JPH0866705A - Composite film forming tool for hot working - Google Patents
Composite film forming tool for hot workingInfo
- Publication number
- JPH0866705A JPH0866705A JP22579394A JP22579394A JPH0866705A JP H0866705 A JPH0866705 A JP H0866705A JP 22579394 A JP22579394 A JP 22579394A JP 22579394 A JP22579394 A JP 22579394A JP H0866705 A JPH0866705 A JP H0866705A
- Authority
- JP
- Japan
- Prior art keywords
- carbide
- composite film
- tool
- metal
- hot working
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Granted
Links
Landscapes
- Reduction Rolling/Reduction Stand/Operation Of Reduction Machine (AREA)
- Other Surface Treatments For Metallic Materials (AREA)
Abstract
Description
【0001】[0001]
【産業上の利用分野】本発明は、継目無製管や板圧延、
形鋼、条鋼、線材圧延等、熱間塑性加工で使用される工
具に係り、特に耐摩耗性および耐熱亀裂性に優れた熱間
加工用複合被膜形成工具に関する。BACKGROUND OF THE INVENTION The present invention relates to a seamless pipe or sheet rolling,
The present invention relates to a tool used in hot plastic working such as shaped steel, bar steel, and wire rod rolling, and particularly to a composite film forming tool for hot working excellent in wear resistance and heat crack resistance.
【0002】[0002]
【従来の技術】継目無製管や板圧延、形鋼、条鋼、線材
圧延等、熱間塑性加工で使用される工具は、高温の被加
工材と直接に接触しながら厳しい摩擦を受けることから
表層部が極端に温度上昇し、そのために摩耗が著しい。
また、これらの工具は被加工材と断続的に繰返し摩擦さ
れ、被加工材と非接触状態にある時に水冷や空冷で表面
の冷却が行われるが、このような被加工材との接触、摩
擦による急熱と、冷却による急冷が繰返されることによ
って熱衝撃や熱疲労によるクラックが生じ易く、これが
被加工材の表面疵の原因になったり、割損して使用不能
となったり、甚だしい場合には圧延トラブルとなって設
備に損傷を与えかねない。したがって、熱間加工用の工
具には、耐摩耗性と耐熱亀裂性が同時に要求される。2. Description of the Related Art Tools used in hot plastic working such as seamless pipe and plate rolling, shaped steel, bar steel and wire rolling suffer from severe friction while being in direct contact with a hot work material. The surface layer temperature rises extremely, which causes considerable wear.
In addition, these tools are repeatedly rubbed intermittently with the work material, and the surface is cooled by water cooling or air cooling when not in contact with the work material. The rapid heating due to and the rapid cooling due to cooling are likely to cause cracks due to thermal shock and thermal fatigue, which may cause surface flaws on the work material, may cause breakage and become unusable, or in extreme cases. It may cause rolling trouble and damage the equipment. Therefore, a tool for hot working is required to have wear resistance and heat crack resistance at the same time.
【0003】例えば、熱間で継目無管を製造する工程の
一つであるプラグミル圧延においては、素管外面を拘束
しながら軸方向に送りを与える一対の孔型ロールと、素
管内面を拘束するプラグとによって圧延が行われるが、
その際プラグは1000〜1200℃の高温の素管内面
と接触しながら高面圧のもとで完全なすべり摩擦を受け
ることから、摩耗を生じ易く、また圧延直後には水冷に
よって急冷されたり、さらに急熱、急冷が繰返されるた
めに熱衝撃や熱疲労によってクラックが発生する。[0003] For example, in plug mill rolling, which is one of the steps of hot-manufacturing seamless pipes, a pair of hole-shaped rolls that feed in the axial direction while restraining the outer surface of the raw pipe and the inner surface of the raw pipe are restrained. Rolling is performed with the plug
At that time, the plug undergoes complete sliding friction under high surface pressure while being in contact with the inner surface of the base material at a high temperature of 1000 to 1200 ° C., so that it easily wears, and immediately after rolling, it is rapidly cooled by water cooling, Furthermore, since rapid heating and rapid cooling are repeated, cracks occur due to thermal shock and thermal fatigue.
【0004】このような状況下で使用されるプラグとし
ては、従来から1.0〜1.5%Cー25%Crー3%
Ni鋼や1.0〜1.5%Cー17%Crー2%W鋼等
の高Cー高Cr鋳鋼が使用されている。Conventionally, a plug used in such a situation is 1.0 to 1.5% C-25% Cr-3%.
High C-high Cr cast steels such as Ni steel and 1.0-1.5% C-17% Cr-2% W steel are used.
【0005】[0005]
【発明が解決しようとする課題】継目無製管や板圧延、
形鋼、条鋼、線材圧延等においては、製造コスト合理化
や製品の表面品質、寸法精度の向上が強く望まれている
が、例えば継目無管の製造に使用されている従来のプラ
グは、前記したごとく摩耗や熱亀裂が早期に生じて寿命
となる上、これらの損傷が製品内面疵や寸法精度不良の
原因となるため、耐摩耗性、耐熱亀裂性の優れた工具の
開発が望まれている。[Problems to be Solved by the Invention] Seamless pipe and sheet rolling,
For shaped steel, bar steel, wire rod rolling, etc., rationalization of manufacturing cost and improvement of product surface quality and dimensional accuracy are strongly desired, but for example, conventional plugs used for manufacturing seamless pipes are As described above, wear and thermal cracks occur early and reach the end of their lives, and these damages cause defects on the inner surface of the product and poor dimensional accuracy, so the development of tools with excellent wear resistance and heat crack resistance is desired. .
【0006】ところが、一般に耐摩耗性を向上させるた
めには工具表層の強度を高める必要があり、一方熱亀裂
の発生、進展を抑制するためには工具の延性、靭性を向
上させる必要があるが、これらは通常、相反する特性で
あるために耐摩耗性と耐熱亀裂性を合わせ持つ工具は未
だ開発されていないのが現状である。However, in general, it is necessary to increase the strength of the tool surface layer in order to improve wear resistance, while it is necessary to improve the ductility and toughness of the tool in order to suppress the occurrence and development of thermal cracks. However, since these are usually contradictory properties, a tool having both wear resistance and heat crack resistance has not yet been developed.
【0007】なお、特開平1−148405号公報で
は、特定成分の金属マトリックス中に重量比で50〜8
0%のニオブ炭化物を分散させた複合肉盛被膜を形成さ
せたシームレスパイプ熱間傾斜圧延用ガイドシューが提
案されているが、耐摩耗性は良好なものの熱亀裂が発生
し易く、思ったほど工具寿命を延長できないのが現状で
ある。In JP-A-1-148405, a metal matrix of a specific component is added in a weight ratio of 50-8.
A guide pipe for hot-rolled seamless pipe with a composite build-up coating in which 0% niobium carbide is dispersed has been proposed. Although it has good wear resistance, it is prone to thermal cracking, The current situation is that the tool life cannot be extended.
【0008】本発明はこのような現状に鑑みてなされた
ものであり、通常は相反する特性である耐摩耗性と耐熱
亀裂性の両面に優れた特性を有する熱間加工用複合被膜
形成工具を提供しようとするものである。The present invention has been made in view of the above circumstances, and provides a composite coating forming tool for hot working which has excellent properties in both wear resistance and heat crack resistance, which are usually contradictory properties. It is the one we are trying to provide.
【0009】[0009]
【課題を解決するための手段】本発明に係る熱間加工用
複合被膜形成工具は、母材表面に、平均粒径が65〜1
35μmの炭化物粒子を体積比で20〜50%含む金属
ー炭化物複合被膜を形成したことを特徴とし、また前記
金属ー炭化物複合被膜中の炭化物粒子がニオブ炭化物で
あることを特徴とするものである。The composite film forming tool for hot working according to the present invention has an average particle size of 65 to 1 on the surface of the base material.
A metal-carbide composite coating containing 20 to 50% by volume of 35 μm carbide particles is formed, and the carbide particles in the metal-carbide composite coating are niobium carbides. .
【0010】[0010]
【作用】本発明における母材鋼としては、圧延途中で変
形したり、クラックが内部まで進展して割損が生じない
ことが必要であり、被加工材の温度や変形抵抗、あるい
は圧延条件等を考慮して適宜選択すればよい。一般的に
はステンレス鋼、炭素鋼、またはSKD等の合金鋼等を
使用する。母材に加わる負荷条件が特段に厳しくならな
い限りは炭素鋼、低合金鋼等を使用できる。The base steel in the present invention is required not to be deformed during rolling or to be cracked to the inside so as not to cause cracking. The temperature and deformation resistance of the work material, rolling conditions, etc. May be selected as appropriate. Generally, stainless steel, carbon steel, or alloy steel such as SKD is used. Carbon steel, low alloy steel, etc. can be used as long as the load conditions applied to the base material are not particularly severe.
【0011】本発明における金属ー炭化物複合被膜の炭
化物としては、ニオブ炭化物、タングステン炭化物、チ
タニウム炭化物、バナジウム炭化物、クロム炭化物等各
種あり、また、金属(マリックス金属)としては、ある
程度の高温強度と靭性を持つマルテンサイト系やオース
テナイト系ステンレスが好ましい。As the carbide of the metal-carbide composite coating in the present invention, there are various niobium carbides, tungsten carbides, titanium carbides, vanadium carbides, chromium carbides, and the like, and the metal (marix metal) has a high temperature strength and toughness to some extent. Martensitic and austenitic stainless steels having
【0012】本発明において、金属ー炭化物複合被膜中
の炭化物平均粒径を65〜135μmに限定したのは、
以下に示す理由による。すなわち、母材表面に形成する
金属ー炭化物複合被膜中の炭化物粒径は、一般に50〜
200μm程度とするのが普通であるが、熱間加工用工
具の耐摩耗性および耐熱亀裂性に重大な影響を及ぼし、
両特性を両立させる最適な粒径範囲が存在することが、
本発明者が行った試験結果より明らかとなった。In the present invention, the average grain size of carbide in the metal-carbide composite coating is limited to 65 to 135 μm.
The reason is as follows. That is, the carbide particle size in the metal-carbide composite coating formed on the surface of the base material is generally 50 to 50.
It is usually about 200 μm, but it has a significant influence on the wear resistance and heat crack resistance of the hot working tool,
There is an optimum particle size range that makes both properties compatible,
It became clear from the test results conducted by the present inventor.
【0013】図1は本発明者が行った試験結果より明ら
かとなった高温摩耗特性に及ぼす炭化物粒径の影響を示
す図であり、下記の条件で行った摩擦試験方法により得
られた結果である。FIG. 1 is a diagram showing the influence of the grain size of carbides on the high temperature wear characteristics which was clarified from the test results conducted by the present inventor, and is the result obtained by the friction test method conducted under the following conditions. is there.
【0014】<摩擦試験条件> 供試材材質:従来プラグ材(1.0〜1.5Cー17C
rー2W鋳鋼)の表面にプラズマ粉体肉盛法で炭化物粒
径を変化させた複合被膜(炭化物:ニオブ炭化物40
%、マトリックス金属:SUS304)を形成。 供試材寸法:長さ20mm×幅20mm×厚さ10mm
(摩擦面は20mm×10mmの面) 相手材材質:2.25%Crー1Mo鋼 相手材寸法:直径100mm×厚さ30mm 相手材加熱温度:1000℃(高周波誘導加熱) 相手材回転数:100rpm 荷重:100kgf(供試材を相手材外周面に押付ける
荷重) 試験時間:10分 評価方法:摩耗痕の体積を測定し、従来プラグを基準と
した場合の相対摩耗度として評価した。<Friction test conditions> Specimen material: Conventional plug material (1.0 to 1.5C-17C)
r-2W cast steel) composite coating (carbide: niobium carbide 40) in which the grain size of carbide is changed by plasma powder overlaying method
%, Matrix metal: SUS304) formed. Specimen size: length 20 mm x width 20 mm x thickness 10 mm
(Friction surface is 20 mm x 10 mm) Mating material: 2.25% Cr-1Mo steel Mating material dimension: 100 mm diameter x 30 mm thickness Mating temperature: 1000 ° C (high frequency induction heating) Mating speed: 100 rpm Load: 100 kgf (load to press the test material against the outer peripheral surface of the mating material) Test time: 10 minutes Evaluation method: The volume of the wear mark was measured and evaluated as the relative wear degree when the conventional plug was used as a reference.
【0015】図1に示すごとく、金属ー炭化物複合被膜
中の炭化物の平均粒径が小さいと摩耗し易く、他方、炭
化物が大きくなりすぎても多少摩耗量が増える傾向にあ
り、最も相対摩耗度の小さい炭化物平均粒径としては6
5〜135μmであることが判明した。As shown in FIG. 1, if the average particle size of the carbide in the metal-carbide composite coating is small, it is likely to wear, while on the other hand, if the carbide becomes too large, the amount of wear tends to increase, and the relative degree of wear is the highest. The average particle size of carbides is 6
It was found to be 5 to 135 μm.
【0016】また、母材の熱亀裂特性に及ぼす金属ー炭
化物複合被膜中の炭化物粒径の影響を調べるために行っ
た熱亀裂試験結果を以下に示す。The results of a thermal crack test conducted to investigate the effect of the carbide grain size in the metal-carbide composite coating on the thermal crack characteristics of the base material are shown below.
【0017】試験方法としては、円柱状試験片(材質:
S45C、寸法:直径30mm×長さ30mm)の外周
部にプラズマ粉体肉盛法で炭化物平均粒径を変化させた
金属ー炭化物複合被膜(炭化物:ニオブ炭化物40%、
マトリックス金属:SUS304)を形成し、外面を切
削して所定の形状に仕上げ、この試験片および従来プラ
グ材(1.0〜1.5Cー17Crー2W鋳鋼)から削
り出した試験片について、高周波加熱(加熱温度100
0℃)した後、水冷する工程を1サイクルとし、これを
100回繰返した。評価方法としては、試験後の供試材
断面をミクロ観察して、クラックの長さを総計し、従来
プラグ材を基準とした場合の相対クラック長さとして評
価した。その結果を図2に示す。As a test method, a cylindrical test piece (material:
S45C, dimensions: diameter 30 mm x length 30 mm) metal-carbide composite coating (carbide: niobium carbide 40%, with varying average carbide particle size by plasma powder overlay method)
Matrix metal: SUS304) was formed, the outer surface was cut to finish into a predetermined shape, and this test piece and a test piece cut out from a conventional plug material (1.0 to 1.5C-17Cr-2W cast steel) were subjected to high frequency Heating (heating temperature 100
After 0 ° C.), the step of cooling with water was defined as one cycle, and this was repeated 100 times. As an evaluation method, the cross section of the test material after the test was microscopically observed, the crack lengths were totaled, and evaluated as the relative crack length based on the conventional plug material. The result is shown in FIG.
【0018】図2に示すごとく、耐熱亀裂性について
は、炭化物平均粒径が大きくなるにつれて緩やかにクラ
ック長さが増加するが、135μmを超えると急激にク
ラック長さが増大することが判明した。一方、炭化物平
均粒径の下限は小さい程クラック長さも短かくなるが、
炭化物平均粒径が65μm未満では前記図1に示すデー
タより明らかなごとく耐摩耗性が低下するため、炭化物
平均粒径の下限は65μmとする必要がある。As shown in FIG. 2, regarding the thermal crack resistance, it was found that the crack length gradually increased as the average grain size of the carbides increased, but when it exceeded 135 μm, the crack length drastically increased. On the other hand, the smaller the lower limit of the carbide average particle size, the shorter the crack length,
If the carbide average particle size is less than 65 μm, the wear resistance is reduced as is apparent from the data shown in FIG. 1, so the lower limit of the carbide average particle size needs to be 65 μm.
【0019】以上の結果より、本発明では耐摩耗性と耐
熱亀裂性の両特性が良好な範囲として、金属ー炭化物複
合被膜中の炭化物粒径を65〜135μmに限定したの
である。From the above results, in the present invention, the grain size of carbide in the metal-carbide composite coating is limited to 65 to 135 μm as a range in which both the wear resistance and the heat crack resistance are good.
【0020】次に、金属ー炭化物複合被膜中の炭化物粒
子の含有量を体積比で20〜50%に限定した理由を以
下に説明する。すなわち、金属中に分散された炭化物粒
子は、被膜の常温から高温におよぶ強度を高め摩耗を抑
制する効果と、焼付きを防止する効果があり、これらの
効果を有効に作用させるためには、少なくとも体積比で
20%は必要であり、他方、50%を超えて含有させて
も効果の増大を期待できないばかりか、炭化物を保持す
る金属の量が低下して被膜の形成が困難となり、また耐
熱亀裂性も低下するため、炭化物粒子の含有量を体積比
で20〜50%に限定したのである。Next, the reason why the content of the carbide particles in the metal-carbide composite coating is limited to 20 to 50% by volume will be described below. That is, the carbide particles dispersed in the metal have the effect of increasing the strength of the coating from normal temperature to high temperature and suppressing wear, and the effect of preventing seizure, and in order to make these effects work effectively, At least 20% by volume is necessary. On the other hand, if the content exceeds 50%, not only the effect cannot be expected to increase, but also the amount of metal that retains carbides decreases, making it difficult to form a film. Since the thermal crack resistance is also reduced, the content of the carbide particles is limited to 20 to 50% by volume.
【0021】また、本発明において、金属ー炭化物複合
被膜中の炭化物粒子として、特にニオブ炭化物を特定し
たのは、被膜中に分散させて耐摩耗性を向上させる効果
を有する炭化物としては、前記したごとくニオブ炭化物
の外、タングステン炭化物、チタニウム炭化物、バナジ
ウム炭化物、クロム炭化物等各種あるが、ニオブ炭化物
を被膜中に分散させた場合に最も優れた耐摩耗性、耐熱
亀裂性が得られるからである。Further, in the present invention, niobium carbide is specified as the carbide particles in the metal-carbide composite coating, and the carbide particles having the effect of improving the wear resistance by being dispersed in the coating are described above. In addition to niobium carbide, there are various types such as tungsten carbide, titanium carbide, vanadium carbide, and chromium carbide. However, when niobium carbide is dispersed in the coating, the best wear resistance and heat crack resistance can be obtained.
【0022】炭化物粒子を含む金属ー炭化物複合被膜の
形成方法としては、母材とカプセルの間に金属および炭
化物の混合粉末を封入して熱間静水圧プレスする方法
(HIP法)、母材表面に上記粉末を塗布した後にレー
ザーを照射して部分的に溶融、固化する方法(レーザー
クラッディング)等も可能であるが、より簡便に複合被
膜を形成させる方法としては、電極と母材との間に発生
させたプラズマ中に前記粉末を送給して母材表面に肉盛
するプラズマ粉体肉盛法があり、母材との密着性および
被膜の緻密性に優れている上に、製作コストの面でも有
利である。この炭化物粒子を含む金属ー炭化物複合被膜
の厚さとしては、特に限定するものではないが、常温か
ら高温におよぶ範囲で十分な表面強度を確保するために
は少なくとも1mm以上の厚みを有することが好まし
い。As a method for forming a metal-carbide composite coating containing carbide particles, a method of enclosing mixed powder of metal and carbide between a base material and a capsule and hot isostatic pressing (HIP method), a surface of the base material A method of partially melting and solidifying by irradiating a laser after applying the above powder to the above (laser cladding) is also possible, but as a simpler method of forming a composite coating, the electrode and the base material are There is a plasma powder build-up method in which the powder is fed into the plasma generated between and built up on the surface of the base material, and in addition to excellent adhesion to the base material and denseness of the coating, It is also advantageous in terms of cost. The thickness of the metal-carbide composite coating containing the carbide particles is not particularly limited, but in order to secure sufficient surface strength in the range from normal temperature to high temperature, it is necessary to have a thickness of at least 1 mm or more. preferable.
【0023】本発明の金属ー炭化物複合被膜形成工具
は、前記したごとく優れた高温耐摩耗性と耐熱衝撃性を
合わせ持ち、また特に炭化物としてニオブ炭化物を用い
ることにより、特段に優れた性能が得られ、優れた工具
寿命を有する。The metal-carbide composite coating forming tool of the present invention has both excellent high-temperature wear resistance and thermal shock resistance as described above, and particularly when niobium carbide is used as the carbide, particularly excellent performance can be obtained. And has an excellent tool life.
【0024】[0024]
実施例1 プラグミルで使用するプラグを対象として、S45C鋼
を母材とし、その表面にニオブ炭化物の含有量を種々に
変化させた金属ーニオブ炭化物混合粉末の外、金属ータ
ングステン炭化物混合粉末、金属ーチタニウム炭化物混
合粉末、金属ーバナジウム炭化物混合粉末、金属ークロ
ム炭化物混合粉末をそれぞれプラズマ粉体肉盛法によっ
て肉盛溶接した。その際使用した金属粉末はSUS30
4ステンレス鋼粉であり、肉盛厚さは約2mmであっ
た。各プラグ表面は切削加工により仕上げた。Example 1 For a plug used in a plug mill, using S45C steel as a base material, in addition to a metal-niobium carbide mixed powder having various contents of niobium carbide on its surface, a metal-tungsten carbide mixed powder, a metal-titanium The carbide mixed powder, the metal-vanadium carbide mixed powder, and the metal-chromium carbide mixed powder were overlay welded by the plasma powder overlay method. The metal powder used at that time was SUS30.
It was 4 stainless steel powder, and the build-up thickness was about 2 mm. The surface of each plug was finished by cutting.
【0025】これらのプラグを用いて炭素鋼素管のプラ
グミル圧延を行った結果を、従来使用されている1.0
〜1.5%Cー17%Crー2%W鋼製プラグの寿命を
基準とした時の寿命比で評価した。その結果を表2に示
す。なお、素管の寸法、温度は表1に示す通りである。The results of plug mill rolling of carbon steel blanks using these plugs are 1.0
Evaluation was made by the life ratio based on the life of a plug made of ~ 1.5% C-17% Cr-2% W steel. The results are shown in Table 2. The dimensions and temperatures of the blank tube are as shown in Table 1.
【0026】この圧延テストの結果、被膜中の炭化物粒
径および炭化物含有量を本発明の範囲としたプラグは、
いずれも優れた耐摩耗性と耐熱亀裂性を合わせ持ち、従
来プラグに比べ2.3〜3.7倍の高寿命を示した。こ
れに対し、炭化物粒径および炭化物含有量が本発明範囲
から外れたプラグおよび従来プラグでは、極端に大きな
摩耗が生じたり、深いクラックが発生して早期に寿命と
なった。As a result of this rolling test, a plug having a carbide grain size and a carbide content in the coating within the range of the present invention was
Both had excellent wear resistance and heat crack resistance, and exhibited a life of 2.3 to 3.7 times that of conventional plugs. On the other hand, in the case where the carbide grain size and the carbide content were out of the range of the present invention and the conventional plug, extremely large abrasion was caused or deep cracks were generated, and the life was early.
【0027】[0027]
【表1】 [Table 1]
【0028】[0028]
【表2】 [Table 2]
【0029】[0029]
【発明の効果】以上説明したごとく、本発明の熱間加工
用複合被膜形成工具は、優れた高温耐摩耗性と耐熱衝撃
性を合わせ持ち、また特に炭化物としてニオブ炭化物を
用いることにより、特段に優れた性能が得られ、優れた
工具寿命を有する。したがって、特に熱間継目無管を製
造する際のプラグミル用プラグミルに適用した場合に
は、プラグ寿命が大幅に延長でき、製管コストの低減が
はかられるとともに、製品内面品質および寸法精度の優
れた製品が得られる等、多大な効果を奏する。また、本
発明はプラグミル用プラグミルのみならず、ピアサー用
プラグ、マンドレルミル用マンドレルバー、ガイドシュ
ー、ロール、管端アプセット加工用ダイやマンドレル、
熱延鋼板や形鋼、条鋼、線材を圧延する際のロール等の
各種熱間工具は勿論のこと、熱間材の搬送用ロールやガ
イド類の熱間摺動部材にも十分適用可能である。As described above, the composite coating forming tool for hot working of the present invention has excellent high temperature wear resistance and thermal shock resistance together, and in particular, when niobium carbide is used as the carbide, Excellent performance is obtained and excellent tool life. Therefore, especially when applied to a plug mill for plug mills when manufacturing hot seamless pipes, the life of the plugs can be significantly extended, pipe manufacturing costs can be reduced, and the product inner surface quality and dimensional accuracy are excellent. It is possible to obtain a great product, which is very effective. Further, the present invention is not only a plug mill for a plug mill, but also a piercer plug, a mandrel bar for a mandrel mill, a guide shoe, a roll, a pipe end upset processing die and a mandrel,
Not only various hot tools such as rolls for rolling hot-rolled steel sheets, shaped steel, bar steel, and wire rods, but also applicable to hot-roll material transfer rolls and hot-sliding members such as guides. .
【図1】本発明における金属ー炭化物複合被膜中の炭化
物平均粒径と摩耗特性の関係を示す図である。FIG. 1 is a diagram showing a relationship between an average grain size of carbides in a metal-carbide composite coating and wear characteristics in the present invention.
【図2】同じく金属ー炭化物複合被膜中の炭化物平均粒
径と熱亀裂特性の関係を示す図である。FIG. 2 is a view showing the relationship between the average grain size of carbide in the metal-carbide composite coating and the thermal cracking property.
Claims (2)
mの炭化物粒子を体積比で20〜50%含む金属ー炭化
物複合被膜を形成したことを特徴とする熱間加工用複合
被膜形成工具。1. An average particle size of 65 to 135 μm on the surface of the base material.
A composite coating forming tool for hot working, wherein a metal-carbide composite coating containing 20 to 50% by volume of carbide particles of m is formed.
ニオブ炭化物であることを特徴とする請求項1記載の熱
間加工用複合被膜形成工具。2. The composite coating forming tool for hot working according to claim 1, wherein the carbide particles in the metal-carbide composite coating are niobium carbide.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP6225793A JP2776266B2 (en) | 1994-08-26 | 1994-08-26 | Composite film forming tool for hot working |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP6225793A JP2776266B2 (en) | 1994-08-26 | 1994-08-26 | Composite film forming tool for hot working |
Publications (2)
Publication Number | Publication Date |
---|---|
JPH0866705A true JPH0866705A (en) | 1996-03-12 |
JP2776266B2 JP2776266B2 (en) | 1998-07-16 |
Family
ID=16834873
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP6225793A Expired - Fee Related JP2776266B2 (en) | 1994-08-26 | 1994-08-26 | Composite film forming tool for hot working |
Country Status (1)
Country | Link |
---|---|
JP (1) | JP2776266B2 (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104736262A (en) * | 2013-01-11 | 2015-06-24 | 新日铁住金株式会社 | Plug for hot pipe manufacturing |
Families Citing this family (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
EP2842645B1 (en) | 2012-04-24 | 2016-12-21 | Nippon Steel & Sumitomo Metal Corporation | Plug used in piercing machine |
Citations (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS63248504A (en) * | 1987-03-31 | 1988-10-14 | Sumitomo Metal Ind Ltd | Plug for hot manufacturing seamless tube |
-
1994
- 1994-08-26 JP JP6225793A patent/JP2776266B2/en not_active Expired - Fee Related
Patent Citations (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS63248504A (en) * | 1987-03-31 | 1988-10-14 | Sumitomo Metal Ind Ltd | Plug for hot manufacturing seamless tube |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104736262A (en) * | 2013-01-11 | 2015-06-24 | 新日铁住金株式会社 | Plug for hot pipe manufacturing |
US9352370B2 (en) | 2013-01-11 | 2016-05-31 | Nippon Steel & Sumitomo Metal Corporation | Plug for hot tube-making |
Also Published As
Publication number | Publication date |
---|---|
JP2776266B2 (en) | 1998-07-16 |
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