JP5110376B2 - Surface coated cutting tool - Google Patents

Surface coated cutting tool Download PDF

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JP5110376B2
JP5110376B2 JP2008085898A JP2008085898A JP5110376B2 JP 5110376 B2 JP5110376 B2 JP 5110376B2 JP 2008085898 A JP2008085898 A JP 2008085898A JP 2008085898 A JP2008085898 A JP 2008085898A JP 5110376 B2 JP5110376 B2 JP 5110376B2
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JP2009233821A (en
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亨 長谷川
哲彦 本間
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Mitsubishi Materials Corp
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Description

この発明は、高い発熱を伴うとともに、切刃に対して大きな機械的・衝撃的負荷が作用する鋼や鋳鉄などの高速断続高送り切削加工で、硬質被覆層がすぐれた耐チッピング性を発揮する表面被覆切削工具(以下、被覆工具という)に関するものである。   The present invention exhibits excellent chipping resistance with a hard coating layer in high-speed intermittent high-feed cutting such as steel and cast iron that is accompanied by high heat generation and a large mechanical / impact load on the cutting edge. The present invention relates to a surface-coated cutting tool (hereinafter referred to as a coated tool).

従来、炭化タングステン基(WC基)超硬合金または炭窒化チタン基(TiCN基)サーメットで構成された工具基体の表面に、硬質被覆層として、
(a)下部層として、0.1〜2μmの平均層厚を有する粒状結晶組織のTiC層、TiN層、TiCN層(以下、粒状Ti化合物層という)、
(b)中間層として、0.5〜3μmの平均層厚を有する縦長成長結晶組織のTiCNO層(以下、縦長TiCNO層という)、
(c)上部層として、2〜20μmの平均層厚を有する縦長成長結晶組織のTiCN層(以下、縦長TiCN層という)、
(d)最表面層として、0.2〜15μmの平均層厚を有するAl層、
上記の各層を化学蒸着により形成してなる被覆工具(以下、従来被覆工具という)が知られており、そして、この従来被覆工具は、高速切削ですぐれた耐摩耗性を発揮することが知られている。
Conventionally, as a hard coating layer on the surface of a tool base composed of a tungsten carbide base (WC base) cemented carbide or a titanium carbonitride base (TiCN base) cermet,
(A) As a lower layer, a TiC layer having a mean grain thickness of 0.1 to 2 μm, a TiN layer, a TiN layer, a TiCN layer (hereinafter referred to as a granular Ti compound layer),
(B) As an intermediate layer, a vertically grown TiCNO layer having an average layer thickness of 0.5 to 3 μm (hereinafter referred to as a vertically elongated TiCNO layer),
(C) As an upper layer, a TiCN layer having a vertically grown crystal structure having an average layer thickness of 2 to 20 μm (hereinafter referred to as a vertically elongated TiCN layer),
(D) As an outermost surface layer, an Al 2 O 3 layer having an average layer thickness of 0.2 to 15 μm,
A coated tool formed by chemical vapor deposition of each of the above layers (hereinafter referred to as a conventional coated tool) is known, and this conventional coated tool is known to exhibit excellent wear resistance at high speed cutting. ing.

なお、上記従来被覆工具における中間層(縦長TiCN層)は、例えば、通常の化学蒸着装置にて、反応ガスとして有機炭窒化物を含む混合ガスを使用し、700〜950℃の中温温度域で化学蒸着することにより形成することができ、そしてこれがすぐれた高温強度を有することも知られている。
特開平11−172464号公報 特開平6−8010号公報
The intermediate layer (longitudinal TiCN layer) in the conventional coated tool is, for example, a normal chemical vapor deposition apparatus, using a mixed gas containing organic carbonitride as a reaction gas, and at a medium temperature range of 700 to 950 ° C. It can also be formed by chemical vapor deposition and it is also known to have excellent high temperature strength.
JP-A-11-172464 Japanese Patent Laid-Open No. 6-8010

近年の切削装置の高性能化はめざましく、一方で切削加工に対する省力化、省エネ化、高効率化、低コスト化の要求は強く、これに伴い、切削加工は一段と過酷な条件下で行われる傾向にあり、被覆工具の長寿命化を図るため、最表面のAl層を厚膜化する試みもなされているが、上記従来被覆工具は、これを鋼や鋳鉄などの高速連続切削や高速断続切削に用いた場合には、耐摩耗性について特段の問題は生じないが、特にこれを高い発熱を伴うとともに切刃に対して大きな機械的・衝撃的負荷が作用する高速断続高送り切削加工に用いた場合には、硬質被覆層の高温強度が十分でないため、切削加工時に切刃に対して大きな機械的・衝撃的負荷によりチッピングが発生しやすく、その結果、比較的短時間で使用寿命に至るのが現状である。 In recent years, the performance of cutting machines has been remarkable, while demands for labor saving, energy saving, high efficiency, and low cost for cutting are strong, and accordingly, cutting tends to be performed under more severe conditions. In order to extend the life of the coated tool, an attempt has been made to increase the thickness of the outermost Al 2 O 3 layer. However, the above-mentioned conventional coated tool is applied to high-speed continuous cutting such as steel and cast iron. When used for high-speed interrupted cutting, there is no particular problem with wear resistance, but it is particularly accompanied by high heat generation and high-speed interrupted high-feed cutting with a large mechanical and impact load acting on the cutting edge. When used for processing, the high temperature strength of the hard coating layer is not sufficient, so chipping is likely to occur due to a large mechanical / impact load on the cutting edge during cutting, and as a result, it can be used in a relatively short time. It is the current state that reaches life A.

そこで、本発明者等は、上述のような観点から、硬質被覆層の耐チッピング性の向上をはかるべく、硬質被覆層の構成層であるTi化合物層、特に、上記従来被覆工具の中間層である縦長TiCNO層に着目し、研究を行った結果、以下のような知見を得た。   In view of the above, the present inventors, in order to improve the chipping resistance of the hard coating layer, in the Ti compound layer that is a constituent layer of the hard coating layer, in particular, the intermediate layer of the conventional coating tool. As a result of conducting research by paying attention to a certain longitudinal TiCNO layer, the following knowledge was obtained.

(a)上記従来被覆工具の硬質被覆層の下部層(粒状Ti化合物層)と上部層(縦長TiCN層)の間に介在形成された中間層(縦長TiCNO層)は、化学蒸着によって微細結晶組織を有する層として形成され、この上に更に縦長TiCN層を形成した場合に、縦長TiCN層の結晶微細化を促進するという作用を有しており、その結果、すぐれた靭性を有する縦長TiCN層からなる上部層が形成されて被覆工具の特性改善が図られていたが、縦長TiCNO層からなる中間層にかえて、硬質被覆層の下部層(粒状Ti化合物層)と上部層(縦長TiCN層)の間に粒状結晶組織を有するCrCNO層(以下、粒状CrCNO層という)を中間層として化学蒸着で形成すると、粒状CrCNO層からなる中間層は、縦長TiCNO層に比して、すぐれた高温強度を備えるため耐チッピング性向上に有効であるが、その反面、高温硬さの低下がみられ、耐摩耗性が不十分となるため、中間層を粒状CrCNO層の単層ではなく、粒状CrCNO層と粒状結晶組織を有するTiCNO層(以下、粒状TiCNO層という)との複層として構成したところ、中間層は、高温硬さの低下もなくすぐれた高温強度を有し、その結果、粒状TiCNO層と粒状CrCNO層の複層からなる中間層を備えた被覆工具は、大きな発熱を伴い、かつ、切刃に対して大きな機械的・衝撃的負荷が作用する高速断続高送り切削加工に用いた場合にも、すぐれた耐チッピング性を示すこと。 (A) The intermediate layer (longitudinal TiCNO layer) formed between the lower layer (granular Ti compound layer) and the upper layer (vertical TiCN layer) of the hard coating layer of the conventional coated tool has a fine crystal structure by chemical vapor deposition. When a vertical TiCN layer is further formed thereon, it has the effect of promoting crystal refinement of the vertical TiCN layer, and as a result, from the vertical TiCN layer having excellent toughness. The upper layer was formed to improve the characteristics of the coated tool, but instead of the intermediate layer consisting of the vertically long TiCNO layer, the lower layer (granular Ti compound layer) and the upper layer (longitudinal TiCN layer) of the hard coating layer When a CrCNO layer having a granular crystal structure (hereinafter referred to as a granular CrCNO layer) is formed by chemical vapor deposition as an intermediate layer, the intermediate layer composed of the granular CrCNO layer is compared with a vertically long TiCNO layer. In addition, since it has excellent high-temperature strength, it is effective in improving chipping resistance, but on the other hand, a decrease in high-temperature hardness is observed and wear resistance is insufficient, so that the intermediate layer is a single layer of a granular CrCNO layer. Rather, when constituted as a multilayer of a granular CrCNO layer and a TiCNO layer having a granular crystal structure (hereinafter referred to as granular TiCNO layer), the intermediate layer has excellent high temperature strength without a decrease in high temperature hardness, As a result, coated tools equipped with an intermediate layer consisting of multiple layers of granular TiCNO layer and granular CrCNO layer are accompanied by large heat generation, and high speed intermittent high feed with large mechanical and impact loads acting on the cutting edge. Excellent chipping resistance when used for cutting.

(b)また、例えば、上記従来被覆工具において、耐摩耗性向上、長寿命化のためにAl層からなる最表面層の厚膜化を図った場合、化学蒸着装置内に配置された工具基体は長時間高温に曝されるため、工具基体を構成する成分元素の拡散が生じやすく、特に、高温強度、耐熱塑性変形性等を向上させるためにCr酸化物、Cr炭化物等のCr成分を含有するWC基超硬合金の場合には、工具基体表面に蒸着形成された下部層(粒状Ti化合物層)へのCrの拡散が生じ、しかも、下部層(粒状Ti化合物層)にはCrの拡散を抑制する機能がないため、上部層である縦長TiCN層にまでCrが拡散し、その結果、縦長TiCN層において高温硬さの低下が生じ、また同時に、工具基体中のCr量が基体表面で減少し、そして、工具基体に形成されたこの低Cr領域は耐熱塑性変形性に劣るため、被覆工具には偏摩耗等が生じやすくなり、耐摩耗性が大幅に低下するため、Al層の厚膜化を行ったとしても、被覆工具の耐摩耗性向上、長寿命化を達成することは非常に困難である。
しかし、粒状Ti化合物層からなる下部層と、縦長TiCN層からなる上部層との間に、粒状TiCNO層と粒状CrCNO層の複層とからなる中間層を化学蒸着で介在形成すると、粒状CrCNO層はCrの拡散抑制作用を有しているため、化学蒸着時に工具基体が高温で長時間曝されたとしても、工具基体からのCr成分の拡散を抑え、したがって、Cr成分が上部層の縦長TiCN層へ拡散することが防止され、その結果として、縦長TiCN層の硬度低下が抑えられ、同時に、工具基体からCrが拡散することによって生じていた工具基体表面近傍の低Cr領域の形成も防止されるため、工具基体自体の耐熱塑性変形性の低下も防止されること。
(B) For example, in the conventional coated tool, when the outermost surface layer composed of the Al 2 O 3 layer is increased in order to improve wear resistance and extend the life, it is disposed in the chemical vapor deposition apparatus. Since the tool base is exposed to a high temperature for a long time, diffusion of component elements constituting the tool base is likely to occur. In particular, Cr oxide such as Cr oxide and Cr carbide is used to improve high-temperature strength, heat-resistant plastic deformation and the like. In the case of a WC-based cemented carbide containing components, Cr diffuses to the lower layer (granular Ti compound layer) deposited on the surface of the tool base, and the lower layer (granular Ti compound layer) Since there is no function to suppress the diffusion of Cr, Cr diffuses to the vertical TiCN layer, which is the upper layer. As a result, the high-temperature hardness is reduced in the vertical TiCN layer, and at the same time, the amount of Cr in the tool base is reduced. Reduced at the substrate surface and Since this low-Cr region formed in the substrate inferior in heat plastic deformation resistance, such uneven wear is liable to occur in the coated tool, since the wear resistance is greatly reduced, the thickening of the Al 2 O 3 layer Even if it is done, it is very difficult to achieve improved wear resistance and long life of the coated tool.
However, when an intermediate layer composed of a granular TiCNO layer and a granular CrCNO layer is interposed between the lower layer composed of the granular Ti compound layer and the upper layer composed of the vertically long TiCN layer by chemical vapor deposition, the granular CrCNO layer Has the effect of suppressing the diffusion of Cr, so even if the tool base is exposed to a high temperature for a long time during chemical vapor deposition, it suppresses the diffusion of the Cr component from the tool base. Therefore, the Cr component is a vertically long TiCN in the upper layer. As a result, the decrease in hardness of the longitudinal TiCN layer is suppressed, and at the same time, the formation of a low Cr region in the vicinity of the tool base surface caused by the diffusion of Cr from the tool base is also prevented. Therefore, the deterioration of the heat-resistant plastic deformability of the tool base itself is also prevented.

(c)さらに、粒状Ti化合物層(下部層)の上に粒状TiCNO層と粒状CrCNO層の複層(中間層)を蒸着し、さらに、この上に縦長TiCN層(上部層)を蒸着形成すると、縦長TiCNO層の場合と同様に、粒状TiCNO層と粒状CrCNO層の複層からなる中間層は、縦長TiCN層(上部層)の結晶微細化を促進するという作用を有しているため、微細結晶の縦長TiCN層が上部層として形成され、その結果、該縦長TiCN層(上部層)はすぐれた靭性を備えるようになること。 (C) Furthermore, a multilayer (intermediate layer) of a granular TiCNO layer and a granular CrCNO layer is vapor-deposited on the granular Ti compound layer (lower layer), and further, a vertically long TiCN layer (upper layer) is vapor-deposited thereon. As in the case of the vertically long TiCNO layer, the intermediate layer composed of a plurality of layers of the granular TiCNO layer and the granular CrCNO layer has an effect of promoting crystal refinement of the vertically long TiCN layer (upper layer). A vertically long TiCN layer of crystal is formed as an upper layer, and as a result, the vertically long TiCN layer (upper layer) has excellent toughness.

(d)したがって、炭化タングステン基超硬合金または炭窒化チタン基サーメットで構成された工具基体の表面に、粒状Ti化合物層からなる下部層、粒状TiCNO層と粒状CrCNO層の複層からなる中間層、縦長TiCN層からなる上部層、さらに、Al層からなる最表面層を硬質被覆層として蒸着形成した被覆工具は、たとえ、高温で長時間曝されたとしても、工具基体からの上部層側へのCrの拡散が抑制され、そのため、工具基体表面近傍の低Cr領域の形成による耐熱塑性変形性の低下が防止され、また、縦長TiCN層(上部層)の硬度低下も防止され、さらに、粒状TiCNO層と粒状CrCNO層の複層からなる中間層がすぐれた高温強度と高温硬さを有することから、高い発熱を伴うとともに切刃に対して大きな機械的・衝撃的負荷がかかる鋼や鋳鉄などの高速断続高送り切削加工に用いた場合であっても、すぐれた耐熱塑性変形性とともにすぐれた耐チッピング性を示し、また、長期にわたってすぐれた耐摩耗性を発揮するようになること。 (D) Therefore, a lower layer composed of a granular Ti compound layer, an intermediate layer composed of a multilayer of a granular TiCNO layer and a granular CrCNO layer on the surface of a tool base composed of tungsten carbide-based cemented carbide or titanium carbonitride-based cermet The upper layer composed of a vertically long TiCN layer, and the outermost surface layer composed of an Al 2 O 3 layer deposited as a hard coating layer, even if the coated tool is exposed to a high temperature for a long time, The diffusion of Cr to the layer side is suppressed, so that a reduction in heat-resistant plastic deformation due to the formation of a low Cr region in the vicinity of the tool base surface is prevented, and a decrease in the hardness of the vertically long TiCN layer (upper layer) is also prevented, Furthermore, since the intermediate layer composed of a multilayer of a granular TiCNO layer and a granular CrCNO layer has excellent high-temperature strength and high-temperature hardness, it is accompanied by high heat generation and large against the cutting edge. Even when used for high-speed intermittent high-feed cutting such as steel and cast iron that are subjected to heavy mechanical and impact loads, it exhibits excellent heat-resistant plastic deformation and excellent chipping resistance, and excellent over a long period of time. The wear resistance must be demonstrated.

この発明は、上記の研究結果に基づいてなされたものであって、
「(1) 炭化タングステン基超硬合金または炭窒化チタン基サーメットで構成された工具基体の表面に、
(a)下部層が、0.1〜2μmの合計平均層厚を有する化学蒸着で形成された、粒状結晶組織のTiの炭化物層(粒状TiC層)、窒化物層(粒状TiN層)、炭窒化物層(粒状TiCN層)のうちの少なくとも1層、
(b)中間層が、0.5〜3μmの合計平均層厚を有する、化学蒸着で形成された粒状結晶組織のTiの炭窒酸化物層(粒状TiCNO層)と、同じく化学蒸着で形成された粒状結晶組織のCrの炭窒酸化物層の積層(粒状CrCNO層)、
(c)上部層が、2〜20μmの平均層厚を有する化学蒸着で形成された、縦長成長結晶組織のTiの炭窒化物層(縦長TiCN層)、
(d)最表面層が、0.2〜15μmの平均層厚を有する化学蒸着で形成された酸化アルミニウム層(Al層)、
以上(a)〜(d)で構成された硬質被覆層を形成してなる表面被覆切削工具(被覆工具)。
(2) 前記(1)記載の表面被覆切削工具(被覆工具)において、
上記(c)の縦長成長結晶組織のTiの炭窒化物層(縦長TiCN層)と、上記(d)の酸化アルミニウム層(Al層)との間に、0.1〜3μmの平均層厚を有する化学蒸着で形成された粒状結晶組織のTiの炭化物層(粒状TiC層)、窒化物層(粒状TiN層)、炭窒化物層(粒状TiCN層)、炭酸化物層(粒状TiCO層)、炭窒酸化物層(粒状TiCNO層)のうちの少なくとも1層からなる密着層を介在してなる前記(1)記載の表面被覆切削工具(被覆工具)。」
に特徴を有するものである。
This invention was made based on the above research results,
“(1) On the surface of a tool base made of tungsten carbide-based cemented carbide or titanium carbonitride-based cermet,
(A) Ti carbide layer (granular TiC layer), nitride layer (granular TiN layer), charcoal of granular crystal structure formed by chemical vapor deposition in which the lower layer has a total average layer thickness of 0.1 to 2 μm At least one of the nitride layers (granular TiCN layers);
(B) The intermediate layer has a total average layer thickness of 0.5 to 3 μm and is formed by chemical vapor deposition, as well as a Ti carbonitride oxide layer (granular TiCNO layer) having a granular crystal structure formed by chemical vapor deposition. A layer of Cr carbonitride oxide layer (granular CrCNO layer) with a granular crystal structure,
(C) Ti carbonitride layer (longitudinal TiCN layer) having a vertically grown crystal structure, wherein the upper layer is formed by chemical vapor deposition having an average layer thickness of 2 to 20 μm,
(D) an aluminum oxide layer (Al 2 O 3 layer) formed by chemical vapor deposition in which the outermost surface layer has an average layer thickness of 0.2 to 15 μm;
A surface-coated cutting tool (coated tool) formed by forming a hard coating layer composed of (a) to (d) above.
(2) In the surface-coated cutting tool (coated tool) described in (1) above,
An average of 0.1 to 3 μm between the Ti carbonitride layer (longitudinal TiCN layer) having the vertically elongated crystal structure (c) and the aluminum oxide layer (Al 2 O 3 layer) (d). Ti carbide layer (granular TiC layer), nitride layer (granular TiN layer), carbonitride layer (granular TiCN layer), carbonate layer (granular TiCO layer) of granular crystal structure formed by chemical vapor deposition having a layer thickness ), A surface-coated cutting tool (coated tool) according to (1) above, wherein an adhesion layer comprising at least one of a carbonitride oxide layer (a granular TiCNO layer) is interposed. "
It has the characteristics.

つぎに、この発明の被覆工具について、詳細に説明する。
(a)工具基体
工具基体としては、従来から汎用されているWC基超硬合金、TiCN基サーメットを用いることができる。特に、工具基体としてWC基超硬合金を用いた場合、通常、WC基超硬合金は硬質相成分と結合相成分からなり、硬質相の主要構成成分としてはWCを含有し、これに加えてさらに、周期律表の4a、5a、6a族の金属炭化物、窒化物、炭窒化物を含有し、また、結合相の主要構成成分としては、鉄族金属元素の少なくとも1種、特にCo、を含有し、これらの構成成分からなるWC基超硬合金は硬質材料であってすぐれた耐摩耗性を有するが、Crの炭化物、窒化物、炭窒化物が含有されている場合には、工具基体表面へ硬質被覆層を蒸着形成する際、特に、厚膜Al層を形成するような場合、長時間高温に曝されるため、Crが硬質被覆層中へ拡散し、工具基体の表面近傍には低Cr領域が形成され、工具基体の耐熱塑性変形性が低下して偏摩耗を生じやすくなり、結果として被覆工具の耐摩耗性が劣化し、一方、硬質被覆層中に拡散Crが含有されることにより、硬質被覆層の高温強度は増大するが、その反面、特に、縦長TiCN層の高温硬さが低下し、これも被覆工具の耐摩耗性低下の原因となる。
しかし、この発明では、硬質被覆層の中間層として、それ自体高温強度にすぐれ、さらに、Crの拡散抑制作用を有する粒状CrCNO層と、粒状CrCNO層による高温硬さの低下を補完する目的で粒状TiCNO層を複層として蒸着形成したことによって、WC基超硬合金からなる工具基体の構成成分としてCr成分を含有する工具基体であっても、これを高温下で長時間曝したとしても、特にCrの拡散防止が図られることにより、被覆工具の耐熱塑性変形性の低下が防止されるとともに、耐摩耗性の維持向上が図られる。
Next, the coated tool of the present invention will be described in detail.
(A) Tool substrate As the tool substrate, a conventionally used WC-based cemented carbide or TiCN-based cermet can be used. In particular, when a WC-based cemented carbide is used as the tool base, the WC-based cemented carbide is usually composed of a hard phase component and a binder phase component, and WC is contained as a main component of the hard phase. Furthermore, it contains 4a, 5a, 6a group metal carbides, nitrides, carbonitrides of the periodic table, and the main component of the binder phase is at least one iron group metal element, especially Co. WC-based cemented carbide containing these constituents is a hard material and has excellent wear resistance. However, when Cr carbide, nitride, carbonitride is contained, a tool substrate When vapor-depositing a hard coating layer on the surface, especially when a thick Al 2 O 3 layer is formed, Cr is diffused into the hard coating layer and exposed to a high temperature for a long time. A low Cr region is formed in the vicinity, and the heat-resistant plastic deformation of the tool base However, the wear resistance of the coated tool is deteriorated as a result, while the diffusion of Cr in the hard coating layer increases the high-temperature strength of the hard coating layer. On the other hand, in particular, the high-temperature hardness of the vertically long TiCN layer decreases, which also causes a decrease in the wear resistance of the coated tool.
However, in the present invention, the intermediate layer of the hard coating layer is itself excellent in high-temperature strength, and further has a granular CrCNO layer having an effect of suppressing Cr diffusion and a granular for the purpose of complementing the decrease in high-temperature hardness due to the granular CrCNO layer. Even if a tool base containing a Cr component as a constituent component of a tool base made of a WC-based cemented carbide is formed by vapor deposition as a TiCNO layer as a multilayer, even if this is exposed to a high temperature for a long time, By preventing the diffusion of Cr, it is possible to prevent a decrease in the heat-resistant plastic deformability of the coated tool and to maintain and improve the wear resistance.

(b)下部層(粒状TiC層、粒状TiN層、粒状TiCN層)
粒状TiC層、粒状TiN層、粒状TiCN層からなる下部層は、それ自体が高温強度を有し、これの存在によって硬質被覆層が高温強度を具備するようになるほか、工具基体と中間層である粒状CrCNO層、粒状TiCNO層のいずれにも強固に密着し、よって硬質被覆層の工具基体に対する密着性向上に寄与する作用をもつが、その合計平均層厚が0.1μm未満では、前記作用を十分に発揮させることができず、一方その合計平均層厚が2μmを越えると、特に高速断続高送り切削ではチッピングを起し易くなることから、その合計平均層厚を0.1〜2μmと定めた。
(B) Lower layer (granular TiC layer, granular TiN layer, granular TiCN layer)
The lower layer composed of the granular TiC layer, the granular TiN layer, and the granular TiCN layer itself has a high temperature strength, and the presence of the lower layer makes the hard coating layer have a high temperature strength. It adheres firmly to both the granular CrCNO layer and the granular TiCNO layer, and thus contributes to improving the adhesion of the hard coating layer to the tool substrate, but if the total average layer thickness is less than 0.1 μm, On the other hand, if the total average layer thickness exceeds 2 μm, chipping is likely to occur particularly in high-speed intermittent high-feed cutting, so the total average layer thickness is 0.1 to 2 μm. Determined.

(c)中間層(粒状TiCNO層と粒状CrCNO層の複層)
通常の化学蒸着装置にて、
反応ガス組成:容量%で、CrCl:1〜8%、CO:0.3〜3%、N:10〜40%、H2:残り、
反応雰囲気温度: 900〜1020 ℃、
反応雰囲気圧力: 6 〜20 kPa、
の条件で化学蒸着を行うと、粒状結晶構造のCrCNO層を蒸着形成できるが、この粒状CrCNO層は、縦長TiCNO層に比して、すぐれた高温強度を有し、また、Crの拡散抑制機能を有するため、硬質被覆層の化学蒸着時に、Cr成分が工具基体から硬質被覆層側へと拡散し、工具基体の表面近傍に低クロム領域が形成されることによる耐熱塑性変形性の低下を防止すると同時に、上部層である縦長TiCN層中へCrが拡散し、含有されることによる縦長TiCN層の硬度低下を防止し、その結果として、被覆工具の偏摩耗の発生を防ぎ、もって、高い発熱を伴う鋼や鋳鉄などの高速断続高送り切削加工における被覆工具の耐摩耗性向上、長寿命化に寄与する。さらに、粒状CrCNO層は、縦長TiCN層を蒸着形成する際に、縦長TiCN層の結晶微細化を促進するという作用も有しているため、微細結晶の縦長TiCN層が上部層として形成され、その結果、該縦長TiCN層(上部層)は高速断続高送り切削加工においてすぐれた靭性を発揮するようになる。
一方、中間層として粒状CrCNO層のみを設けた場合には、中間層の高温硬さが十分でなく耐摩耗性が低下する恐れがあるので、高温硬さの低下を補完するために、粒状結晶構造のTiCNO層を蒸着形成し、中間層を粒状TiCNO層と粒状CrCNO層の複層構造として構成する。
粒状TiCNO層は、通常の化学蒸着装置にて、
反応ガス組成:容量%で、TiCl:2〜5%、CO:0.5〜3%、CH:1〜10%、N:10〜25%、H2:残り、
反応雰囲気温度:980〜1020 ℃、
反応雰囲気圧力:5〜10 kPa、
の条件で化学蒸着を行うことによって形成することができる。
粒状TiCNO層と粒状CrCNO層との複層からなる中間層の合計平均層厚については、その平均層厚が0.5μm未満では、Crの拡散抑制効果が十分に機能せず、高温強度向上効果も少なく、また、その合計平均層厚が3μmを超えると、チッピングを発生する恐れがあるので、粒状TiCNO層と粒状CrCNO層との複層からなる中間層の合計平均層厚は0.5〜3μmと定めた。
(C) Intermediate layer (multilayer of granular TiCNO layer and granular CrCNO layer)
With normal chemical vapor deposition equipment,
Reaction gas composition:% by volume, CrCl 3 : 1 to 8%, CO: 0.3 to 3 %, N 2 : 10 to 40%, H 2 : remaining,
Reaction atmosphere temperature: 900 to 1020 ° C.
Reaction atmosphere pressure: 6 to 20 kPa,
When the chemical vapor deposition is carried out under the above conditions, a CrCNO layer having a granular crystal structure can be formed by vapor deposition. However, this granular CrCNO layer has superior high-temperature strength as compared with a vertically long TiCNO layer, and also has a Cr diffusion suppression function. Therefore, during chemical vapor deposition of the hard coating layer, the Cr component diffuses from the tool base to the hard coating layer side, preventing the deterioration of heat-resistant plastic deformation due to the formation of a low chromium region near the surface of the tool base. At the same time, Cr diffuses into the longitudinal TiCN layer, which is the upper layer, and prevents the hardness of the longitudinal TiCN layer from being reduced, and as a result, prevents the uneven wear of the coated tool, resulting in high heat generation. This contributes to improved wear resistance and longer life of coated tools in high-speed intermittent high-feed cutting such as steel and cast iron. Furthermore, since the granular CrCNO layer also has an effect of promoting the crystal refinement of the vertical TiCN layer when the vertical TiCN layer is formed by vapor deposition, the fine vertical crystal TiCN layer is formed as an upper layer. As a result, the vertically long TiCN layer (upper layer) exhibits excellent toughness in high-speed intermittent high-feed cutting.
On the other hand, when only the granular CrCNO layer is provided as the intermediate layer, the intermediate layer has insufficient high-temperature hardness and may have reduced wear resistance. Therefore, in order to supplement the decrease in high-temperature hardness, A TiCNO layer having a structure is formed by vapor deposition, and the intermediate layer is configured as a multilayer structure of a granular TiCNO layer and a granular CrCNO layer.
The granular TiCNO layer is a normal chemical vapor deposition device.
Reaction gas composition: volume%, TiCl 4 : 2 to 5%, CO: 0.5 to 3%, CH 4 : 1 to 10%, N 2 : 10 to 25%, H 2 : remaining,
Reaction atmosphere temperature: 980 to 1020 ° C.
Reaction atmosphere pressure: 5 to 10 kPa,
It can form by performing chemical vapor deposition on the conditions of.
Regarding the total average layer thickness of the intermediate layer composed of a multilayer of a granular TiCNO layer and a granular CrCNO layer, if the average layer thickness is less than 0.5 μm, the Cr diffusion suppression effect does not function sufficiently, and the high temperature strength improvement effect If the total average layer thickness exceeds 3 μm, chipping may occur. Therefore, the total average layer thickness of the intermediate layer composed of a multilayer of the granular TiCNO layer and the granular CrCNO layer is 0.5 to It was determined to be 3 μm.

(d)上部層(縦長TiCN層)
上部層としての、縦長TiCN層は、例えば、通常の化学蒸着装置にて、
反応ガス組成:容量%で、TiCl:2〜10%、CHCN:0.5〜3%、N:10〜30%、H2:残り、
反応雰囲気温度:800〜900℃、
反応雰囲気圧力:6〜20kPa、
の条件で蒸着形成されるが、粒状TiCNO層と粒状CrCNO層との複層からなる中間層上に形成されることによって、微細結晶かつ縦長成長結晶組織を有する縦長TiCN層として形成され、さらに、工具基体からのCr成分の拡散も防止されるため、その靭性に優れるばかりか、粒状TiCN層に比して、一段とすぐれた高温強度を具備し、高速断続高送り切削加工において、耐チッピング性を一段と向上させる。
そして、上記縦長TiCN層の平均層厚が2μm未満では、靭性向上、高温強度向上効果を十分に発揮することができず、また、平均層厚が20μmを超えるとチッピングを発生しやすくなることから、縦長TiCN層の平均層厚を2〜20μmと定めた。
(D) Upper layer (vertical TiCN layer)
The vertical TiCN layer as the upper layer is, for example, a normal chemical vapor deposition apparatus,
Reaction gas composition: by volume%, TiCl 4: 2~10%, CH 3 CN: 0.5~3%, N 2: 10~30%, H 2: remainder,
Reaction atmosphere temperature: 800 to 900 ° C.
Reaction atmosphere pressure: 6-20 kPa,
However, it is formed as a vertically elongated TiCN layer having a fine crystal and a vertically elongated crystal structure by being formed on an intermediate layer composed of a multilayer of a granular TiCNO layer and a granular CrCNO layer. Since the diffusion of Cr component from the tool base is also prevented, not only is it excellent in toughness, but also has a higher high-temperature strength than the granular TiCN layer, and has high chipping resistance in high-speed intermittent high-feed cutting. Further improve.
And, if the average layer thickness of the longitudinal TiCN layer is less than 2 μm, the effect of improving toughness and high temperature strength cannot be sufficiently exerted, and if the average layer thickness exceeds 20 μm, chipping tends to occur. The average layer thickness of the vertically long TiCN layer was determined to be 2 to 20 μm.

(e)密着層(粒状Ti化合物層)
上部層である上記l−TiCN層と、最表面層であるAl層の間に、粒状結晶組織のTi化合物層(例えば、粒状結晶組織のTiC層、TiN層、TiCN層、TiCO層、TiCNO層)を0.1〜3μmの合計層厚で蒸着形成し、密着層として介在させると、上記l−TiCN層と、最表面層であるAl層の密着性が向上するようになり、この結果、被覆工具は、高熱発生を伴い、かつ、切刃に対して大きな機械的・衝撃的負荷が作用する鋼や鋳鉄などの高速断続高送り切削加工においても、硬質被覆層の層間剥離の発生およびチッピングの発生がなく、すぐれた切削性能を長期に亘って発揮する。
(E) Adhesion layer (granular Ti compound layer)
Between the l-TiCN layer as the upper layer and the Al 2 O 3 layer as the outermost layer, a Ti compound layer having a granular crystal structure (eg, a TiC layer, TiN layer, TiCN layer, TiCO layer having a granular crystal structure) , TiCNO layer) is deposited with a total layer thickness of 0.1 to 3 μm and interposed as an adhesion layer, the adhesion between the l-TiCN layer and the Al 2 O 3 layer as the outermost surface layer is improved. As a result, the coated tool has a hard coating layer even in high-speed intermittent high-feed cutting such as steel or cast iron, which is accompanied by high heat generation and a large mechanical / impact load on the cutting edge. Delamination and chipping do not occur, and excellent cutting performance is demonstrated over a long period of time.

(f)最表面層(Al層)
Al層からなる上部層は、すぐれた高温硬さと耐熱性を有し、硬質被覆層の耐摩耗性向上に寄与するが、その平均層厚が0.2μm未満では、硬質被覆層に十分な耐摩耗性を発揮せしめることができず、一方その平均層厚が15μmを越えて厚くなりすぎると、チッピングが発生し易くなることから、その平均層厚を0.2〜15μmと定めた。
(F) Outermost surface layer (Al 2 O 3 layer)
The upper layer composed of the Al 2 O 3 layer has excellent high-temperature hardness and heat resistance and contributes to improving the wear resistance of the hard coating layer. However, if the average layer thickness is less than 0.2 μm, Sufficient wear resistance cannot be exhibited. On the other hand, if the average layer thickness exceeds 15 μm, chipping tends to occur. Therefore, the average layer thickness is set to 0.2 to 15 μm. .

なお、切削工具の使用前後の識別を目的として、黄金色の色調を有するTiN層を、必要に応じて蒸着形成してもよいが、この場合の平均層厚は0.1〜1μmでよい。これは0.1μm未満では、十分な識別効果が得られず、一方前記TiN層による前記識別効果は1μmまでの平均層厚で十分であるという理由からである。   A TiN layer having a golden color tone may be vapor-deposited as necessary for the purpose of identifying the cutting tool before and after use, but the average layer thickness in this case may be 0.1 to 1 μm. This is because if the thickness is less than 0.1 μm, a sufficient discrimination effect cannot be obtained, while the discrimination effect by the TiN layer is sufficient with an average layer thickness of up to 1 μm.

この発明の被覆工具は、硬質被覆層の中間層として形成した粒状TiCNO層と粒状CrCNO層との複層が、すぐれた高温強度と高温硬さを有するとともに、縦長TiCN層の靭性、高温強度を向上させ、さらに、工具基体表面近傍に低Cr領域が形成されることを防止し、拡散により縦長TiCN層中にCrが拡散・含有されることを防止し、もって、高い発熱を伴い切刃に対して大きな機械的・衝撃的負荷がかかる鋼や鋳鉄などの高速断続高送り切削加工に用いた場合でも、被覆工具のすぐれた耐チッピング性、耐摩耗性が長期の使用に亘って確保されるものである。   In the coated tool of the present invention, a multilayer of a granular TiCNO layer and a granular CrCNO layer formed as an intermediate layer of a hard coating layer has excellent high-temperature strength and high-temperature hardness, as well as the toughness and high-temperature strength of a vertically long TiCN layer. Furthermore, it prevents the formation of a low Cr region in the vicinity of the tool base surface, prevents the diffusion and inclusion of Cr in the vertically long TiCN layer due to diffusion, and thus causes the cutting blade with high heat generation. Even when used for high-speed intermittent high-feed cutting such as steel and cast iron that are subject to large mechanical and impact loads, excellent chipping resistance and wear resistance of the coated tool are ensured over a long period of use. Is.

つぎに、この発明の被覆工具を実施例により具体的に説明する。   Next, the coated tool of the present invention will be specifically described with reference to examples.

原料粉末として、いずれも1〜3μmの平均粒径を有するWC粉末、TiC粉末、ZrC粉末、VC粉末、TaC粉末、NbC粉末、Cr32粉末、TiN粉末、TaN粉末、およびCo粉末を用意し、これら原料粉末を、表1に示される配合組成に配合し、さらにワックスを加えてアセトン中で24時間ボールミル混合し、減圧乾燥した後、98MPaの圧力で所定形状の圧粉体にプレス成形し、この圧粉体を5Paの真空中、1370〜1470℃の範囲内の所定の温度に1時間保持の条件で真空焼結し、焼結後、切刃部にR:0.07mmのホーニング加工を施すことによりISO・CNMG120408に規定するインサート形状をもったWC基超硬合金製の工具基体A〜Fをそれぞれ製造した。 WC powder, TiC powder, ZrC powder, VC powder, TaC powder, NbC powder, Cr 3 C 2 powder, TiN powder, TaN powder, and Co powder all having an average particle diameter of 1 to 3 μm are prepared as raw material powders. These raw material powders were blended into the composition shown in Table 1, added with wax, ball milled in acetone for 24 hours, dried under reduced pressure, and pressed into a green compact with a predetermined shape at a pressure of 98 MPa. The green compact was vacuum sintered at a predetermined temperature in the range of 1370 to 1470 ° C. for 1 hour in a vacuum of 5 Pa. After sintering, the cutting edge portion was R: 0.07 mm honing By performing the processing, tool bases A to F made of WC-based cemented carbide having an insert shape specified in ISO · CNMG120408 were manufactured.

つぎに、これらの工具基体A〜Fの表面に、通常の化学蒸着装置を用い、硬質被覆層の下部層として、粒状TiC層、粒状TiN層、粒状TiCN層のうちの少なくとも1層を表2に示される条件、かつ、表3に示される組み合わせ、目標層厚で蒸着形成し、
ついで、中間層としての粒状TiCNO層および粒状CrCNO層を、それぞれ表2に示される条件にて、表3に示される目標層厚で複層を形成すべく蒸着形成し、
ついで、上部層としての縦長TiCN層を、表2に示される条件にて、表3に示される目標層厚で蒸着形成し、
ついで、密着層としての粒状Ti化合物層を、表2に示される条件にて、表3に示される組み合わせ、目標層厚で蒸着形成し、
さらに、最表面層としてのAl層を、表2に示される条件にて、表3に示される目標層厚で蒸着形成して本発明被覆工具1〜13をそれぞれ製造した。
Next, at least one of a granular TiC layer, a granular TiN layer, and a granular TiCN layer is formed on the surface of these tool bases A to F as a lower layer of the hard coating layer using a normal chemical vapor deposition apparatus. And the combination shown in Table 3 with the target layer thickness,
Next, a granular TiCNO layer and a granular CrCNO layer as an intermediate layer are vapor-deposited to form a multilayer with the target layer thickness shown in Table 3 under the conditions shown in Table 2, respectively.
Then, a vertically long TiCN layer as an upper layer is formed by vapor deposition with the target layer thickness shown in Table 3 under the conditions shown in Table 2.
Next, a granular Ti compound layer as an adhesion layer is formed by vapor deposition with the combination shown in Table 3 and the target layer thickness under the conditions shown in Table 2.
Furthermore, the Al 2 O 3 layer as the outermost surface layer was vapor-deposited with the target layer thickness shown in Table 3 under the conditions shown in Table 2, and the inventive coated tools 1 to 13 were respectively produced.

また、比較の目的で、硬質被覆層の中間層として、縦長TiCNO層単層を表2に示される条件で、表4に示される目標層厚で蒸着形成した以外は、実施例と同様にして、表2に示される条件で、表4に示される下部層、中間層、上部層、密着層、最表面層を、表4に示される目標層厚で蒸着形成することにより比較被覆工具1〜13をそれぞれ製造した。   Further, for the purpose of comparison, as a middle layer of the hard coating layer, a vertically long TiCNO layer single layer was formed under the conditions shown in Table 2 with the target layer thickness shown in Table 4, and the same as in the example. Under the conditions shown in Table 2, the lower layer, the intermediate layer, the upper layer, the adhesion layer, and the outermost surface layer shown in Table 4 are formed by vapor deposition with the target layer thickness shown in Table 4, and the comparative coated tool 1 13 were produced respectively.

そして、上記の本発明被覆工具1〜13および従来被覆工具1〜13について、これの硬質被覆層の構成層を電子線マイクロアナライザー(EPMA)およびオージェ分光分析装置を用いて観察(層の縦断面を観察)したところ、いずれも目標組成と実質的に同じ組成を有することが確認された。
また、これらの被覆工具の硬質被覆層の構成層の厚さを、走査型電子顕微鏡を用いて測定(同じく縦断面測定)したところ、いずれも目標層厚と実質的に同じ平均層厚(5点測定の平均値)を示した。
And about the said this invention coated tool 1-13 and the conventional coated tools 1-13, the structural layer of this hard coating layer is observed using an electron beam microanalyzer (EPMA) and an Auger spectrometer (longitudinal section of a layer) Were observed), and it was confirmed that both had substantially the same composition as the target composition.
Moreover, when the thickness of the constituent layer of the hard coating layer of these coated tools was measured using a scanning electron microscope (similarly longitudinal section measurement), the average layer thickness (5 The average value of point measurement) was shown.

つぎに、上記の各種の被覆工具をいずれも工具鋼製バイトの先端部に固定治具にてネジ止めした状態で、本発明被覆工具1〜13および従来被覆工具1〜13について、
被削材:JIS・SCM440の長さ方向等間隔4本縦溝入の丸棒、
切削速度: 350 m/min、
切り込み: 2.0 mm、
送り: 0.40 mm/rev、
切削時間: 5 分、
の条件(切削条件A)での合金鋼の乾式高速断続高送り切削試験(通常の切削速度は、200m/min、送りは、0.25mm/rev)、
被削材:JIS・S40Cの長さ方向等間隔4本縦溝入の丸棒、
切削速度: 400 m/min、
切り込み: 2.5 mm、
送り: 0.20 mm/rev、
切削時間: 5 分、
の条件(切削条件B)での炭素鋼の乾式高速断続高送り切削試験(通常の切削速度は、200m/min、送りは、0.10mm/rev)、
被削材:JIS・FCD700の長さ方向等間隔4本縦溝入の丸棒、
切削速度: 350 m/min、
切り込み: 2.0 mm、
送り: 0.35 mm/rev、
切削時間: 5 分、
の条件(切削条件C)でのダクタイル鋳鉄の乾式高速断続高送り切削試験(通常の切削速度は、300m/min、送りは、0.15mm/rev)、
を行い、いずれの切削試験でも切刃の逃げ面摩耗幅を測定した。この測定結果を表5に示した。
Next, in the state where all of the above various coated tools are screwed to the tip of the tool steel tool with a fixing jig, the present coated tools 1 to 13 and the conventional coated tools 1 to 13,
Work material: JIS / SCM440 lengthwise equidistantly four round bars with vertical grooves,
Cutting speed: 350 m / min,
Cutting depth: 2.0 mm,
Feed: 0.40 mm / rev,
Cutting time: 5 minutes,
Dry high-speed intermittent high-feed cutting test of alloy steel under the conditions (cutting condition A) (normal cutting speed is 200 m / min, feed is 0.25 mm / rev),
Work material: JIS / S40C lengthwise equidistant 4 round grooved round bars,
Cutting speed: 400 m / min,
Cutting depth: 2.5 mm,
Feed: 0.20 mm / rev,
Cutting time: 5 minutes,
Dry high-speed intermittent high-feed cutting test of carbon steel under the following conditions (cutting condition B) (normal cutting speed is 200 m / min, feed is 0.10 mm / rev),
Work material: JIS / FCD700 round bar with four equal grooves in the longitudinal direction,
Cutting speed: 350 m / min,
Cutting depth: 2.0 mm,
Feed: 0.35 mm / rev,
Cutting time: 5 minutes,
Dry high-speed intermittent high-feed cutting test of ductile cast iron under the above conditions (cutting condition C) (normal cutting speed is 300 m / min, feed is 0.15 mm / rev),
In each cutting test, the flank wear width of the cutting edge was measured. The measurement results are shown in Table 5.

Figure 0005110376
Figure 0005110376

Figure 0005110376
Figure 0005110376

Figure 0005110376
Figure 0005110376

Figure 0005110376
Figure 0005110376

Figure 0005110376
Figure 0005110376

表3〜5に示される結果から、本発明被覆工具1〜13は、硬質被覆層の中間層が粒状TiCNO層と粒状CrCNO層の複層として構成されていることから、高い発熱を伴うとともに切刃に対して大きな機械的・衝撃的負荷がかかる高速断続高送り切削加工でも、前記粒状CrCNO層が一段とすぐれた高温強度を備えるとともに、基体からのCr拡散抑制作用を有するので、基体の耐熱塑性変形性の低下はなく、また、粒状TiCNO層が粒状CrCNO層の高温硬さの低下を補完し、さらに、縦長TiCN層においては靭性が向上し硬度の低下もないため、すぐれた耐チッピング性と耐摩耗性を示すのに対して、硬質被覆層の中間層が縦長TiCNO層の単層で構成されている比較被覆工具1〜13においては、硬質被覆層の高温強度が不十分であり、さらに、基体の表面にCr欠乏層が生じるため耐熱塑性変形性に劣り、加えて、縦長TiCN層の硬度低下も生じるため、高速断続高送り切削加工では特に耐チッピング性が低下し、比較的短時間で使用寿命に至ることが明らかである。   From the results shown in Tables 3 to 5, the coated tools 1 to 13 of the present invention are accompanied by high heat generation because the intermediate layer of the hard coating layer is configured as a multilayer of a granular TiCNO layer and a granular CrCNO layer. Even in high-speed intermittent high-feed cutting where a large mechanical / impact load is applied to the blade, the granular CrCNO layer has excellent high-temperature strength and also has a Cr diffusion suppression action from the base. There is no decrease in deformability, and the granular TiCNO layer complements the decrease in high-temperature hardness of the granular CrCNO layer. Further, in the longitudinal TiCN layer, the toughness is improved and the hardness is not decreased. In the comparative coating tools 1 to 13 in which the intermediate layer of the hard coating layer is composed of a single layer of a vertically long TiCNO layer, while exhibiting wear resistance, the high temperature strength of the hard coating layer In addition, the Cr-depleted layer is formed on the surface of the substrate, resulting in inferior heat-resistant plastic deformability. In addition, the hardness of the vertically long TiCN layer is also reduced, so that chipping resistance is particularly reduced in high-speed intermittent high-feed cutting. It is clear that the service life is reached in a relatively short time.

上述のように、この発明の被覆工具は、各種鋼や鋳鉄などの通常の条件での連続切削や断続切削は勿論のこと、大きな発熱を伴い、かつ、切刃に対して大きな機械的・衝撃的負荷がかかる高速断続高送り切削加工でもすぐれた耐チッピング性を示し、長期に亘ってすぐれた切削性能を発揮するものであるから、切削装置の高性能化並びに切削加工の省力化および省エネ化、さらに低コスト化に十分満足に対応できるものである。   As described above, the coated tool of the present invention is not only continuous and intermittent cutting under normal conditions such as various steels and cast irons, but also generates a large amount of heat and has a large mechanical / impact on the cutting edge. Show excellent chipping resistance even in high-speed intermittent high-feed cutting with heavy loads, and exhibit excellent cutting performance over a long period of time. In addition, it can cope with the cost reduction sufficiently satisfactorily.

Claims (2)

炭化タングステン基超硬合金または炭窒化チタン基サーメットで構成された工具基体の表面に、
(a)下部層が、0.1〜2μmの合計平均層厚を有する化学蒸着で形成された、粒状結晶組織のTiの炭化物層、窒化物層、炭窒化物層のうちの少なくとも1層、
(b)中間層が、0.5〜3μmの合計平均層厚を有する、化学蒸着で形成された粒状結晶組織のTiの炭窒酸化物層と、同じく化学蒸着で形成された粒状結晶組織のCrの炭窒酸化物層の積層、
(c)上部層が、2〜20μmの平均層厚を有する化学蒸着で形成された、縦長成長結晶組織のTiの炭窒化物層、
(d)最表面層が、0.2〜15μmの平均層厚を有する化学蒸着で形成された酸化アルミニウム層、
以上(a)〜(d)で構成された硬質被覆層を形成してなる表面被覆切削工具。
On the surface of the tool base composed of tungsten carbide based cemented carbide or titanium carbonitride based cermet,
(A) the lower layer is formed by chemical vapor deposition having a total average layer thickness of 0.1 to 2 μm, at least one of a Ti carbide layer, a nitride layer, and a carbonitride layer having a granular crystal structure;
(B) an intermediate layer having a total average layer thickness of 0.5 to 3 μm, a Ti crystal oxynitride layer having a granular crystal structure formed by chemical vapor deposition, and a granular crystal structure also formed by chemical vapor deposition Lamination of Cr carbonitride layer,
(C) The upper layer is formed by chemical vapor deposition having an average layer thickness of 2 to 20 μm, and a Ti carbonitride layer having a vertically grown crystal structure,
(D) an aluminum oxide layer formed by chemical vapor deposition in which the outermost surface layer has an average layer thickness of 0.2 to 15 μm;
A surface-coated cutting tool formed by forming a hard coating layer composed of (a) to (d) above.
請求項1記載の表面被覆切削工具において、
上記(c)の縦長成長結晶組織のTiの炭窒化物層と、上記(d)の酸化アルミニウム層との間に、0.1〜3μmの平均層厚を有する化学蒸着で形成された粒状結晶組織のTiの炭化物層、窒化物層、炭窒化物層、炭酸化物層、炭窒酸化物層のうちの少なくとも1層からなる密着層を介在してなる請求項1に記載の表面被覆切削工具。
The surface-coated cutting tool according to claim 1,
Granular crystals formed by chemical vapor deposition having an average layer thickness of 0.1 to 3 μm between the Ti carbonitride layer having the vertically elongated crystal structure (c) and the aluminum oxide layer (d). 2. The surface-coated cutting tool according to claim 1, comprising an adhesion layer comprising at least one of a Ti carbide layer, a nitride layer, a carbonitride layer, a carbonate layer, and a carbonitride layer of the structure. .
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