable tip, a cutting edge is formed at the corner, and a chip breaker is provided on a rake face connected to the cutting blade, and a cemented carbide layer is also provided on the breaker portion. When it is provided, it is preferable to make the cemented carbide layer present in the breaker part thicker than the cutting edge part. The chip breaker is easily subjected to an impact due to chip contact. Therefore, by providing a thicker cemented carbide layer with excellent toughness to the above-mentioned breaker part, impact resistance can be improved, and by relatively thinning the cemented carbide layer of the cutting edge part, the cutting edge and its vicinity Since the ratio of the cermet layer on the flank side in contact with the workpiece is increased, a good finished surface gloss can be obtained more remarkably. Specifically, when the thickness of the cemented carbide layer that protrudes most from the rake face in the chip breaker is hb (see FIG. 1 (II)), h2 / hb is preferably 0.5 or more and 1 or less. . If it is less than 0.5, the difference in the thickness of the cemented carbide layer becomes too large and deformation is likely to occur, and if it exceeds 1.0, it is difficult to sufficiently obtain both the above-described improvement in impact resistance and the good effect of maintaining the finished surface gloss.

<Cemented carbide layer>
《Hard phase》
The cemented carbide layer is composed of a WC-based cemented carbide with WC particles as the main hard phase and iron group metal such as Co as the main binder phase. This cemented carbide layer contains a larger amount of WC particles as a hard phase than the cermet layer. In particular, the cemented carbide layer preferably contains a total of more than 65% by mass of W and WC, and more preferably contains 80% by mass or more. The WC particles are particularly preferably 0.1 μm or more and 1.0 μm or less. Within the above range, if the average particle size is small, a cemented carbide layer having high hardness and excellent wear resistance can be obtained, and if it is large, a cemented carbide layer having excellent toughness such as heat cracking resistance can be obtained. Further, when the WC particles are in the above range, a small blade edge treatment with a blade edge treatment width of 0.05 mm or less is possible, and the cutting edge ridge line can be sharpened. Furthermore, when the WC particles are in the above range, when a coating film is formed on the cemented carbide layer existing on the surface of the tool of the present invention by the PVD method, in the coating film, near the interface with the cemented carbide layer. The effect is that the crystal grains of the film are refined to follow the fine WC particles and the adhesion of the film is enhanced. The size of the WC particles can be selected according to the desired properties. Since the size of the WC particles in the cemented carbide layer generally depends on the raw material powder, it may be adjusted according to the size of the raw material powder. Similarly, the size of the hard phase particles in the cermet layer described later can be adjusted by the size of the raw material powder.

<< Binder Phase >>
The binder phase is mainly composed of an iron group metal (80% by mass or more is an iron group metal), and allows an element considered to be derived from the raw material powder in addition to the iron group metal (solid solution). The iron group metal may contain Fe or Ni in addition to Co, but only Co is preferable. The content of the binder phase in the cemented carbide layer is preferably 3% by mass or more and 20% by mass or less. If it exceeds 20% by mass, the toughness increases, but the strength and wear resistance tend to decrease, and if it is less than 3% by mass, the toughness tends to decrease. In particular, the content of 5% by mass or more and 15% by mass or less is preferable because of excellent toughness.

《Other contents》
The cemented carbide layer is selected from one or more elements selected from the group of metal elements of the periodic table IVa, Va, VIa in addition to WC particles and iron group metals, and 1 It may contain a compound or solid solution composed of one or more elements and one or more elements selected from the group consisting of carbon, nitrogen, oxygen and boron. Specific elements include Cr, Ta, Ti, Nb, Zr, and V, and examples of the compound include (Ta, Nb) C, VC, Cr ₂ C ₃ , NbC, and TiCN. These elements and compounds exist in the binder phase (solid solution) or exist as particles and function as a hard phase. Many of these elements and compounds have an action of suppressing the grain growth of WC particles during sintering. When the cemented carbide layer contains these elements and compounds, the total content is preferably 40% by mass or less (including 0% by mass). The WC particles constitute the remainder excluding these elements, compounds, binder phases and impurities.

  In particular, the cemented carbide layer preferably contains Cr, and the cemented phase amount of the cemented carbide layer is x1 (mass%), and the content of Cr in the cemented carbide layer is x2 (mass%). X2 / x1 preferably satisfies 0.02 or more and 0.2 or less. If the Cr content is less than 0.02 and the Cr content is too small, the effect of suppressing grain growth cannot be obtained sufficiently, and the WC in the cemented carbide layer becomes coarse, resulting in a decrease in wear resistance. On the other hand, if it exceeds 0.2 and there is too much Cr, it becomes easy to precipitate and agglomerate Cr in the structure of the cemented carbide, and breakage occurs starting from this precipitate and the like, leading to a reduction in fracture resistance. Moreover, the liquid phase appearance temperature of a cemented carbide can be adjusted by containing Cr in the said range. As the Cr content increases, the liquid phase appearance temperature tends to decrease, and the difference between the liquid phase appearance temperature of the cemented carbide and the liquid phase appearance temperature of the cermet can be reduced. By reducing the difference, liquid phase movement can be suppressed, and performance degradation and deformation due to liquid phase movement can be reduced. The composition of the raw material powder is designed so that the cemented carbide layer has a desired composition.

<Cermet layer>
《Hard phase》
The cermet layer is composed of a hard material containing at least a Ti compound as a hard phase and having an iron group metal such as Co or Ni as a main binder phase. The Ti compound typically includes at least one compound selected from Ti carbide (TiC), Ti nitride (TiN), and Ti carbonitride (TiCN). In addition, the Ti compound is a composite compound containing Ti and periodic group IVa, Va, VIa group metal elements (excluding Ti) and at least one of C and N, that is, a composite carbide containing Ti, Ti. The composite nitride containing and the composite carbonitride containing Ti are mentioned. Specific composite compounds are (Ti, W, Mo, Ta, Nb) (C, N), (Ti, W, Nb) (C, N), (Ti, W, Mo, Ta) (C, N ), (Ti, W, Mo, Zr) (C, N) and the like. The particles composed of the Ti compound constituting the hard phase may be composed of a single composition (for example, TiCN), or may have a cored structure in which the Ti concentration is different between the central portion and the peripheral portion. According to SEM observation, among the cored structure particles, particles containing a large amount of Ti at the center portion appear black (black core particles), and particles containing a large amount of W at the center portion appear white (white core particles). The average particle size of these hard phase particles (in the case of cored structure particles including the peripheral portion) is preferably 0.5 to 5.0 μm, particularly preferably 1.0 to 3.0 μm. Further, it is preferable that the cermet layer contains at least W so that the difference in thermal expansion coefficient from the cemented carbide layer is reduced and deformation and peeling are easily suppressed. In order to make W exist in the cermet layer, WC is used as a raw material. The raw material WC exists as a W after being sintered and contained (solid solution) in the binder phase, etc., and there is a tendency for the composite compound containing a large amount of WC and W to precipitate as the amount of raw material added increases. . The precipitated WC and composite compound function as a hard phase. In addition, white core particles tend to increase as the amount of raw material WC increases. When the cermet layer is 100% by mass, the above effect can be expected if the total content of WC and W is 15% by mass or more. As the total content of W and WC increases, it is easy to reduce the difference in thermal expansion coefficient, but if too much, it is difficult to obtain the effect of improving toughness due to the presence of compressive stress in the cemented carbide layer. The total content is preferably 65% by mass or less. A more preferable total content of WC and W is 15% by mass or more and 40% by mass or less. Since the amount of WC and W in the cermet layer generally depends on the amount of WC added to the raw material powder, the amount of WC added to the raw material can be adjusted to the predetermined range. If the average particle size of WC is 1 to 8 μm, especially 3 to 5 μm, the WC that is relatively coarse is used, and the WC deposited on the cermet layer becomes relatively coarse, improving the resistance to crack growth. The effect is obtained. Measurement of the amount of WC in the cermet layer can be performed, for example, by identifying the compound with XRD and analyzing the composition using EDX, EPMA, fluorescent X-ray, IPC-AES, etc. This can be done by analyzing the composition with the above EDX.

<< Binder Phase >>
The content of the binder phase in the cermet layer is preferably 8% by mass or more and 20% by mass or less. If it exceeds 20% by mass, the toughness increases, but the strength and wear resistance decrease. If it is less than 8% by mass, the sinterability and toughness decrease. This binder phase is mainly composed of an iron group metal (80% by mass or more is an iron group metal), and allows an element considered to be caused by the raw material powder in addition to the iron group metal to be contained (solid solution). . The iron group metal may contain Ni in addition to Co. However, if Ni is contained in a large amount, liquid phase transfer in which Ni moves to the cemented carbide layer easily occurs during sintering or the like. If the amount of liquid phase transfer is large, the composition of the cemented carbide layer may change, and there is a risk of performance deterioration such as a decrease in hardness, deformation of the tool of the present invention, and the like. Therefore, the binder phase of the cermet layer is preferably rich in Co. When the iron group metal in the binder phase of the cermet layer is 100% by mass, 80% by mass or more, particularly 90% by mass or more may be Co. Preferably, only Co is optimal. Thus, by containing much Co in a binder phase, there can exist an effect, such as suppression of a deformation | transformation and suppression of a performance fall.

  A laminated body of cemented carbide and cermet is liable to cause liquid phase movement during sintering due to differences in composition and the like, and as described above, performance deterioration and deformation are liable to occur due to liquid phase movement. However, if the difference between the content of the binder phase in the cermet layer and the content of the binder phase in the cemented carbide layer is small, the liquid phase transfer amount can be reduced, and the deterioration of the characteristics accompanying the liquid phase transfer can be reduced. Specifically, when the binder phase content of the cemented carbide layer is y1 (volume%) and the binder phase content of the cermet layer is y2 (volume%), y1 / y2 satisfies 0.8 or more and 1.2 or less. It is preferable. If it is less than 0.8 and more than 1.2, liquid phase transfer tends to occur in the direction from the larger amount of the binder phase to the smaller amount. Moreover, when Cr is added to the cemented carbide layer as described above, liquid phase transfer can be suppressed.

《Other contents》
The cermet layer may further contain elements such as Cr, Ta, Nb, Zr, V, Mo and compounds such as (Ta, Nb) C, VC, Cr ₂ C ₃ , and NbC, similar to the above cemented carbide. The content is preferably 5 to 50% by mass in total. In the cermet layer, the remainder excluding the binder phase and impurities constitutes the hard phase. The composition of the raw material powder is designed so that the cermet layer has a desired composition.

《Blade treatment》
In the tool of the present invention, at least a part of the surface ridge line becomes a cutting edge. The cutting edge may be in the as-sintered state, but in addition to being able to improve chipping resistance by performing cutting edge processing such as honing, it is better to reduce the work surface roughness of the workpiece (work material) A machined surface can be obtained. Here, although the base material made of cermet is a sharp cutting edge as it is sintered, chipping is likely to occur due to low toughness, and even when trying to perform cutting edge processing, because the toughness is low, sharp cutting edge processing is difficult, The machined surface roughness tends to increase. On the other hand, since the tool of the present invention includes a cemented carbide layer having high toughness in at least a part of a portion serving as a cutting edge, the chipping resistance is excellent even without performing blade edge treatment. Even when performing the blade edge treatment, the tool of the present invention includes a cemented carbide layer having high toughness in the portion subjected to the blade edge treatment, and therefore, a sharp edge can be obtained by the above-mentioned blade edge treatment. Can be made smaller. Furthermore, in addition to improving the processing accuracy, the generation of burrs can also be suppressed. The cutting edge processing amount is preferably such that the cutting edge processing width is more than 0 mm and not more than 0.05 mm. If it exceeds 0.05 mm, the cutting edge is not sharp, so the surface roughness will not be small and the processing accuracy cannot be improved sufficiently.

《Compressive stress》
By adjusting the thermal expansion coefficient and shrinkage rate of the cemented carbide layer and the cermet layer, compressive stress can be present in the cemented carbide layer as described above. When materials having different thermal expansion coefficients are laminated, compressive stress is generated on the side having a smaller thermal expansion coefficient, and delamination may occur due to the compressive stress. On the other hand, since the present invention tool is microscopically engaged as described above, delamination due to the compressive stress hardly occurs, and an effect of improving toughness due to the compressive stress can be expected. However, since the delamination occurs when the compressive stress is too large, it is preferable that the compressive stress exists within a range in which delamination does not occur. The adjustment of the compressive stress includes adjusting the thermal expansion coefficient and the shrinkage rate as described above, specifically, adjusting the composition of the raw material powder. The magnitude of the compressive stress is obtained, for example, by wrapping the surface of the cemented carbide layer and measuring the vicinity of the center of the surface by XRD. A suitable magnitude of the compressive stress is about 0.1 to 3.0 GPa.

<Manufacturing method>
The tool of the present invention prepares the granulated powder as described above, sequentially supplies it to the mold so as to obtain a desired laminated structure, presses after filling all the powder into the mold, and presses the laminated structure It can be manufactured by forming a molded body and sintering the molded body. The obtained sintered body (tool of the present invention) has a concavo-convex shape generally corresponding to the size and shape of granulation at the boundary between the cemented carbide layer and the cermet layer. The uneven shape can be changed by adjusting the granulated particle size to, for example, 10 to 200 μm, or adjusting the granulated powder properties such as the granulated particle size, the hardness, density, and shape of the granulated powder, and the press pressure. By controlling these factors, it is possible to obtain the tool of the present invention which is excellent in the bondability between the cemented carbide layer and the cermet layer. The pressure during pressing is preferably 0.5 t / cm ² or more and 2.5 t / cm ² or less. If the density is less than 0.5 t / cm ² , the density of the press-molded body is low, the shrinkage amount during sintering is large, and the dimensional accuracy tends to decrease, and if it exceeds 2.5 t / cm ² , the press-molded body is too dense, Cracks are likely to occur, and more cracks are generated particularly in the case of a molded article having a complicated shape. Since the cemented carbide layer provided on the surface side of the tool of the present invention is relatively thin, it is easy to follow the shape of the punch used for pressing, and the outer shape of the tool and the shape of the boundary between the cemented carbide layer on the surface side and the cermet layer Is a similar shape.

  The above-mentioned sintering also serves as integral bonding of the cemented carbide layer and the cermet layer together with the formation of the sintered body. Sintering can utilize general conditions. For example, the sintering conditions include holding at 1300-1500 ° C. in a vacuum atmosphere for 0.5-3.0 hours.

<Application>
The tool of the present invention combines the characteristics of both a cemented carbide layer and a cermet layer, has high toughness and excellent finished surface accuracy. Therefore, the tool of the present invention can be suitably used particularly for finishing. As a typical form of the tool of the present invention, there are a cutting edge exchangeable tip for milling and a cutting edge exchangeable tip for turning. In addition, use of drills, end mills, metal saws, gear cutting tools, reamers, taps, etc. can be expected.

The tool of the present invention may be a coated cutting tool having a coating film on the substrate surface. Here, the base material which consists of cermets generally has low adhesiveness with a coating film. On the other hand, the tool of the present invention can improve the adhesion with the coating film by providing the cemented carbide layer, and can obtain a good finished surface gloss. The coating film is preferably provided at least on the cutting edge and in the vicinity thereof. The composition of the coating film is, for example, periodic table IVa, Va, VIa group elements, and at least one element selected from Si, Al, carbon (C), nitrogen (N), oxygen (O), and Examples thereof include compounds composed of at least one element selected from boron (B), at least one selected from diamond, diamond-like carbon (DLC), and cubic boron nitride (cBN). That is, carbides, nitrides, oxides, borides, and solid solutions of these elements such as metals, such as TiCN, Al ₂ O ₃ , TiAlN, TiN, AlCrN, TiSiN, diamond, DLC, and cBN Of these, one or more may be mentioned. A coated cutting tool having one or more layers selected from the above-mentioned candidates can further improve wear resistance as compared with a state without a coating layer. The coating film may be a single layer or a plurality of layers, and the total film thickness is preferably 1 to 20 μm. When formed by the PVD method, the total film thickness is more preferably 1 to 10 μm. The thickness of the coating film can be changed by adjusting the film formation time.

The PVD method and the CVD method can be used to form the coating film. For example, when the arc ion plating method is used as the PVD method, the film formation conditions include a substrate temperature: 400 to 600 ° C., an atmospheric pressure: 0.5 to 5 Pa, and a bias voltage: −50 to −150 V. For example, when the thermal CVD method is used as the CVD method, the film forming conditions are: substrate temperature: 800 to 1000 ° C., gas pressure: 5 to 10 MPa, reaction gas: CH ₄ , H ₂ , N ₂ , CO ₂ , AlCl ₃ , TiCl _{4 and the} like. As film formation conditions, known conditions can be used.

  For example, when forming a Ti compound film by the CVD method, if Ni is contained in the cermet layer, Ni may adversely affect the performance of the film. Therefore, increase the amount of Co in the binder phase of the cermet layer. Is considered preferable. On the other hand, when a film is formed by the PVD method, since a film by the PVD method is usually thinner than a CVD method, a sharp cutting edge is easily obtained. In addition, the surface roughness of the film by the PVD method tends to be smaller than that by the CVD method. Therefore, even when a thin film formed by the PVD method is formed on a base material that is not subjected to the above-mentioned blade edge treatment, the wear resistance can be improved, the processed surface roughness is small, and the processing accuracy is excellent. Furthermore, when a PVD film is formed on a base material that has been subjected to a small blade edge treatment with a blade edge treatment width of 0.05 mm or less, chipping of the blade edge can be effectively suppressed while maintaining processing accuracy to some extent.

  The cutting tool of the present invention combines the characteristics of both a cemented carbide layer and a cermet layer, and is excellent in impact resistance and has a good finished surface gloss.

(Test Example 1)
A cutting tool made of a composite material in which a cemented carbide layer and a cermet layer were laminated was produced, and the cutting performance was examined. In this test, a sample having a different thickness of the cemented carbide layer in the cutting edge portion and a sample made of only cermet as a comparison were used.

  The cutting tool was produced as follows. The raw material powder was weighed so as to have the composition shown in Table 1, and these raw material powders were mixed in ethanol for 11 hours with an attritor (ATR), then granulated, and the powder for cemented carbide with an average particle size of 100 μm (Granulated powder) and cermet powder (granulated powder) are obtained. Measurement of the average particle size of the granulated powder was performed by image analysis of a SEM (scanning electron microscope) photograph of the powder, but can also be performed using a particle size measuring instrument or the like. The obtained cemented carbide powder and cermet powder are weighed out so that the cemented carbide layer and the cermet layer have a desired thickness. In Table 1 and Table 15 described later, the “Cr ratio” in the cemented carbide is the content of Cr x2 (mass%) with respect to the binder phase (mainly Co) content x1 (mass%). Ratio: Indicates x2 / x1 (no unit). The “Co ratio” in the cermet indicates the Co content (mass%) when the content of the binder phase (mainly Co + Ni here) is 100 mass%.

A laminated press-molded body is produced using the obtained powder for cemented carbide and cermet powder. In this test, a square pillar-shaped cutting tip with a breaker (Sumitomo Electric Industries, Ltd. model number: SNMG120408N-UX) was produced. Specifically, cemented carbide powder, cermet powder, and cemented carbide powder are sequentially fed to a mold having a predetermined shape, and then pressed at 1.0 t / cm ² to produce a laminated press-formed body. . The obtained molded body was sintered in a vacuum atmosphere at 1430 ° C. for 60 minutes, and as shown in FIG. 2, three layers in which a pair of cemented carbide layers 11 were arranged so as to sandwich one cermet layer 12 A structural composite material is obtained. In this composite material, the entire upper and lower surfaces are substantially formed of a cemented carbide layer, and the side surfaces are formed of a laminated surface of a cemented carbide layer and a cermet layer. At the corner of the obtained composite material, cutting edge processing (cutting edge processing width w (see FIG. 1 (III)): 0.04 mm) is applied to part of the line of intersection between the upper and lower surfaces and the side surface to obtain the cutting tool 10. It is done. The upper and lower surfaces of the cutting tool 10 are the rake face and the side face are the flank face, the intersection line between the rake face and the flank face is the cutting edge, and the dent part and the protruding part of the rake face are chip breakers. In the center of the tool, an attachment hole 14 for attaching to a main body (not shown) is provided.

  The maximum thickness h1 in the stacking direction of the obtained cutting tool is 4.76 mm, the maximum thickness h2 of the cemented carbide layer in the cutting edge part (area from the flank face to the rake face direction is 1000 μm), and the superthickness in the breaker part. Table 3 shows the maximum thickness hb of the hard alloy layer (here, the maximum thickness of the portion protruding to the rake face side of the cutting edge). The thickness h1 of the cutting tool is measured using a height gauge, and the thickness h2 and hb of the cemented carbide layer is measured by observing the section of the cutting tool with a microscope (500 times) and using the observation image. It was. In this observation image, when the shape of the boundary 13 of the cutting tool was examined, the shape was substantially along the outer shape (press punch), but fine irregularities that did not partially follow the punch shape were observed. Moreover, the thickness of the cemented carbide layer in the cutting edge portion is substantially uniform. Furthermore, when the average particle diameter of WC of the cemented carbide layer was measured, it was 0.9 μm. The average particle size is determined by wrapping the cut surface of the tool and performing crystal analysis by SEM, taking the analysis image into an image analyzer and analyzing it, and measuring the particle size (μm) of the WC particles on the cut surface. And the average of these values. For these cutting tools, the amount of the binder phase from the boundary between the two layers to the point 1/2 of the maximum thickness h2 of the cemented carbide layer at the cutting edge part (for example, the point 50 μm from the boundary when h2 = 100 μm) is EPMA. As a result of measurement, the bonded phase amount y1 of the cemented carbide layer is 16.2% by volume, and the bonded phase amount y2 of the cermet layer is 15.8% by volume, y1 / y2: 1.0. The Cr content and the Co ratio can be obtained by measuring the Cr content in the cemented carbide layer and the Co content in the cermet layer in the same manner as the measurement of the binder phase. For the measurement, EDX may be used in addition to EPMA. The total amount of W and WC in the cermet layer was measured and found to be 36.3% by mass. The amount of W was measured in the same manner as the amount of Co above, and the amount of WC was measured using EPMA and XRD at a point 100 μm from the boundary between both layers, and these were combined to obtain the total content of W and WC. . These measured amounts are all average values. When the structure of the cermet layer of the obtained composite material was observed by SEM, TiCN particles, black core particles, and white core particles were present as hard phase particles.

  Using the obtained cutting tool, a toughness test and a finishing test (both turned) were performed under the cutting conditions shown in Table 2. The results are shown in Table 3. As for toughness (breakage resistance), the number of impacts until the tool was damaged was evaluated. In the finishing process, the gloss of the finished surface was evaluated. As for the finished surface gloss, the processed workpiece was visually confirmed, and the case where it had a black metallic luster, the case where it had a white metallic gloss, Δ, and the case where it was cloudy, x. If the finished surface is clean, the metallic luster appears blackish, the normal metallic luster appears whitish, and the roughened surface appears cloudy.

  As shown in Table 3, it can be seen that the sample provided with the cemented carbide layer is superior in toughness as compared with Sample No. 100 consisting only of cermet. In addition, it can be seen that a thin sample having a cemented carbide layer of the cutting edge portion of 100 μm or less can obtain a good finished surface gloss. In particular, it can be seen that a sample having a cemented carbide layer of the cutting edge portion of 10 μm or more and 50 μm or less is excellent in both toughness and finishing accuracy. In addition, in any sample including the cemented carbide layer, the cemented carbide layer did not peel off. The reason for this is considered that microscopic irregularities existed at the boundary between the cemented carbide layer and the cermet layer.

(Test Example 2)
A cutting tool (cutting tip) having the same shape was produced in the same manner as in Test Example 1, and the peeled state of the cemented carbide layer and the cutting performance were examined. In this test, points other than the change in the composition (total content of W and WC) with respect to the cermet layer of the tool used in Test Example 1 are substantially the same as in Test Example 1 (the cemented carbide layer). Composition: Similar to Test Example 1, thickness h1: 4.76 mm, cemented carbide layer thickness h2 at cutting edge: 50 μm (h2 / h1 = 0.01), cemented carbide layer thickness at breaker hb: 100 μm (h2 / hb = 0.5), cutting edge treatment width: 0.04 mm, Cr ratio of cemented carbide layer: 0.06, Co ratio of cermet layer: 88.9 mass%, average particle size of WC particles of cemented carbide layer: 0.9 μm) . By changing the amount of WC used as a raw material, the total content of W and WC in the cermet layer was changed as shown in Table 4. The amount of TiCN added to the raw material was increased or decreased relative to the amount of increase or decrease in the amount of WC added to the raw material, so that the total amount of TiCN and WC was the same as in Test Example 1. Measurement of the amount of W and the amount of WC in the cermet layer was performed in the same manner as in Test Example 1. Further, when the binder phase ratio y1 / y2 between both layers of the tool was examined in the same manner as in Test Example 1, all the samples satisfied y1 / y2: 0.8 to 1.2.

  About the obtained cutting tool, the peeling state of the cemented carbide layer was investigated. The results are shown in Table 4. Further, using the obtained cutting tool, a toughness (breakage resistance) test was performed under the cutting conditions shown in Table 2. The results are shown in Table 4. The peeled state is observed with a microscope or visually, and at the bonding interface between the cemented carbide layer and the cermet layer, at least a part of the cemented carbide layer is not joined with the cermet layer and is floating or part of the cemented carbide layer. Is evaluated as “X”, with no omission or floating but with a fine crack, and with no floating, omission or crack. Evaluation of toughness is the same as in Test Example 1. A sample having a toughness evaluation of “x” has not been subjected to a cutting test because peeling of the cemented carbide layer occurred after sintering.

  As shown in Table 4, it can be seen that the higher the total content of W and WC contained in the cermet layer, the more difficult it is to peel off. However, it can be seen that if there is too much W and WC, the toughness tends to decrease. This is because the total content of W and WC in the tool becomes too large, the difference in thermal expansion coefficient between the cemented carbide layer and the cermet layer is reduced, and the compressive stress introduced into the cemented carbide layer is reduced. It is thought that it was because of. As the amount of WC added as a raw material increased, precipitation of WC and white core particles was observed in the cermet layer.

(Test Example 3)
In the same manner as in Test Example 1, a cutting tip having the same shape was prepared as a base material, a coating film was formed on the base material to prepare a coated cutting tool, and the cutting performance was examined. In this test, the cutting tip used in Test Example 1 is substantially the same as Test Example 1 except that the Co ratio of the cermet layer is changed (the composition of the cemented carbide layer: Test Example 1 and Similarly, the thickness h1: 4.76 mm, the thickness of the cemented carbide layer at the cutting edge h2: 50 μm (h2 / h1 = 0.01), the thickness of the cemented carbide layer at the breaker portion hb: 100 μm (h2 / hb = 0.5) ), Cutting edge treatment width: 0.04 mm, Cr ratio of cemented carbide layer: 0.06, total content of W and WC in cermet layer: 36.3% by mass, average particle size of WC particles in cemented carbide layer: 0.9 μm). The amount of Ni was increased or decreased with respect to the amount of increase or decrease of the Co content, so that the total amount of the binder phase was the same as in Test Example 1. Then, by changing the amount of Co used as a raw material, the amount of Co in the binder phase of the cermet layer was changed as shown in Table 7. In the Co ratio in Table 7, the amount of iron group metal in the binder phase is 100% by mass. The amount of iron group metal and the amount of Co were measured by EPMA in the same manner as in the measurement of the binder phase amount in Test Example 1. Further, when the binder phase amount ratio y1 / y2 of both layers of the base material was examined in the same manner as in Test Example 1, all the samples satisfied 0.8 to 1.2.

  On the obtained base material, a coating film (three layers) having the composition shown in Table 5 was formed under a known condition by a CVD method (here, thermal CVD method) to produce a coated cutting tool, and shown in Table 6. Cutting tests (both turning) were performed under the cutting conditions to examine the wear resistance and toughness (breakage resistance). The results are shown in Table 7. The evaluation of toughness was the same as in Test Example 1, and the evaluation of wear resistance was performed by measuring the flank wear amount (mm) after 30 minutes.

  As shown in Table 7, it can be seen that the higher the Co ratio of the cermet layer to the binder phase, the better the toughness. It is also found that the wear resistance is excellent. This is thought to be because the wear resistance was improved as a result of reducing the decrease in hardness by preventing deformation by reducing the movement of the liquid phase by reducing Ni. In this test, a CVD film was formed, but the base material provided with a cemented carbide layer was excellent in adhesion between the base material and the coating film.

(Test Example 4)
In the same manner as in Test Example 1, a cutting tip having the same shape was prepared as a base material, a coating film was formed on the base material to prepare a coated cutting tool, and the cutting performance was examined. In this test, the cutting tip used in Test Example 1 is substantially the same as Test Example 1 except that the cutting edge processing width was changed (base material composition: same (bonded phase amount ratio y1 of both layers). /y2:1.0), thickness h1: 4.76 mm, the thickness of the cemented carbide layer at the cutting edge h2: 50 μm (h2 / h1 = 0.01), the thickness of the cemented carbide layer at the breaker portion hb: 100 μm (h2 /hb=0.5), Cr ratio of cemented carbide layer: 0.06, total content of W and WC in cermet layer: 36.3% by mass, Co ratio in cermet layer: 88.9% by mass, average of WC particles in cemented carbide layer Particle size: 0.9 μm).

  A coating film is formed on the obtained substrate by the PVD method (here, arc ion plating method) as follows. Argon gas is introduced into the chamber of the deposition system, the pressure in the chamber is maintained at 3.0 Pa, the substrate bias voltage is -1000 V, and the substrate surface is cleaned using a tungsten (W) filament. After 30 minutes, the argon gas is evacuated from the chamber and film formation is subsequently performed. The film is formed by setting the substrate temperature to a predetermined temperature, in a vacuum state, or by introducing an arc discharge between the evaporation source and the chamber while introducing at least one of nitrogen, methane and oxygen as the reaction gas. To evaporate the cathode material. In this test, a coating film (two layers) having the composition shown in Table 8 was formed. The film forming conditions were as follows: substrate temperature: 500 ° C., bias voltage: −100 V, and atmospheric pressure: 1.5 Pa.

  Using the obtained coated cutting tool, a cutting test (both turned) was performed under the cutting conditions shown in Table 9, and the toughness (breakage resistance) and the burr state of the workpiece were examined. The results are shown in Table 10. The toughness evaluation method is the same as in Test Example 1. The burr state of the workpiece was evaluated by measuring the height of the burr generated on the workpiece and evaluating the burr height as 1 mm or less: ◯, 1 mm to 1.5 mm or less: Δ, 1.5 mm or more: ×.

  As shown in Table 10, it can be seen that the toughness can be improved by performing the cutting edge treatment. In particular, it can be seen that the generation of burrs can be suppressed by obtaining a sharp cutting edge by a small cutting edge treatment with a cutting edge treatment width of 0.05 mm or less. In addition, since the base material has a cemented carbide layer, it has excellent adhesion to the coating film, and by providing a PVD film on the base material that has been subjected to a cutting edge treatment of 0.05 mm or less, the above toughness is achieved. In addition to improvement, good machining accuracy can be achieved.

(Test Example 5)
A cutting tool (cutting tip) having the same shape was produced in the same manner as in Test Example 1, and the cutting performance was examined. In this test, the tool used in Test Example 1 is substantially the same as Test Example 1 except that the content of Cr in the cemented carbide layer is changed (the composition of the cermet layer: Test Example 1). Similar to, thickness h1: 4.76mm, cutting edge part cemented carbide layer thickness h2: 50μm (h2 / h1 = 0.01), breaker part cemented carbide layer thickness hb: 100μm (h2 / hb = 0.5), blade edge treatment width: 0.04 mm, average particle size of WC particles in cemented carbide layer: 0.9 μm, total content of W and WC in cermet layer: 36.3 mass%, Co ratio in cermet layer: 88.9 mass%) . By changing the amount of Cr used as the raw material, the Cr content of the cemented carbide layer was changed as shown in Table 12. The amount of WC added as a raw material was increased or decreased with respect to the amount of increase in the amount of Cr added as a raw material, and the Co content was kept constant (Co: 10% by mass). Further, when the binder phase amount ratio y1 / y2 of both layers of the substrate was examined in the same manner as in Test Example 1, all the samples satisfied y1 / y2: 0.8 to 1.2.

  Using the obtained cutting tool, a cutting test was performed under the cutting conditions shown in Table 11, and the wear resistance and toughness (breakage resistance) were examined. The results are shown in Table 12. The evaluation methods for wear resistance and toughness are the same as in Test Example 3. In Table 12, “x2 / x1” indicates the ratio of the content of Cr: x2 (mass%) to the content of the binder phase (Co) in the cemented carbide layer: x1 (mass%). The Cr amount was measured in the same manner as in Test Example 1 using EPMA. The results are shown in Table 12.

  As shown in Table 12, when the Cr content ratio x2 / x1 in the cemented carbide layer satisfies 0.02 or more and 0.2 or less, wear resistance decreases due to coarsening of WC particles, and fracture resistance due to Cr precipitation, etc. It can be seen that the decrease in the resistance can be suppressed, and both the wear resistance and the toughness are excellent. In addition, it is considered that deformation and deterioration of performance due to liquid phase transfer could be suppressed by containing an appropriate amount of Cr.

(Test Example 6)
A cutting tool was produced in which the amount of binder phase (vol%) in the cemented carbide layer was changed while the amount of binder phase (vol%) in the cermet layer was constant, and the deformation state after sintering was examined. Here, a cemented carbide layer having a two-layer structure with a uniform thickness and a planar square columnar shape (see FIG. 1 (I)), i.e., without a breaker (thickness h1). : 4.76 mm, the thickness of the cemented carbide layer at the cutting edge h2: 50 μm (h2 / h1 = 0.01)). Except that the amount of the binder phase in both layers was changed, the same raw material powder as in Test Example 1 was used, and the powder for cermet and the powder for cemented carbide were sequentially fed to a mold with a predetermined shape, and then 1.0 t / cm ^The laminated press-formed body produced by pressing in ² was sintered under the same conditions as in Test Example 1 to obtain a cutting tool. The WC was increased or decreased with respect to the increased or decreased binder phase of the cemented carbide layer. Note that the powder feeding sequence may be reversed.

  For the obtained cutting tool, the amount of binder phase (% by volume) in the vicinity of the boundary between the cemented carbide layer and the cermet layer was measured. The amount of the binder phase was measured by observing a cross section of the tool with a microscope (500 times) and performing line analysis with EPMA at a point (25 μm) of the thickness h2 of the cemented carbide layer from the boundary. Moreover, the deformation state of the obtained cutting tool was evaluated. In the deformed state, each sample is placed on a horizontal table so that the cemented carbide layer faces upward, and the entire surface is measured with a height gauge, and the difference between the highest position and the lowest position (warpage of the surface) is measured. Degree) is evaluated as x when the difference is more than 0.1 mm, and ○ when the difference is 0.1 mm or less. These results are shown in Table 13.

  As shown in Table 13, it can be seen that the smaller the difference in the amount of the binder phase between the two layers, the less the movement of the binder phase and the smaller the deformation.

(Test Example 7)
As in Test Example 1, a cutting tip having the same shape was prepared as a base material, and a coated film (PVD film) was formed on the base material in the same manner as in Test Example 4 to produce a coated cutting tool, and cutting was performed. The performance was examined. In this test, the cutting tip used in Test Example 1 is substantially the same as Test Example 1 except that the size of the WC powder used in the cemented carbide layer was changed (Substrate composition: Test Same as Example 1 (Binder phase ratio y1 / y2: 1.0), thickness h1: 4.76 mm, cemented carbide layer thickness h2: 50 μm (h2 / h1 = 0.01), breaker part Cemented carbide layer thickness hb: 100μm (h2 / hb = 0.5), cutting edge treatment width: 0.04mm, Cr ratio of cemented carbide layer: 0.06, total content of W and WC in cermet layer: 36.3 mass% , Co ratio of cermet layer: 88.9% by mass).

  About the obtained cutting tool, the average particle diameter of the cemented carbide layer was investigated. The results are shown in Table 14. In addition, using the obtained coated cutting tool, a cutting test was performed under the cutting conditions shown in Table 6 to examine the wear resistance and toughness (breakage resistance). The results are shown in Table 14. The average particle size was measured in the same manner as in Test Example 1. The evaluation methods for wear resistance and toughness are the same as in Test Example 3.

  As shown in Table 14, it can be seen that a sample having a small average WC particle size of 1.0 μm or less in the cemented carbide layer is excellent in wear resistance. And it turns out that these samples are excellent also in toughness. This is because the fine WC particles in the cemented carbide layer are followed by the crystal grains near the boundary between the PVD film and the base material, and the adhesion between the base material and the PVD film is enhanced, improving toughness. It is thought.

(Test Example 8)
A cutting tool (cutting tip) having the same shape was produced in the same manner as in Test Example 1, and the cutting performance was examined. In this test, the sample used in Test Example 1 was the same as Test Example 1 except that the composition of the cermet layer was changed, and multiple samples with different cemented carbide layer thicknesses were prepared. did.

  The cutting tool was produced as follows. The raw material powder is weighed so as to have the composition shown in Table 15, and a granulated powder having an average particle diameter of 100 μm is prepared in the same manner as in Test Example 1. Using the obtained cemented carbide powder and cermet powder, a laminated press-molded body having a three-layer structure was prepared in the same manner as in Test Example 1, and the obtained molded body was 1480 ° C x 60 min in a vacuum atmosphere. The composite material having a three-layer structure shown in FIG. 2 is obtained by sintering under conditions. In the corner portion of the obtained composite material, the cutting edge treatment (blade edge treatment width: 0.04 mm) was applied in the same manner as in Test Example 1, and the cutting tip with a square column breaker (Sumitomo Electric Industries, Ltd. : SNMG120408N-UX).

  After sintering, for the obtained cutting tool, the structure of the cermet layer was observed by SEM, around the core part (black core) made of TiCN (Ti, W, Mo, Ta, Nb) (C, N) It was the structure | tissue in which the particle | grains with the core structure which have the peripheral part which consists of exist. In addition, in the observation image used for the thickness measurement described later, when the shape of the boundary between the cemented carbide layer and the cermet layer in the tool was examined, the shape was generally along the outer shape (press punch), but partially There are fine irregularities that do not follow the shape of the punch. Moreover, the thickness of the cemented carbide layer in the cutting edge portion is substantially uniform.

  For each of the obtained cutting tools, the maximum thickness h1 in the tool stacking direction was measured in the same manner as in Test Example 1, and all the samples were 4.76 mm. For each cutting tool, the maximum thickness h2 of the cemented carbide layer at the cutting edge portion and the maximum thickness hb of the cemented carbide layer at the breaker portion were measured in the same manner as in Test Example 1. The results are shown in Table 16. Furthermore, when various properties were measured in the same manner as in Test Example 1, the average particle diameter of WC of the cemented carbide layer was 0.9 μm, the binder phase amount of the cemented carbide layer was y1: 16.2% by volume, and the binder phase of the cermet layer. The amount is y2: 16.4% by volume, y1 / y2: 1.0, and the total amount of W and WC in the cermet layer is 32.6% by mass.

  Using the obtained cutting tool, a toughness test and a finishing test (both turned) were performed under the cutting conditions shown in Table 2. The results are shown in Table 16. The test evaluation method is the same as in Test Example 1.

  As shown in Table 16, it can be seen that also in the cutting tool produced in this test example, the sample including the cemented carbide layer is superior in toughness as compared with the sample No. 800 including only cermet. In addition, it can be seen that a thin sample having a cemented carbide layer of the cutting edge portion of 100 μm or less can obtain a good finished surface gloss. In particular, it can be seen that a sample having a cemented carbide layer of the cutting edge portion of 10 μm or more and 50 μm or less is excellent in both toughness and finishing accuracy. Moreover, the sample which provided the cemented carbide layer did not exfoliate the cemented carbide layer.

  The above-described embodiment can be appropriately changed without departing from the gist of the present invention, and is not limited to the above-described configuration. For example, the composition of the cemented carbide layer and the cermet layer, the type of coating film, the film forming method, and the like can be changed.

  The cutting tool of the present invention can be suitably used for cutting work that is desired to be excellent in impact resistance and finished surface gloss. For example, it can be suitably used for finishing.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic cross-sectional explanatory view illustrating a method for measuring the thickness of a cutting tool of the present invention, the thickness of a cemented carbide layer, and the amount of cutting edge treatment, (I) is a two-layer structure tool, and (II) is a three-layer structure. (III) is an enlarged view of the cutting edge portion. It is a schematic cross section which shows an example of this invention cutting tool.

Explanation of symbols

10 Cutting tool (base material) 11 Cemented carbide layer 12 Cermet layer 13 Boundary
14 Mounting hole 100 Cutting tool (base material) 100c Cutting edge part 101 Cemented carbide layer
101f Surface 102 Cermet layer 103 Boundary S Reference plane
200 Ridge line 201 Flank 202 Rake face 203 Intersection

Claims (12)

Comprising a substrate in which a cemented carbide layer and a cermet layer are laminated,
The cemented carbide layer is disposed on at least a part of the rake face side connected to the cutting edge and the cutting edge of the base material,
The base material is h1 when the thickness of the portion with the largest thickness in the laminating direction is h1, and the thickness of the portion with the largest thickness in the laminating direction of the cemented carbide layer existing in the cutting edge portion is h2. Cutting tool characterized by / h1 satisfying 0.002 or more and 0.02 or less.   2. The cutting tool according to claim 1, wherein a thickness h2 of the cemented carbide layer is 10 μm or more and 100 μm or less.   2. The cutting tool according to claim 1, wherein a thickness h2 of the cemented carbide layer is 10 μm or more and 50 μm or less.   The cutting tool according to any one of claims 1 to 3, wherein the cermet layer contains WC and W in a total of 15 mass% or more and 65 mass% or less.   The cemented carbide layer includes a binder phase containing an iron group metal and Cr, and when the amount of the binder phase is x1 (mass%) and the content of Cr is x2 (mass%), x2 The cutting tool according to any one of claims 1 to 4, wherein / x1 satisfies 0.02 or more and 0.2 or less.   The cemented carbide layer and the cermet layer comprise a binder phase containing an iron group metal, the binder phase content of the cemented carbide layer is y1 (volume%), and the binder phase content of the cermet layer is y2 (volume). 6) The cutting tool according to any one of claims 1 to 5, wherein y1 / y2 satisfies 0.8 or more and 1.2 or less. The substrate is
It is a polygonal column-shaped blade tip replaceable tip, and a cutting blade is formed at its corner,
A chip breaker is provided on the rake face connected to the cutting blade, and a cemented carbide layer is present in the breaker part,
The thickness of the cemented carbide layer of the portion most protruding from the rake face in the chip breaker is hb, h2 / hb is 0.5 or more and 1 or less, any one of claims 1 to 6, The cutting tool described in 1.   The cutting according to any one of claims 1 to 7, wherein the cermet layer includes a binder phase containing an iron group metal, and 80 mass% or more of the iron group metal in the binder phase is Co. tool. The cutting tool further comprises a coating film formed on the substrate surface,
The cutting tool according to any one of claims 1 to 8, wherein the coating film is formed by a CVD method. The cutting tool further comprises a coating film formed on the substrate surface,
The cutting tool according to any one of claims 1 to 8, wherein the coating film is formed by a PVD method.   11. The cutting tool according to claim 10, wherein in the base material, an average particle size of hard phase particles in the cemented carbide layer is 0.1 μm or more and 1.0 μm or less.   The cutting tool according to any one of claims 9 to 11, wherein the base material has a blade edge processing portion, and the blade edge processing width is 0.05 mm or less.

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