[go: up one dir, main page]
More Web Proxy on the site http://driver.im/

JPH051321A - Production of high strength bolt excellent in delayed fracture resistance and fatigue characteristic - Google Patents

Production of high strength bolt excellent in delayed fracture resistance and fatigue characteristic

Info

Publication number
JPH051321A
JPH051321A JP15174191A JP15174191A JPH051321A JP H051321 A JPH051321 A JP H051321A JP 15174191 A JP15174191 A JP 15174191A JP 15174191 A JP15174191 A JP 15174191A JP H051321 A JPH051321 A JP H051321A
Authority
JP
Japan
Prior art keywords
bolt
steel
strength
bolts
delayed fracture
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.)
Pending
Application number
JP15174191A
Other languages
Japanese (ja)
Inventor
Toshimitsu Kimura
利光 木村
Kazuo Yanagihara
和夫 柳原
Kunio Namiki
邦夫 並木
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.)
Daido Steel Co Ltd
Original Assignee
Daido Steel 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 Daido Steel Co Ltd filed Critical Daido Steel Co Ltd
Priority to JP15174191A priority Critical patent/JPH051321A/en
Publication of JPH051321A publication Critical patent/JPH051321A/en
Pending legal-status Critical Current

Links

Landscapes

  • Forging (AREA)
  • Heat Treatment Of Articles (AREA)

Abstract

PURPOSE:To improve delayed fracture resistance and fatigue strength by using a boron compound as a lubricant at the time of wiredrawing and also adopting atmospheric conditions of slight-degree decarburizing-extremely-slight-degree carburizing at the time of heat treatment after working. CONSTITUTION:A lubricating film composed essentially of boron compound is formed on the surface of a wire rod of steel for bolt containing 0.20-0.45% carbon, which is wiredrawn, formed into a bolt, and subjected to quench-and- temper treatment. By controlling carbon potential in a hardening atmosphere, carbon concentration in the vicinity of the surface of the bolt after heat treatment is controlled to a fluctuations in the range of -0.15 to +0.02% based on the carbon content in the steel, by which tensile strength can be regulated to 1200-1600N/mm<2>. By this method, a risk of phosphorizing due to conventional phosphate film can be removed, and an effect of improvement in the intergranular binding power of boron compound and also a hardening- supplementing effect can be used.

Description

【発明の詳細な説明】Detailed Description of the Invention

【0001】[0001]

【産業上の利用分野】本発明は、耐遅れ破壊性と疲労特
性のすぐれたボルトの製造方法に関する。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of manufacturing a bolt having excellent delayed fracture resistance and fatigue characteristics.

【0002】[0002]

【従来の技術】自動車や各種産業機械の小型化、軽量
化、さらには高出力化の傾向により、部品を締結するボ
ルトに対しても負荷が大きくなって、強度を高める必要
が生じている。 そこで、ボルトの材料としては一般
に、JISの強靱鋼のカテゴリーに属するSCM43
5,SCM440,SCR440などが使用されてい
る。
2. Description of the Related Art Due to the trend toward smaller size, lighter weight and higher output of automobiles and various industrial machines, the bolts for fastening parts are also subject to a large load and need to be strengthened. Therefore, as a material for bolts, SCM43, which generally belongs to JIS tough steel category, is generally used.
5, SCM440, SCR440, etc. are used.

【0003】ところが、これらの鋼のボルトにおいて、
引張強さを1200N/mm2以上に高めると、遅れ破
壊を生じる危険が出てくるため、保安上重要な部分に高
強度ボルトを使用できない。
However, in these steel bolts,
If the tensile strength is increased to 1200 N / mm 2 or more, there is a risk of delayed fracture, so high-strength bolts cannot be used in important parts for safety.

【0004】ボルトの材料とする線材の製造に当って
は、多くの場合、リン酸塩被膜を潤滑剤として利用した
伸線加工を行なう。 リン酸塩が付着したままの鋼を焼
入れ温度に保持すると、鋼の表面からPが侵入する侵リ
ン現象が起り、侵入したPはボルトの表面近くの粒界の
結合力を弱めるため、使用中に遅れ破壊が生じる可能性
が高い。 従って、焼入れ前にリン酸塩の被膜を除去し
なければならない。
In the production of wire rods, which are the materials for bolts, in many cases, wire drawing using a phosphate coating as a lubricant is carried out. If the steel with the phosphate adhered is kept at the quenching temperature, the phosphorus invasion phenomenon that P invades from the surface of the steel occurs, and the invading P weakens the binding force of the grain boundary near the surface of the bolt, so during use There is a high possibility that delayed destruction will occur. Therefore, the phosphate coating must be removed before quenching.

【0005】一方、ボルトの表面を脱炭させることによ
り軟化させ、遅れ破壊に対する感受性を低下させること
が試みられている。 しかし、脱炭がごく軽微である
と、上記の侵リンによる遅れ破壊は防げないし、過度に
なれば、表面の軟化域で容易に疲労亀裂が発生してそれ
が伝播する結果、疲労強度が低下するという別の問題が
出てくる。
On the other hand, attempts have been made to reduce the susceptibility to delayed fracture by decarburizing the surface of the bolt to soften it. However, if decarburization is extremely slight, delayed fracture due to the above phosphorus cannot be prevented, and if it becomes excessive, fatigue cracks easily occur in the softened area of the surface and it propagates, resulting in reduced fatigue strength. Another problem of doing it comes out.

【0006】高強度ボルトにおいて、浸炭は避けるべき
ものとされている。 侵リンを受けなかったボルトで
も、比較的軽い浸炭で耐遅れ破壊性は劣るというのが常
識である。
In high-strength bolts, carburizing should be avoided. It is common knowledge that even bolts that have not been subjected to phosphorus infiltration are inferior in delayed fracture resistance due to relatively light carburization.

【0007】出願人は、ボルトの耐遅れ破壊性を改善す
るためのひとつの方策として、特定の合金成分を選択
し、これに500℃以上の高温焼もどしを組み合わせる
ことを提案した(特開昭61−130456)。
[0007] The applicant has proposed, as one measure for improving the delayed fracture resistance of bolts, to select a specific alloy component and combine it with a high temperature tempering of 500 ° C or more (Japanese Patent Laid-Open No. Sho 6-96). 61-130456).

【0008】その後の研究の結果、耐遅れ破壊性の向上
にとって、伸線加工時の潤滑被膜の選択と焼入時の雰囲
気が重要であることを見出した。 また、多くの場合に
転造技術によって行なっているねじ部の成形を、熱処理
前の粗加工と、熱処理後の仕上げ加工とに分けて行なう
のが有利であることを知った。
As a result of subsequent research, it was found that the selection of the lubricating coating during wire drawing and the atmosphere during quenching are important for improving delayed fracture resistance. Further, it has been found that it is advantageous to form the threaded portion, which is performed by the rolling technique in many cases, separately in the roughing process before the heat treatment and the finishing process after the heat treatment.

【0009】[0009]

【発明が解決しようとする課題】本発明の目的は、上記
した知見を生かし、侵リンがひきおこす危険を原理的に
なくし、耐遅れ破壊性と疲労強度を向上させた高強度ボ
ルトの製造方法を提供することにある。
SUMMARY OF THE INVENTION An object of the present invention is to provide a method for producing a high strength bolt, which makes use of the above-mentioned findings and in principle eliminates the risk of phosphorus invasion and improves delayed fracture resistance and fatigue strength. To provide.

【0010】[0010]

【課題を解決するための手段】本発明の耐遅れ破壊性と
疲労強度のすぐれた高強度ボルトの製造方法は、0.2
0〜0.45%の炭素を含有するボルト用鋼の線材の表
面にホウ素化合物を主成分とする潤滑被膜を形成し、伸
線加工した後、そのままボルトに成形加工して焼入れ・
焼戻し処理を施し、その際、熱処理後のボルト表面近傍
における炭素濃度の鋼中の炭素含有量に対する変動が−
0.15〜+0.02%の範囲に止まるように雰囲気を
制御して熱処理を行ない、それによって引張強さを12
00〜1600N/mm2に調節することからなる。
A method of manufacturing a high strength bolt having excellent delayed fracture resistance and fatigue strength according to the present invention is 0.2
After forming a lubricating coating containing a boron compound as the main component on the surface of a steel wire for bolts containing 0 to 0.45% carbon, wire drawing is performed, and then the bolts are directly processed into quenching.
When tempering is applied, the carbon concentration in the vicinity of the bolt surface after heat treatment varies with the carbon content in the steel.
The heat treatment is performed by controlling the atmosphere so that the tensile strength is 12 to 12 in the range of 0.15 to + 0.02%.
It consists of adjusting to 0 to 1600 N / mm 2 .

【0011】この種のボルトのねじ部の成形は、通常は
転造技術によって行なわれており、本発明においても転
造は有利に実施できる。 焼入れ前の転造だけで所望の
ねじ部を得るのに不足な場合、または特別に精密なねじ
部を形成したい場合には、焼入れ・焼戻し後に仕上げの
ための転造を行なうとよい。
The thread portion of this type of bolt is usually formed by a rolling technique, and the rolling can be advantageously performed in the present invention. If it is insufficient to obtain the desired threaded portion only by rolling before quenching, or if it is desired to form a particularly precise threaded portion, rolling for finishing may be performed after quenching and tempering.

【0012】潤滑被膜として利用するホウ素化合物は、
ホウ酸、ホウ酸ナトリウム、ホウ酸カリウムなどを使用
すればよい。 ホウ砂すなわちホウ酸ナトリウム10水
塩が、安価に入手でき、加工温度でガラス化して良好な
潤滑性能を示す点で、好適である。
The boron compound used as the lubricating coating is
Boric acid, sodium borate, potassium borate or the like may be used. Borax, that is, sodium borate decahydrate, is preferable in that it can be obtained at a low cost and vitrifies at a processing temperature to exhibit good lubricating performance.

【0013】熱処理後のボルトの表面近傍の炭素濃度を
鋼中の炭素含有量に対して−0.15〜+0.02%の
変動に抑えるには、焼入れの雰囲気のカーボンポテンシ
ャルを制御すればよい。
In order to keep the carbon concentration near the surface of the bolt after heat treatment within a range of −0.15 to + 0.02% with respect to the carbon content in steel, the carbon potential of the quenching atmosphere may be controlled. .

【0014】ボルト用鋼は、C:0.20〜0.45%
を含有するものであれば種々の鋼種が使用可能である
が、代表的なものは、SCMおよびSCRのうちC含有
量が上記の範囲の鋼である。
Steel for bolts contains C: 0.20 to 0.45%
Various steel types can be used as long as they contain C, but a typical one is a steel having a C content in the above range among SCM and SCR.

【0015】[0015]

【作用】前述のように、伸線加工時の潤滑剤としてリン
酸塩を使用することは、侵リンの危険があり原理的に好
ましくないから、本発明ではこれに代えてホウ素化合物
を採用した。 ホウ素化合物による潤滑は、リンを排除
するだけでなく、伸線後の成形加工や熱処理時にも潤滑
被膜を残存させておくことによって、ボルト表層に微量
のBが侵入して粒界の結合力を高めるとともに、表層部
の焼入性を増強するはたらきがある。 侵入したBが粒
界の結合力を高める機構は、鋼中に残存する不純物たと
えばPの析出を抑えることにあると考えられる。
As described above, the use of phosphate as a lubricant during wire drawing is not preferable in principle because of the risk of phosphorus penetration. Therefore, in the present invention, a boron compound is used instead. . Lubrication by a boron compound not only eliminates phosphorus, but also leaves a lubricating coating during molding and heat treatment after wire drawing, so that a trace amount of B penetrates into the bolt surface layer to improve the bond strength of grain boundaries. It has the function of increasing the hardenability of the surface layer as well as increasing the hardness. It is considered that the mechanism by which the invaded B enhances the bond strength of the grain boundary is to suppress the precipitation of impurities such as P remaining in the steel.

【0016】ボルトの熱処理に当って酸化性の雰囲気に
さらされると、脱炭の進行とともにSi,Mn,Cr,
Alなどの合金元素が酸化される。 それらの酸化物は
主に粒界に生成するため、疲労による亀裂の発生点を提
供し、亀裂の初期伝播を助長する危険がある。 Bは粒
界に偏析することによって、これら酸化物の粒界におけ
る析出を抑制するものと思われる。 合金元素の酸化は
マトリクス中の合金成分量を減少させ、その結果、焼入
性が低下して不完全焼入組織ができることによりボルト
表層部は軟いものになる。 Bの侵入は、この焼入性低
下を補完する。
When the bolt is heat treated and exposed to an oxidizing atmosphere, Si, Mn, Cr,
Alloying elements such as Al are oxidized. Since these oxides mainly form at grain boundaries, they provide a starting point for cracks due to fatigue, and there is a risk of promoting initial propagation of cracks. It is considered that B segregates at the grain boundaries to suppress the precipitation of these oxides at the grain boundaries. Oxidation of alloying elements reduces the amount of alloying components in the matrix, and as a result, the hardenability deteriorates and an incompletely hardened structure is formed, so that the bolt surface layer becomes soft. The invasion of B complements this decrease in hardenability.

【0017】焼入後のボルト表層部の炭素濃度を、前述
のように、鋼の炭素含有量に対する変動が−0.15%
〜+0.02%の範囲に止まるようにする意味は、軽度
の脱炭から極軽度の浸炭にわたる領域から逸脱しないと
いうことを意味する。 この限界より強い脱炭が行なわ
れると焼入性の低下が著しくなり、前記したBの侵入に
よる焼入性の補完で対処しきれなくなる。 一方、上記
の限界を超えた浸炭は、侵入したBによる粒界結合力の
向上を効果のないものとする。 こうした脱炭〜浸炭の
制御は、材料とするボルト用鋼の炭素含有量に応じて雰
囲気のカーボンポテンシャルをえらぶことにより可能で
あり、ガス浸炭の技術において知られているところに従
って実施すればよい。
As described above, the carbon concentration in the surface layer of the bolt after quenching varies by -0.15% with respect to the carbon content of steel.
The meaning of staying in the range of + 0.02% means not to deviate from the region from mild decarburization to extremely mild carburization. If decarburization stronger than this limit is carried out, the hardenability deteriorates remarkably, and it becomes impossible to deal with it by supplementing the hardenability due to the penetration of B as described above. On the other hand, carburization that exceeds the above-mentioned limit has no effect on the improvement of the grain boundary bonding force by the invading B. Such control of decarburization to carburization can be performed by selecting the carbon potential of the atmosphere according to the carbon content of the steel for bolts used as a material, and may be performed according to what is known in the art of gas carburization.

【0018】熱処理後の強度を1200N/mm2以上
に調節するのは、これが高強度ボルトとして必要とされ
る水準だからであり、1600N/mm2を上限とした
のは、これより高い強度にすると、ボルトの表面性状の
管理だけでは耐遅れ破壊性の改善が困難となるからであ
る。
The strength after heat treatment is adjusted to 1200 N / mm 2 or more because this is the level required for high strength bolts, and the upper limit of 1600 N / mm 2 is that when strength is higher than this. This is because it is difficult to improve the delayed fracture resistance only by controlling the surface properties of the bolt.

【0019】[0019]

【実施例】表1の合金組成(重量%、残部不純物および
Fe)を有する鋼の線材を用意した。 その一部は、潤
滑被膜を形成してから冷間鍛造および転造によりボルト
に成形し、別の一部は、引張試験片および遅れ破壊試験
片に機械加工してから潤滑被膜を形成し、いずれも熱処
理した。
Example A steel wire rod having the alloy composition shown in Table 1 (weight%, balance impurities and Fe) was prepared. Some of them are formed into bolts by cold forging and rolling after forming a lubricating coating, and another is formed into a lubricating coating after machining into tensile test pieces and delayed fracture test pieces, Both were heat-treated.

【0020】 表1 Si Mn Cr その他 A 0.260 0.31 0.81 1.12 Mo0.17 B 0.421 0.30 0.77 1.16 − C 0.332 0.05 0.34 1.02 Mo0.61,V0.14 D 0.379 0.11 0.29 1.25 Mo0.31,V0.31 Nb0.06 潤滑被膜は、ホウ酸ナトリウムNa247・5H2Oの
濃度200g/lの水溶液に、温度90℃で10分間浸
漬してひき上げ、風乾することによって形成した(これ
を「B系」であらわす)。 比較のため、リン酸塩系の
潤滑被膜を形成したものも用意した(これを「P系」で
あらわす)。
Table 1 Steel C Si Mn Cr Other A 0.260 0.31 0.81 1.12 Mo0.17 B 0.421 0.30 0.77 1.16-C 0.332 0.05 0. 34 1.02 Mo0.61, V0.14 D 0.379 0.11 0.29 1.25 Mo0.31, V0.31 Nb0.06 lubricating coating, sodium borate Na 2 B 4 O 7 · 5H 2 It was formed by immersing in an aqueous solution of O at a concentration of 200 g / l at a temperature of 90 ° C. for 10 minutes, pulling it up, and air-drying (this is represented by “B system”). For comparison, a product having a phosphate-based lubricating coating formed thereon was also prepared (this is referred to as "P-based").

【0021】種々の焼入れ・焼戻し温度において、かつ
脱炭〜浸炭にわたる雰囲気の下に、上記の試験片および
ボルトを熱処理した。 熱処理の条件、熱処理後の試験
片(遅れ破壊試験片)の表層部の炭素濃度と、それが鋼
中の炭素濃度に対してどのくらい変動したかを、表2に
示す。
The above test pieces and bolts were heat-treated at various quenching and tempering temperatures and under an atmosphere ranging from decarburization to carburization. Table 2 shows the heat treatment conditions, the carbon concentration in the surface layer of the test piece (delayed fracture test piece) after the heat treatment, and how much it changed with respect to the carbon concentration in the steel.

【0022】 表2 No. 鋼 被膜 焼入温度 焼戻温度 表層部 C%の差 (℃) (℃) C(%) 実施例1 A B系 870 450 0.210 −0.050 〃 2 B 〃 850 490 0.273 −0.148 〃 3 C 〃 875 600 0.294 −0.038 〃 4 D 〃 930 580 0.255 −0.077 〃 5 C 〃 890 570 0.391 +0.012 〃 6 D 〃 920 620 0.364 −0.015 比較例1 A P系 865 430 0.250 −0.010 〃 2 B 〃 855 470 0.250 −0.171 〃 3 C 〃 925 610 0.339 +0.007 〃 4 D B系 950 560 0.412 +0.033 〃 5 B 〃 870 480 0.200 −0.221 〃 6 C P系 880 520 0.299 −0.033 上記それぞれの試験片またはボルト製品について、下記
の試験を行なった。
Table 2 No. Steel film Quenching temperature Tempering temperature Surface layer C% difference (℃) (℃) C (%) Example 1 AB series 870 450 0.210 -0.050 〃 2 B 〃 850 490 0.273 -0.148 〃 3 C 〃 875 600 0.294 -0.038 〃 4 D 〃 930 580 0.255 -0.077 5 C 890 570 370 0.391 +0.012 6 D 920 620 620 0.364 -0.015 Comparative Example 1 AP type 865 430 0.250 -0.010 〃 2 B 〃 855 470 0.250-0.171 〃 3 C 〃 925 610 0.339 +0.007 〃 4 DB system 950 560 0.412 +0.033 〃 5 B 〃 870 480 0.200 -0.221 〃 6 C P system 880 520 0.299 -0.033 The following tests were performed on each of the above test pieces or bolt products.

【0023】(遅れ破壊試験)径6mm×長さ40mm
の丸棒の中央に60°の角度のV字ノッチを深さ1m
m、底部のアール0.1mmで設けたものを試験片とし
た。 このノッチ部に腐食液(0.1N−HCl)を滴
下しながら曲げ応力を負荷した。 一部の試験片に対し
ては、ノッチの底に0.1mmRの工具鋼(HRC6
0)を200kgf/mm2の圧力で押しつけ、転造加
工条件のシミュレーションとした。
(Delayed Fracture Test) Diameter 6 mm × Length 40 mm
V-shaped notch with an angle of 60 ° at the center of the round bar
The test piece was provided with m and a radius of 0.1 mm at the bottom. A bending stress was applied to the notch while dropping a corrosive liquid (0.1N-HCl). For some specimens, 0.1 mmR tool steel (HRC6
0) was pressed at a pressure of 200 kgf / mm 2 to simulate rolling processing conditions.

【0024】耐遅れ破壊性は、上記の条件で曲げ応力を
加えたときに30時間経過後に破断する応力(「30時
間強度」という)に対する、腐食液を滴下せずに曲げ応
力を加えて破断したときの応力(「靜曲げ応力」とい
う)の比をとり、遅れ破壊強度比として評価した。(値
が1に近いほど好成績といえる。) 遅れ破壊強度比=30時間強度/靜曲げ応力 (疲労試験)前記のボルトに対し、実体疲労試験機で平
均応力790N/mm2を負荷して、3×106回後に破
断しない応力振幅をもって、疲労強度の尺度とした。
Delayed fracture resistance is defined as the stress that breaks after 30 hours when a bending stress is applied under the above conditions (referred to as "30-hour strength"), when a bending stress is applied without dropping a corrosive liquid. The ratio of the stress (referred to as "bending stress") was taken and evaluated as the delayed fracture strength ratio. (The closer the value is to 1, the better the result.) Delayed fracture strength ratio = 30-hour strength / Bending stress (fatigue test) An average stress of 790 N / mm 2 was applied to the above bolts using a physical fatigue tester. The stress amplitude that does not break after 3 × 10 6 cycles was used as a measure of fatigue strength.

【0025】上記2種の試験の結果を、表3に示す。The results of the above two types of tests are shown in Table 3.

【0026】 表3 No. 転造シミュ 引張強さ 遅破壊 疲労強度 レーション (N/mm2 強度比 (N/mm2 実施例1 なし 1200 0.80 96 〃 2 〃 1280 0.81 88 〃 3 〃 1250 0.88 103 〃 4 あり 1540 0.78 125 〃 5 〃 1370 0.75 116 〃 6 なし 1410 0.84 124 比較例1 〃 1240 0.59 50 〃 2 〃 1310 0.86 34 〃 3 〃 1230 0.38 57 〃 4 〃 1580 0.31 120 〃 5 あり 1300 0.89 41 〃 6 〃 1320 0.62 64Table 3 No. Rolling simulation Tensile strength Slow fracture Fatigue strength Configuration (N / mm 2) intensity ratio (N / mm 2) Example 1 None 1200 0.80 96 〃 2 〃 1280 0.81 88 〃 3 〃 1250 0.88 103 〃 4 there 1540 0.78 125 〃 5 〃 1370 0.75 116 〃 6 None 1410 0.84 124 Comparative Example 1 〃 1240 0.59 50 〃 2 〃 1310 0.86 34 34 〃 3 〃 1230 0.38 57 〃 4 〃 5 1 80 ッ 0.31 1300 0.89 41 〃 6 〃 1320 0.62 64

【0027】[0027]

【発明の効果】本発明の高強度ボルトの製造方法は、伸
線加工時の潤滑剤として在来技術のリン酸塩に代えてホ
ウ素化合物を使用したから、侵リンの危険を原理的にな
くし、Bの侵入による粒界結合力の向上と焼入性の補完
を行ない、かつ熱処理時に軽脱炭〜極軽浸炭の雰囲気条
件を採用することによって、耐遅れ破壊性を向上し、疲
労特性を改善することに成功した。
EFFECT OF THE INVENTION In the method for producing a high strength bolt of the present invention, since a boron compound is used as a lubricant during wire drawing in place of the conventional phosphate, the risk of phosphorus penetration is eliminated in principle. , B to improve the grain boundary bond strength and complement the hardenability, and by adopting the atmosphere conditions of light decarburization to ultra-light carburization during the heat treatment, the delayed fracture resistance is improved and the fatigue property is improved. Succeeded in improving.

【0028】従ってこの製造方法は、各種強靱鋼でボル
トを製造する場合に採用して効果がある。
Therefore, this manufacturing method is effective when it is used to manufacture bolts from various tough steels.

Claims (5)

【特許請求の範囲】[Claims] 【請求項1】 0.20〜0.45%の炭素を含有する
ボルト用鋼の線材の表面にホウ素化合物を主成分とする
潤滑被膜を形成し、伸線加工した後そのままボルトに成
形加工して焼入れ・焼戻し処理を施し、その際、熱処理
後のボルト表面近傍における炭素濃度の鋼中の炭素含有
量に対する変動が−0.15〜+0.02%の範囲に止
まるように雰囲気を制御して熱処理を行ない、それによ
って引張強さを1200〜1600N/mm2に調節す
ることからなる耐遅れ破壊性と疲労特性のすぐれた高強
度ボルトの製造方法。
1. A lubricating coating containing a boron compound as a main component is formed on the surface of a steel wire for bolts containing 0.20 to 0.45% carbon, drawn and then formed into bolts as it is. Quenching and tempering treatment, while controlling the atmosphere so that the fluctuation of the carbon concentration in the vicinity of the bolt surface after heat treatment with respect to the carbon content in the steel remains within the range of -0.15 to + 0.02%. A method for producing a high-strength bolt having excellent delayed fracture resistance and fatigue properties, which comprises performing heat treatment to adjust the tensile strength to 1200 to 1600 N / mm 2 .
【請求項2】 請求項1の製造方法において、焼入れ・
焼戻し処理を行なったのち、ねじ部の仕上げ加工を行な
う工程を付加した高強度ボルト用鋼の製造方法。
2. The manufacturing method according to claim 1, wherein quenching
A method for manufacturing high-strength steel for bolts, which includes a step of finishing the threaded portion after tempering.
【請求項3】 ボルトのねじ部の成形加工および(また
は)仕上げ加工を転造により実施する請求項1または2
の高強度ボルトの製造方法。
3. The method according to claim 1, wherein the forming process and / or the finishing process of the thread portion of the bolt are performed by rolling.
Manufacturing method of high strength bolts.
【請求項4】 ホウ素化合物として、ホウ酸、ホウ酸ナ
トリウムおよびホウ酸カリウムからえらんだものを使用
する請求項1または2の高強度ボルトの製造方法。
4. The method for producing a high strength bolt according to claim 1, wherein a boron compound selected from boric acid, sodium borate and potassium borate is used.
【請求項5】 ボルト用鋼がSCMまたはSCRである
請求項1または2の高強度ボルトの製造方法。
5. The method for producing a high-strength bolt according to claim 1, wherein the bolt steel is SCM or SCR.
JP15174191A 1991-06-24 1991-06-24 Production of high strength bolt excellent in delayed fracture resistance and fatigue characteristic Pending JPH051321A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP15174191A JPH051321A (en) 1991-06-24 1991-06-24 Production of high strength bolt excellent in delayed fracture resistance and fatigue characteristic

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP15174191A JPH051321A (en) 1991-06-24 1991-06-24 Production of high strength bolt excellent in delayed fracture resistance and fatigue characteristic

Publications (1)

Publication Number Publication Date
JPH051321A true JPH051321A (en) 1993-01-08

Family

ID=15525273

Family Applications (1)

Application Number Title Priority Date Filing Date
JP15174191A Pending JPH051321A (en) 1991-06-24 1991-06-24 Production of high strength bolt excellent in delayed fracture resistance and fatigue characteristic

Country Status (1)

Country Link
JP (1) JPH051321A (en)

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
KR20020047667A (en) * 2000-12-13 2002-06-22 이계안 Method of making a stud bolt for a ball joint
US6905825B2 (en) 2001-06-05 2005-06-14 Hitachi, Ltd. Method for isolating and purifying nucleic acids
US7215788B2 (en) 1995-03-31 2007-05-08 1 . . . Limited Digital loudspeaker
KR101107018B1 (en) * 2004-05-31 2012-01-25 이케우치 세이코 컴퍼니 리미티드 High-strength bolt and manufacturing method thereof

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US7215788B2 (en) 1995-03-31 2007-05-08 1 . . . Limited Digital loudspeaker
KR20020047667A (en) * 2000-12-13 2002-06-22 이계안 Method of making a stud bolt for a ball joint
US6905825B2 (en) 2001-06-05 2005-06-14 Hitachi, Ltd. Method for isolating and purifying nucleic acids
KR101107018B1 (en) * 2004-05-31 2012-01-25 이케우치 세이코 컴퍼니 리미티드 High-strength bolt and manufacturing method thereof

Similar Documents

Publication Publication Date Title
JP2008539331A (en) Tempered martensitic steel, method for producing parts from the steel, and parts so obtained
JPH10219392A (en) Parts for induction hardening and production thereof
JPH06172867A (en) Production of gear excellent in impact fatigue life
JPH11131176A (en) Induction hardened parts and production thereof
JPH051321A (en) Production of high strength bolt excellent in delayed fracture resistance and fatigue characteristic
JP3550886B2 (en) Manufacturing method of gear steel for induction hardening excellent in machinability and fatigue strength
JPH09256102A (en) Carburized parts excellent in bending strength and impact characteristic
JPH1171654A (en) Carburized gear
JPH108189A (en) Steel for induction hardening excellent in bendability and induction hardened part excellent in bendability using the same steel
JPS5948949B2 (en) carburizing steel
JPH09241821A (en) Carburized gear
JPH01176031A (en) Manufacture of non-heattreated steel for hot forging
JP3623313B2 (en) Carburized gear parts
JP3236883B2 (en) Case hardening steel and method for manufacturing steel pipe using the same
JP3340016B2 (en) Structural steel for soft nitriding
JPH11131135A (en) Induction-hardened parts and production thereof
JP3036401B2 (en) Case hardened steel and carburized parts with excellent impact fatigue properties
JP3242336B2 (en) Cold forging steel excellent in cold forgeability and fatigue strength and method for producing cold forged member
JPH08165557A (en) Production of pitting resisting soft-nitrided gear
JP3428282B2 (en) Gear steel for induction hardening and method of manufacturing the same
JP3264790B2 (en) Drawing part having irregular cross section and method of manufacturing the same
JPS63206449A (en) Low-carbon steel for cold forging
JPH05320748A (en) Production of high strength shaft parts excellent in form rollability and machinability
JP2000309846A (en) Non-heat treated steel for soft nitriding
JPH02217421A (en) Production of spring with high fatigue strength and steel wire for use therein