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JPH11302826A - Normal temperature carburizing method - Google Patents

Normal temperature carburizing method

Info

Publication number
JPH11302826A
JPH11302826A JP11360198A JP11360198A JPH11302826A JP H11302826 A JPH11302826 A JP H11302826A JP 11360198 A JP11360198 A JP 11360198A JP 11360198 A JP11360198 A JP 11360198A JP H11302826 A JPH11302826 A JP H11302826A
Authority
JP
Japan
Prior art keywords
treated
product
carbide powder
steel
carbon
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
Application number
JP11360198A
Other languages
Japanese (ja)
Other versions
JP3242060B2 (en
Inventor
Yoshio Miyasaka
四志男 宮坂
Tadaharu Kagaya
忠治 加賀谷
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Fuji Kihan Co Ltd
Original Assignee
Fuji Kihan Co Ltd
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Application filed by Fuji Kihan Co Ltd filed Critical Fuji Kihan Co Ltd
Priority to JP11360198A priority Critical patent/JP3242060B2/en
Publication of JPH11302826A publication Critical patent/JPH11302826A/en
Application granted granted Critical
Publication of JP3242060B2 publication Critical patent/JP3242060B2/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

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  • Other Surface Treatments For Metallic Materials (AREA)

Abstract

PROBLEM TO BE SOLVED: To provide a normal temperature carburizing method to reduce the deformation of a product and to improve the wear resistance and he fatigue strength of the product by performing the carburizing treatment of steel through a blast treatment and treating it at a normal temperature using a device less in pollution and inexpensive. SOLUTION: When carbide powder preferably higher in hardness and a melting point than a product to be treated is ejected against the surface of the product to be treated consisting of carbon steel, special steel or a mixed body thereof, the change in speed of the carbide powder before and after the collision is converted into thermal energy and the temperature of the surface of the product to be treated and the carbide powder rises. At this time, since the carbide powder is thermally decomposed and the carbon element in the carbide powder is diffused into the surface of the product to be treated, the carburizing treatment is performed.

Description

【発明の詳細な説明】DETAILED DESCRIPTION OF THE INVENTION

【0001】[0001]

【発明の属する技術分野】本発明は、炭素鋼又は合金
鋼、工具鋼、特殊用途鋼などの特殊鋼又はこれらの混合
体の鉄鋼材料から成る被処理成品、及びアルミニウムな
ど非鉄金属材料から成る被処理成品、特に低炭素鋼又は
低炭素量の特殊鋼から成る被処理成品の耐摩耗性などの
向上の目的で行われる浸炭処理としての金属表面処理法
に関し、被処理成品の表面に、炭化物粉体を噴射し、前
記炭化物粉体中の炭素元素を被処理成品表面に拡散さ
せ、より深い浸炭処理層を得ることのできる常温浸炭処
理方法に関する。
BACKGROUND OF THE INVENTION The present invention relates to a treated product made of a steel material of a special steel such as carbon steel or alloy steel, tool steel, special purpose steel or a mixture thereof, and a product made of a non-ferrous metal material such as aluminum. Regarding the metal surface treatment method as a carburizing treatment performed for the purpose of improving the wear resistance etc. of the treated product, especially the treated product composed of low carbon steel or low carbon content special steel, the surface of the treated product is treated with carbide powder. The present invention relates to a normal temperature carburizing method capable of injecting a body and diffusing a carbon element in the carbide powder to a surface of a product to be treated to obtain a deeper carburizing layer.

【0002】[0002]

【従来の技術】従来、例えば、鋼の耐摩耗性を向上させ
る方法として、焼入れ、窒化処理、各種メッキ法及び浸
炭処理などがある。
2. Description of the Related Art Conventionally, for example, methods for improving the wear resistance of steel include quenching, nitriding, various plating methods, and carburizing.

【0003】焼入れは、鋼をオーステナイト組織に加熱
した後、冷却剤中で急冷する処理のことで、マルテンサ
イト組織を生成して硬度を高めるものである。
[0003] Quenching is a process in which steel is heated to an austenitic structure and then quenched in a coolant to generate a martensite structure and increase the hardness.

【0004】窒化処理には、ガス窒化、液体窒化があ
り、例えばガス窒化では、アルミニウムやクロムなどの
合金鋼をアンモニアガス中で高温保持して鋼の表面層に
窒素を拡散させ、硬質の窒化層を形成させる処理であ
る。
[0004] Nitriding includes gas nitriding and liquid nitriding. For example, in gas nitriding, an alloy steel such as aluminum or chromium is kept at a high temperature in ammonia gas to diffuse nitrogen into the surface layer of the steel to form a hard nitride. This is a process for forming a layer.

【0005】また、各種メッキ法では、溶融メッキ法、
拡散浸透メッキ法、電気メッキ法などがあり、例えば溶
融メッキ法は、溶融している金属浴に被処理成品を漬け
て、所定時間経過後、金属浴から引き上げる作業によっ
て行うメッキ法であり、溶融亜鉛メッキ、溶融錫メッキ
などがある。
[0005] In various plating methods, hot-dip plating,
Diffusion infiltration plating, electroplating, etc., for example, hot-dip plating is a plating method performed by immersing a product to be treated in a molten metal bath and pulling it out of the metal bath after a predetermined time elapses. There are zinc plating and hot-dip tin plating.

【0006】浸炭処理は、一般に、低炭素鋼又は低炭素
量の特殊鋼を浸炭性雰囲気中で加熱し、鋼の表面層の炭
素量を高める処理であり、浸炭性雰囲気の状態により、
固体浸炭法、ガス浸炭法、液体浸炭法に分けられるが、
このうちガス浸炭法は、表面炭素濃度の調節ができるこ
とや大量生産ができるといった長所があり、このガス浸
炭法が主流となっている。この浸炭処理後、焼入れをす
ることで表面が硬化する。
[0006] Carburizing treatment is generally a treatment in which low-carbon steel or low-carbon special steel is heated in a carburizing atmosphere to increase the carbon content of the surface layer of the steel.
Solid carburizing method, gas carburizing method, and liquid carburizing method,
Among them, the gas carburizing method has advantages in that the surface carbon concentration can be adjusted and mass production is possible, and the gas carburizing method is mainly used. After this carburizing treatment, the surface is hardened by quenching.

【0007】[0007]

【発明が解決しようとする課題】従来の鋼の表面硬化法
には、以下の問題があった。
The conventional method for hardening steel has the following problems.

【0008】(1)焼入れでは、例えば高炭素鋼に焼入
れした場合、全体が硬化して脆く、疲労強度が低下する
問題があった。
(1) In quenching, for example, when quenched into high carbon steel, there is a problem that the whole hardens and becomes brittle, and the fatigue strength decreases.

【0009】また、焼入れによる急冷操作によって生じ
る熱ひずみ、変態ひずみ、変態時期のずれによるひずみ
により、被処理成品が変形し、特にプレス部品などでは
その変形の影響が大きく問題となることや、一般に焼入
れ処理の設備費が高いという問題があった。
[0009] In addition, the product to be processed is deformed due to thermal strain, transformation strain, and strain due to a shift in transformation time caused by the quenching operation due to quenching, and the effect of the deformation is a serious problem particularly in pressed parts. There is a problem that the equipment cost of the quenching process is high.

【0010】(2)窒化処理にあっては、焼入れより変
形は少ないが、用いる薬品などコストが高いほか、設備
費も高いという問題があった。
(2) In the nitriding treatment, the deformation is smaller than that of quenching, but there is a problem that the cost of chemicals used is high and the equipment cost is high.

【0011】(3)各種メッキ法では、例えば溶融メッ
キ法では、固体金属の成品を浸漬するための溶融した液
体金属が必要であるために、液体金属を常に溶融状態に
維持するための加熱設備費が高いという問題や、有害な
化学薬品を使用し、処理時に発生する有害な蒸気による
環境汚染などの公害の問題があった。
(3) In various plating methods, for example, in a hot-dip plating method, a molten liquid metal for immersing a solid metal product is required, and therefore, a heating facility for constantly maintaining the liquid metal in a molten state. There are problems such as high cost and pollution problems such as environmental pollution due to harmful vapor generated during processing using harmful chemicals.

【0012】(4)また、浸炭処理にあっては、脱炭層
となる浸炭異常層の発生の可能性及び設備費が高いこと
に加え、処理作業に専門的な知識を必要とすることや爆
発の危険性があった。
(4) In the case of carburizing, in addition to the high possibility of occurrence of an abnormal carburizing layer serving as a decarburized layer and high equipment costs, special knowledge is required for the processing operation, and explosion occurs. There was a danger.

【0013】本発明は、途上の問題点を解決するために
開発されたもので、比較的安価な設備でしかも常温処理
によって、炭素元素を被処理成品の表面に拡散させ、被
処理成品の耐摩耗性、疲労強度を向上させることができ
る常温浸炭処理方法を提供することを目的とする。
The present invention has been developed in order to solve the problems in the course of the process. The carbon element is diffused to the surface of the article to be treated by relatively inexpensive equipment and at ordinary temperature, and the resistance of the article to be treated is improved. It is an object of the present invention to provide a room temperature carburizing method capable of improving abrasion and fatigue strength.

【0014】[0014]

【課題を解決するための手段】上記目的を達成するため
に、本発明の常温浸炭処理方法は、例えば炭素鋼又は特
殊鋼又はこれらの混合体から成る被処理成品の表面に、
好ましくは、該被処理成品よりも高硬度且つ高融点の、
炭化物粉体を噴射し、前記炭化物粉体中の炭素元素を被
処理成品の表面に拡散させることを特徴とする。
In order to achieve the above object, the cold carburizing method of the present invention is applied to a surface of a product to be treated made of, for example, carbon steel or special steel or a mixture thereof.
Preferably, higher hardness and higher melting point than the article to be treated,
The method is characterized in that a carbide powder is sprayed to diffuse a carbon element in the carbide powder to a surface of a product to be treated.

【0015】また、前記炭化物粉体の噴射を、噴射速度
80m/sec 以上又は噴射圧力0.3MPa 以上で行うこと
が好ましい。
Preferably, the carbide powder is injected at an injection speed of 80 m / sec or more or an injection pressure of 0.3 MPa or more.

【0016】前記被処理成品は、広く金属材料として、
鉄鋼材料、アルミニウムなど非鉄金属材料から成るもの
を含み、含有炭素量が約0.15%以下の低炭素鋼又は
低炭素量の特殊鋼とすると、被処理成品の耐摩耗性向上
などの効果が顕著となる。さらに、既知の浸炭処理によ
る浸炭異常層の脱炭層を対象として浸炭処理が可能であ
る。
The article to be treated is widely used as a metal material,
Including low-carbon steel with a carbon content of about 0.15% or less or special steel with a low carbon content, including those made of non-ferrous metal materials such as steel and aluminum, the effect of improving the wear resistance of the product to be treated can be improved. Will be noticeable. Further, carburizing can be performed on a decarburized layer of an abnormal carburized layer by a known carburizing process.

【0017】なお、ここで例示される炭素鋼とは、鉄と
炭素の合金で炭素含有量が通常0.02〜約2%の鋼を
いい、少量のけい素、マンガン、りん、硫黄などを含む
ものであり、特殊鋼とは炭素鋼の中に特殊元素がはいっ
て、特殊な性質を示すようになった鋼であって、合金
鋼、工具鋼、特殊用途鋼などを含むものである。
The carbon steel exemplified here is an alloy of iron and carbon and usually has a carbon content of 0.02% to about 2%, and a small amount of silicon, manganese, phosphorus, sulfur, etc. The special steel is a steel in which a special element is inserted into carbon steel to exhibit special properties, and includes alloy steel, tool steel, special use steel, and the like.

【0018】また、炭化物粉体とは、例えば、B4C 、Si
C 、好ましくは、SiC(α)、TiC 、VCなどの炭化物の粉
末をいい、平均粒径が80μm 〜平均粒径が300μm
の粉末、実施に応じて、好ましくは、平均粒径が80μ
m 以下の微粉を用いる。
The carbide powder is, for example, B 4 C, Si
C, preferably, a powder of a carbide such as SiC (α), TiC, or VC, having an average particle size of 80 μm to an average particle size of 300 μm
Powder, depending on the implementation, preferably the average particle size is 80μ
Use fine powder of m or less.

【0019】[0019]

【発明の実施の形態】金属材料から成る被処理成品の表
面に、炭化物粉体を高速で噴射すると、前記粉体の被処
理成品の表面への衝突前後の速度変化により、エネルギ
ー不変の法則を考慮すると、熱エネルギーが生じる。こ
のエネルギー変換は、前記炭化物粉体が衝突した変形部
分のみで行われるので、炭化物粉体及び被処理成品の表
面付近に局部的に温度上昇が起こる。
BEST MODE FOR CARRYING OUT THE INVENTION When a carbide powder is jetted at a high speed onto the surface of a processed product made of a metal material, the law of energy invariance is obtained by a change in the speed of the powder before and after collision with the surface of the processed product. When considered, heat energy is generated. Since this energy conversion is performed only at the deformed portion where the carbide powder collides, a local temperature rise occurs near the surfaces of the carbide powder and the article to be treated.

【0020】また、温度上昇は炭化物粉体の衝突前の速
度に比例するので、前記炭化物粉体の速度を高速にする
と、前記炭化物粉体及び被処理成品の表面の温度を上昇
させることができる。このとき炭化物粉体が被処理成品
の表面で加熱され、さらには加熱分解し、前記炭化物粉
体を成す炭化物中の炭素元素が被処理成品の表面に活性
化吸着して拡散浸透するものと考えられる。
Since the temperature rise is proportional to the speed of the carbide powder before collision, increasing the speed of the carbide powder can increase the temperature of the surfaces of the carbide powder and the article to be treated. . At this time, it is considered that the carbide powder is heated on the surface of the article to be treated and further thermally decomposed, and the carbon element in the carbide forming the carbide powder is activatedly adsorbed on the surface of the article to be treated and diffuses and penetrates. Can be

【0021】したがって、本発明の常温浸炭処理方法
は、従来の表面硬化処理における浸炭処理とは異なり、
ブラスト処理により炭化物粉体を鋼である被処理成品に
衝突させたときの前記炭化物粉体の温度上昇による加熱
分解とその分解により生成した前記炭化物粉体中の炭素
元素の被処理成品表面への拡散浸透により、浸炭処理を
行うものである。
Therefore, the cold carburizing method of the present invention is different from the carburizing treatment in the conventional surface hardening treatment,
When the carbide powder collides with the steel product to be processed by blasting, the carbon powder in the carbon powder generated by the thermal decomposition and the decomposition of the carbon powder generated by the temperature rise is applied to the surface of the product to be processed. Carburizing is performed by diffusion infiltration.

【0022】なお、前記炭化物粉体が被処理成品に衝突
したときに炭化物粉体及び被処理成品が部分的に温度上
昇するとはいえ、実際は常温で処理を行うので、本発明
の浸炭処理を本明細書では「常温浸炭処理」という。
When the carbide powder collides with the article to be treated, although the temperature of the carbide powder and the article to be treated partially rises, the carburizing treatment of the present invention is carried out at room temperature. In the specification, it is referred to as “normal temperature carburizing treatment”.

【0023】より詳細に説明するために、一般に行われ
るガス浸炭処理を例に挙げると、浸炭性の雰囲気ガス
は、メタン(CH4 )、プロパン(C3H8)又はブタン(C4
H10 )の炭化水素系ガスと、空気を一定割合で混合した
ものを原料として使用する。この混合ガスを、加熱する
と吸熱反応により一酸化炭素(CO)、水素(H2) 、窒素
(N2)が発生するが、浸炭は主としてこのCOガスが次式
で表される熱解離をして生じた活性炭素が、鋼中のFeと
反応することで行われる。
To explain in more detail, taking as an example the gas carburizing process generally performed, the carburizing atmosphere gas is methane (CH 4 ), propane (C 3 H 8 ) or butane (C 4
A hydrocarbon-based gas H 10), a mixture of air at a constant rate used as a raw material. When this mixed gas is heated, carbon monoxide (CO), hydrogen (H 2 ), and nitrogen (N 2 ) are generated by an endothermic reaction. Carburization mainly involves thermal dissociation of this CO gas represented by the following formula. The activated carbon produced is reacted with Fe in the steel.

【0024】2CO=C+CO2 すなわち、鋼の表面に、COガスが単に外力や加熱その他
の物理的方法によって簡単に除去できるような物理的付
着をしただけでは、鋼中のFeとCOガスが反応を起こすこ
とはできないが、さらに熱その他のエネルギーをある一
定以上与えるとCOガスはFeの表面に活性化吸着をする。
この活性化吸着をしたCOガスは、二酸化炭素と炭素に熱
解離をし、この反応により生じた活性炭素が、Feの格子
内に拡散して浸炭現象を起こすものと考えられる。
2CO = C + CO 2 That is, if the CO gas is merely physically attached to the surface of the steel so that the CO gas can be easily removed by an external force, heating or other physical method, the Fe and CO gas in the steel will not be obtained. Cannot cause a reaction, but when heat or other energy is given for a certain amount or more, CO gas is activated and adsorbed on the surface of Fe.
It is considered that the activated adsorbed CO gas thermally dissociates into carbon dioxide and carbon, and activated carbon generated by this reaction diffuses into the lattice of Fe to cause carburization.

【0025】ここで、ガス浸炭処理において問題となる
ことは、拡散させる炭素量を目標とする濃度に制御する
ために、上記主反応の他にH2、COガス、H2O などの平衡
状態を示す副反応についても理解を深め、浸炭性雰囲気
ガスの成分と濃度との関係を把握するなど、専門的知識
を必要とすることである。
Here, a problem in the gas carburizing process is that, in order to control the amount of carbon to be diffused to a target concentration, in addition to the main reaction, the equilibrium state of H 2 , CO gas, H 2 O, etc. This requires specialized knowledge, such as deepening the understanding of the side reaction, which indicates, and understanding the relationship between the components and concentrations of the carburizing atmosphere gas.

【0026】上記の従来のガス浸炭処理における現象を
考慮すると、本発明の常温浸炭処理においては、以下に
示すような炭素の拡散現象が行われると考えられる。
In consideration of the above-described phenomenon in the conventional gas carburizing treatment, it is considered that the following carbon diffusion phenomenon occurs in the normal temperature carburizing treatment of the present invention.

【0027】例えば、炭素鋼から成る被処理成品の表面
に炭化物粉体を噴射し、被処理成品の表面に衝突させる
と跳ね返るが、衝突後は速度が遅くなる。衝突前と衝突
後の速度の比、すなわち反発係数は被処理成品の材質、
硬度により異なるが、失われた運動エネルギーは、エネ
ルギー不変の法則から、音以外にその大部分は熱エネル
ギーに変換される。熱エネルギーは衝突時に被処理成品
の衝突部が変形することによる内部摩擦と考えられる
が、噴射された炭化物粉体が衝突した変形部分のみで熱
交換が行われるので、部分的には高温になる。このとき
炭化物粉体が、被処理成品の表面で加熱されるために熱
分解し、炭化物粉体中の活性炭素が被処理成品に活性化
吸着し、拡散するものと考えられる。
For example, when carbide powder is sprayed on the surface of a product to be treated made of carbon steel and collides with the surface of the product to be treated, the powder rebounds, but after the collision, the speed is reduced. The ratio of the speed before and after the collision, that is, the coefficient of restitution is the material of the product to be treated,
Depending on the hardness, the lost kinetic energy is largely converted to thermal energy other than sound from the law of energy invariance. Thermal energy is considered to be internal friction due to deformation of the collision part of the product to be processed at the time of collision, but heat is exchanged only at the deformed part where the injected carbide powder collided, so the temperature becomes partially high . At this time, it is considered that the carbide powder is thermally decomposed because it is heated on the surface of the article to be treated, and activated carbon in the carbide powder is activatedly adsorbed and diffused into the article to be treated.

【0028】なお、本発明では被処理成品の表面を加熱
して熱処理することではなく、むしろ噴射される炭化物
粉体が加熱されて熱分解反応を起こし、生じた炭素元素
が被処理成品の表面に活性化吸着することを目的とする
ので、したがって、炭化物粉体は、被処理成品よりも高
硬度且つ高融点である必要がある。逆に、被処理成品の
表面を熱処理する場合には、被処理成品よりも高硬度か
つ高融点である粉体を用いる必要があり、例えば前記粉
体として炭化物粉体を用いた場合には、炭化物粉体が熱
分解せずに被処理成品表面内部に食い込み、分散するも
のと考えられる。
In the present invention, the surface of the article to be treated is not heat-treated by heating, but rather, the injected carbide powder is heated to cause a thermal decomposition reaction, and the generated carbon element is removed from the surface of the article to be treated. Therefore, the carbide powder needs to have a higher hardness and a higher melting point than the product to be treated. Conversely, when heat-treating the surface of the article to be treated, it is necessary to use a powder having a higher hardness and a higher melting point than the article to be treated.For example, when using a carbide powder as the powder, It is considered that the carbide powder does not thermally decompose, but penetrates and disperses inside the surface of the article to be treated.

【0029】また、本発明で用いる炭化物粉体は前述の
通り炭化物から成り、この炭化物は一般に金属に比べ密
度が低いために(例 SiC:3.2g/cm3、B4C:2.5g/cm3)被
処理成品に対して高速で噴射しても衝突時の変形は少な
いため、本発明にあっては、被処理成品全体を高温に加
熱する必要のある従来のガス浸炭処理方法などに比べ被
処理成品の変形が少なく、浸炭処理が可能である。
As described above, the carbide powder used in the present invention is composed of carbide, which is generally lower in density than metal (eg, SiC: 3.2 g / cm 3 , B 4 C: 2.5 g / cm 3) . 3 ) Deformation at the time of collision is small even if it is injected at high speed to the product to be treated. Therefore, in the present invention, compared to the conventional gas carburizing method that requires heating the whole product to be processed to a high temperature, etc. Deformation of the product to be treated is small and carburizing is possible.

【0030】〔ブラスト装置〕ブラスト装置はエア式で
あれば直圧式、吸込式の重力式、あるいは他のブラスト
装置でも良いが、ここでは、直圧式のブラスト装置につ
いて説明する。
[Blasting Apparatus] The blasting apparatus may be a direct pressure type, a suction type gravity type, or another blasting apparatus as long as it is an air type. Here, the direct pressure type blasting apparatus will be described.

【0031】図1及び図2において、51はブラスト装
置50のキャビネットで、被処理成品を投入する投入口
53を備え、この投入口53から投入した被処理成品に
研磨材を噴射する噴射ノズル52をキャビネット51内
に設けている。
In FIG. 1 and FIG. 2, reference numeral 51 denotes a cabinet of a blasting device 50, which is provided with a charging port 53 for charging a product to be processed, and an injection nozzle 52 for spraying an abrasive onto the product to be processed supplied from the charging port 53. Are provided in the cabinet 51.

【0032】また、前記キャビネット51の下部にはホ
ッパ58が設けられ、ホッパ58の最下端は導管55を
介してキャビネット51の近くに設置された研磨材回収
用の回収タンク40の上部に連通する。
A hopper 58 is provided at a lower portion of the cabinet 51, and a lowermost end of the hopper 58 communicates with an upper portion of a collection tank 40 for collecting abrasives installed near the cabinet 51 via a conduit 55. .

【0033】回収タンク40はいわゆるサイクロンで、
粉塵を研磨材から分離する装置であり、図1に示すよう
に、上部に円筒形状を成す円筒部41と、下部に下方に
向けて徐々に狭くなる円錐形状を成す円錐部42とから
成るタンクで、回収タンク40の円筒部41の上部の側
壁に流入口43を設け、この流入口43に連通管45を
介して導管55を連結する。なお、前記連通管45の軸
線方向は円筒部41の横断面円形を成す内壁面の接線方
向に位置しているので、連通管45を経て回収タンク4
0内に流入した気流は円筒部41の内壁に沿って回りな
がら降下してゆくのである。
The recovery tank 40 is a so-called cyclone.
As shown in FIG. 1, a tank for separating dust from an abrasive material, comprising a cylindrical portion 41 having a cylindrical shape at an upper portion, and a conical portion 42 having a conical shape gradually narrowing downward at a lower portion. Then, an inlet 43 is provided on the upper side wall of the cylindrical portion 41 of the recovery tank 40, and a conduit 55 is connected to the inlet 43 via a communication pipe 45. The axial direction of the communication pipe 45 is tangential to the inner wall surface of the cylindrical portion 41 having a circular cross section.
The airflow that has flowed into the space 0 descends while rotating along the inner wall of the cylindrical portion 41.

【0034】また、回収タンク40の円錐部42の下端
は、ダンプバルブ46を介して研磨材圧送用のタンク4
7に開閉自在に連通しており、このタンク47の下端に
は噴射ノズル52から噴射する研磨材の噴射量を調整す
る研磨材調整器48を備え、該研磨材調整器48から管
54を介して前記噴射ノズル52に連通している。
The lower end of the conical portion 42 of the collection tank 40 is connected to a tank 4 for pumping the abrasive through a dump valve 46.
The tank 47 is provided at its lower end with an abrasive adjuster 48 at the lower end of the tank 47 for adjusting the amount of abrasive abrasive injected from the injection nozzle 52. And is in communication with the injection nozzle 52.

【0035】直圧式ブラスト装置の特徴は、前記タンク
47内に圧縮空気を送り込むと、タンク47の下部の研
磨材調整器48より前記圧縮空気によって研磨材が圧縮
空気と共に圧送され、管54内を噴射ノズル52の方向
に向けて送給され、噴射ノズル52から研磨材が圧縮空
気と共にキャビネット51内の被処理成品へ噴射され
る。
The feature of the direct pressure type blasting apparatus is that when compressed air is fed into the tank 47, the abrasive is sent together with the compressed air by the compressed air from the abrasive adjuster 48 at the lower part of the tank 47, and the inside of the pipe 54 is fed. The abrasive is fed toward the injection nozzle 52, and the abrasive is injected from the injection nozzle 52 together with the compressed air to the product to be processed in the cabinet 51.

【0036】前記ダンプバルブ46は、図示せざるフッ
トスイッチ又はマイクロスイッチに連動する電磁弁の作
動により上下動し、このダンプバルブ46の上下動によ
り回収タンク40とタンク47間を開閉するよう構成し
ている。前記フットスイッチ又はマイクロスイッチを作
動すると、前記ダンプバルブ46が上がり、回収タンク
40とタンク47間を遮断すると同時にタンク47内に
圧縮空気が充満し、タンク47内の研摩材が圧縮空気に
押圧されて研磨材調整器48内に流入し、この研磨材調
整器48内で圧縮空気と研磨材とが適当に混合され研磨
材供給口49を経て図示せざる管を介して噴射ノズル5
2から噴射される。
The dump valve 46 is configured to move up and down by the operation of an electromagnetic valve linked to a foot switch or micro switch (not shown), and to open and close the collection tank 40 and the tank 47 by the up and down movement of the dump valve 46. ing. When the foot switch or the micro switch is actuated, the dump valve 46 is raised to shut off the space between the collection tank 40 and the tank 47, and at the same time, the compressed air is filled in the tank 47, and the abrasive in the tank 47 is pressed by the compressed air. Then, the compressed air and the abrasive are mixed appropriately in the abrasive adjuster 48, and the spray nozzle 5 passes through a pipe (not shown) through an abrasive supply port 49.
Injected from 2.

【0037】次に、前記スイッチを元に戻すと、ダンプ
バルブ46が下がり回収タンク40とタンク47間を開
放しタンク47内の圧縮空気が回収タンク40内に逃げ
出しタンク47内の圧力が大気圧になる。タンク47内
が大気圧になる直前に、ダンプバルブ46が下がると直
ちに噴射ノズル52から研摩材の噴射が止まり、同時に
回収タンク40の底部に集積されている研磨材が一気に
タンク47内へ落下する。
Next, when the switch is returned to its original position, the dump valve 46 is lowered to open the space between the collection tank 40 and the tank 47, and the compressed air in the tank 47 escapes into the collection tank 40, and the pressure in the tank 47 becomes atmospheric pressure. become. Immediately before the pressure in the tank 47 becomes the atmospheric pressure, when the dump valve 46 is lowered, the injection of the abrasive is stopped from the injection nozzle 52 immediately, and at the same time, the abrasive accumulated at the bottom of the collection tank 40 falls into the tank 47 at a stretch. .

【0038】一方、回収タンク40の上端壁面の略中央
には連結管44が設けられ、この連結管44は排出管5
7を介してダストコレクタ56に連通している。
On the other hand, a connecting pipe 44 is provided substantially at the center of the upper end wall of the recovery tank 40, and this connecting pipe 44
7, and communicates with the dust collector 56.

【0039】ダストコレクタ56は排風機59を回転し
ダストコレクタ56内の空気を外気へ放出している。こ
の排風機59によりブラスト装置50のキャビネット5
1、導管55、回収タンク40内がそれぞれ負圧にな
り、また図示せざる圧縮機から供給された圧縮空気が研
磨材と共に噴射ノズル52から噴射されるので、キャビ
ネット51から順に導管55、回収タンク40、ダスト
コレクタ56へ気流が流れる。
The dust collector 56 rotates the exhaust fan 59 to discharge the air in the dust collector 56 to the outside air. The air blower 59 causes the cabinet 5 of the blast device 50
1, the inside of the conduit 55 and the collection tank 40 become negative pressure, and the compressed air supplied from the compressor (not shown) is jetted from the jet nozzle 52 together with the abrasive. 40, an air current flows to the dust collector 56.

【0040】〔実施例1〕上記のブラスト装置50を用
いて、被処理成品として炭素含有量が0.12%以下の
低炭素鋼であるSPCCを投入口53からキャビネット
51内のバレル64へ投入し、研磨材として炭化物であ
るSiC から成る炭化物粉体を用いて、表1に示す加工条
件で、前記研摩材を噴射ノズル52より前記被処理成品
の表面へ噴射してブラスト加工を行った。
[Example 1] Using the above-mentioned blasting device 50, SPCC, which is a low-carbon steel having a carbon content of 0.12% or less as a product to be treated, is charged from a charging port 53 into a barrel 64 in the cabinet 51. Then, blasting was performed by spraying the abrasive onto the surface of the workpiece using a spray nozzle 52 under the processing conditions shown in Table 1, using a carbide powder made of SiC, which is a carbide, as an abrasive.

【0041】[0041]

【表1】 [Table 1]

【0042】また、上記実施例1の比較例1として、前
述の本出願人による「金属成品の表面加工熱処理法」を
用いて、被処理成品としてSPCCを表2に示す加工条
件でブラスト加工した。
As Comparative Example 1 of Example 1 above, SPCC was blast-processed as a product to be treated under the processing conditions shown in Table 2 by using the above-mentioned “metal surface treatment and heat treatment method” by the present applicant. .

【0043】[0043]

【表2】 [Table 2]

【0044】さらに、上記実施例1の処理後さらに比較
例1の処理工程を経たものを比較例2とした。
Further, after the processing of the above-mentioned Example 1, the processing steps of the comparative example 1 were further performed to obtain a comparative example 2.

【0045】上記実施例1、比較例2及び比較例2によ
り処理した被処理成品の表面硬度を測定した結果を表3
に示す。
Table 3 shows the results of the measurement of the surface hardness of the articles treated according to Example 1, Comparative Example 2 and Comparative Example 2.
Shown in

【0046】[0046]

【表3】 [Table 3]

【0047】表3の結果より、本発明の常温浸炭処理方
法で処理した実施例1では、被処理成品の表面に炭素が
拡散し浸炭しており、表面硬度が増加していることがわ
かる。よって、被処理成品自体の耐摩耗性、疲労強度が
増加していると考えられる。
From the results shown in Table 3, it can be seen that in Example 1, which was treated by the normal temperature carburizing method of the present invention, carbon diffused and carburized on the surface of the product to be treated, and the surface hardness increased. Therefore, it is considered that the abrasion resistance and the fatigue strength of the processed product itself are increased.

【0048】〔実施例2〕次いで、被処理成品として炭
素含有量が0.10%以下の低炭素鋼であるSPHEを
用いて、表4に示す加工条件にてブラスト加工を行っ
た。
Example 2 Next, blasting was performed under the processing conditions shown in Table 4 using SPHE which is a low-carbon steel having a carbon content of 0.10% or less as a product to be treated.

【0049】[0049]

【表4】 [Table 4]

【0050】また、上記実施例2の比較例3として、比
較例2と同様に「金属成品の表面熱処理法」により、表
5に示す加工条件によりSPHEをブラスト加工した。
Further, as Comparative Example 3 of Example 2 above, SPHE was blasted under the processing conditions shown in Table 5 by the “metal surface heat treatment method” in the same manner as in Comparative Example 2.

【0051】[0051]

【表5】 [Table 5]

【0052】以上の実施例2及び比較例3にて処理した
被処理成品表面の硬度及び含有炭素量を測定した結果を
表6に示す。
Table 6 shows the results of the measurement of the hardness and the carbon content of the surface of the product to be treated in Example 2 and Comparative Example 3 described above.

【0053】[0053]

【表6】 [Table 6]

【0054】表6の結果より、実施例2及び比較例3共
に表面硬度は増加してるが、本発明の常温浸炭処理方法
による実施例2では、SiC 中の炭素がSPHEの表面に
拡散し、浸炭処理が行われているので含有炭素量も増加
し、その分硬度も増加していることがわかる。
From the results shown in Table 6, although the surface hardness was increased in both Example 2 and Comparative Example 3, in Example 2 by the cold carburizing method of the present invention, carbon in SiC diffused to the surface of SPHE, It can be seen that the carbon content is increased due to the carburizing treatment, and the hardness is increased accordingly.

【0055】[0055]

【発明の効果】(1)比較的安価でしかも公害の発生の
可能性が低いブラスト加工により、短時間で浸炭処理を
行え、鋼成品の耐摩耗性及び疲労強度の増加を可能にし
た。
(1) Carburizing treatment can be performed in a short time by blast processing which is relatively inexpensive and has a low possibility of generating pollution, thereby increasing the wear resistance and fatigue strength of a steel product.

【0056】(2)被処理成品全体を加熱する必要がな
く常温で処理でき、また、使用する炭化物粉体も比較的
低密度な炭化物であるので、被処理成品の変形が少な
く、不良率の低下及び品質が向上した。
(2) It is not necessary to heat the whole product to be processed, and it can be processed at normal temperature. Also, since the carbide powder to be used is a relatively low-density carbide, the product to be processed is less deformed and the defect rate is lower. Deterioration and quality improved.

【0057】(3)また、2次処理として従来の熱処理
法を行うことにより、より一層の効果を高めることがで
きた。
(3) Further effects can be further enhanced by performing a conventional heat treatment as the secondary treatment.

【図面の簡単な説明】[Brief description of the drawings]

【図l】本発明の実施例に用いるブラスト装置を示す正
面図である。
FIG. 1 is a front view showing a blast device used in an embodiment of the present invention.

【図2】本発明の実施例に用いるブラスト装置を示す平
面図である。
FIG. 2 is a plan view showing a blast device used in an embodiment of the present invention.

【符号の説明】[Explanation of symbols]

40 回収タンク 41 円筒部 42 円錐部 43 流入口 44 連結管 45 連通管 46 ダンプバルブ 47 タンク 48 研磨材調整器 50 ブラスト装置 51 キャビネット 52 噴射ノズル 53 投入口 54 管 55 導管 56 ダストコレクタ 57 排出管 58 ホッパ 59 排風機 Reference Signs List 40 Collection tank 41 Cylindrical part 42 Conical part 43 Inflow port 44 Connecting pipe 45 Communication pipe 46 Dump valve 47 Tank 48 Abrasive conditioner 50 Blasting device 51 Cabinet 52 Injection nozzle 53 Inlet 54 Pipe 55 Pipe 55 Duct 56 Dust collector 57 Discharge pipe 58 Hopper 59 exhaust fan

Claims (4)

【特許請求の範囲】[Claims] 【請求項1】金属材料から成る被処理成品の表面に、炭
化物粉体を噴射し、前記炭化物粉体中の炭素元素を被処
理成品の表面に拡散させることを特徴とする常温浸炭処
理方法。
1. A cold carburizing method comprising: spraying a carbide powder on a surface of an article to be treated made of a metal material; and diffusing a carbon element in the carbide powder to the surface of the article to be treated.
【請求項2】前記炭化物粉体の噴射を、噴射速度80m/
sec 以上又は噴射圧力0.3MPa 以上で行うことを特徴
とする請求項1記載の常温浸炭処理方法。
2. The injection of said carbide powder is performed at an injection speed of 80 m /
The room-temperature carburizing method according to claim 1, wherein the method is performed at a pressure of at least sec or a pressure of at least 0.3 MPa.
【請求項3】前記被処理成品を、含有炭素量が約0.1
5%以下の低炭素鋼又は低炭素量の特殊鋼とし、前記炭
化物粉体を前記被処理成品よりも高硬度且つ高融点とす
る請求項1又は2記載の常温浸炭処理方法。
3. The method according to claim 1, wherein the material to be treated has a carbon content of about 0.1.
The room temperature carburizing method according to claim 1 or 2, wherein the carbon powder is made of a low carbon steel or a special steel having a low carbon content of 5% or less and has a higher hardness and a higher melting point than the target product.
【請求項4】前記炭化物粉体は、SiC好ましくはSiC(α)
とする請求項1〜3いづれか1記載の常温浸炭処理方
法。
4. The method according to claim 1, wherein the carbide powder is SiC, preferably SiC (α).
The normal temperature carburizing method according to any one of claims 1 to 3.
JP11360198A 1998-04-23 1998-04-23 Room temperature carburizing method Expired - Lifetime JP3242060B2 (en)

Priority Applications (1)

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JP11360198A JP3242060B2 (en) 1998-04-23 1998-04-23 Room temperature carburizing method

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Application Number Priority Date Filing Date Title
JP11360198A JP3242060B2 (en) 1998-04-23 1998-04-23 Room temperature carburizing method

Publications (2)

Publication Number Publication Date
JPH11302826A true JPH11302826A (en) 1999-11-02
JP3242060B2 JP3242060B2 (en) 2001-12-25

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Country Link
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