JP2006028623A - Austenitic stainless steel wire rod and austenitic stainless steel bolt - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a high strength stainless steel bolt having ≥800 N/mm<SP>2</SP>tensile strength and also, excellent corrosion resistance, and a wire rod used for this production. <P>SOLUTION: The austenitic stainless steel wire rod having residual stress in the axial direction and also, 820-950 N/mm<SP>2</SP>tensile strength, is produced by applying a wire-drawing to austenitic stainless steel controlled to 550-700 N/mm<SP>2</SP>tensile strength by annealing. This wire rod is compressed in the axial direction to form the head part and the screw part is formed by applying a thread-rolling, and thus, the austenitic stainless steel bolt having ≥800 N/mm<SP>2</SP>tensile strength is obtained. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

The present invention relates to a high-strength stainless steel bolt, and more particularly to a high-strength stainless steel bolt having a tensile strength of 800 N / mm ² or more and excellent corrosion resistance and a wire used for manufacturing the same.

  When increasing the strength of stainless steel bolts, martensitic stainless steel is used and processed into a bolt shape, and then quenched and tempered to adjust to a predetermined tensile strength (for example, patents) Reference 1).

  This is based on the property that martensitic stainless steel has a higher C content because it has a higher C content than austenitic or ferritic stainless steel and can form a martensitic structure by quenching. is there. And if it uses it as it is quenched, toughness will fall, and the tempering process is implemented to predetermined | prescribed hardness. However, at that time, the martensitic structure, which is a quenched structure, is decomposed into a sorbite and troostite structure, so that the passive characteristics are lowered and the corrosion resistance is deteriorated.

Therefore, in recent years, a technique for producing a high-strength stainless steel bolt having a corrosion resistance superior to that of a martensitic bolt using an austenitic stainless steel having a corrosion resistance superior to that of a martensitic steel has been proposed (for example, a patent). Reference 2).
JP-A-9-314276 Japanese Examined Patent Publication No. 6-68284

Since austenitic stainless steel has a martensitic transformation start temperature (Ms point) much lower than room temperature, it remains metastable supercooled austenite at room temperature. Therefore, there is no quenching curability and it is impossible to increase the strength by heat treatment. Therefore, in producing a high-strength austenitic stainless steel bolt, it is necessary to harden by cold working at room temperature, but no technology for industrial mass production including economy has been found yet. The austenitic stainless steel bolt described in Patent Document 2 described above has a tensile strength of only 750 N / mm ² or less.

The present invention has been made in view of the above-described problems, and its object is to provide a high-strength stainless steel bolt having a tensile strength of 800 N / mm ² or more and excellent corrosion resistance, and a wire used for manufacturing the same. Is to provide.

In order to achieve the above object, in the austenitic stainless steel wire according to the present invention, the tensile strength is set to 550 N / mm ² or more and 700 N / mm ² or less by annealing, and then drawn in the axial direction. tensile strength and having a residual stress, characterized in that at 820N / mm ² or more 950 N / mm ² or less.

In the austenitic stainless steel bolt according to the present invention, compressing the austenitic stainless steel wire tensile strength and having an axial residual stress described above is 820N / mm ² or more 950 N / mm ² or less in the axial direction And having a threaded portion formed by rolling and a tensile strength of 800 N / mm ² or more.

  By producing a bolt using austenitic stainless steel, a bolt having better corrosion resistance than a bolt produced using martensitic stainless steel can be produced.

  However, since austenitic stainless steel cannot be strengthened by quenching and tempering like martensitic stainless steel, it must be hardened by cold working to increase its strength. At that time, the strength is increased by utilizing the characteristic that the tensile strength increases as the processing rate increases. In such a case, it is necessary to determine the processing rate so that the final bolt has a desired strength. On the other hand, since the life of the molding die is shortened as the processing rate increases, it is necessary to set the processing rate so that it can be industrially mass-produced including economy. Furthermore, when the thread portion after work hardening is rolled, the height is lowered and the tensile strength is reduced.

Therefore, the tensile strength when the producing 800 N / mm ² or more high-strength stainless bolt, first, pulling the annealing austenitic stainless steel strength was set to be 550 N / mm ² or more 700 N / mm ² or less after a predetermined working ratio (e.g., about 25%) by drawing, the tensile strength of the production of austenitic stainless steel wire rod for 820N / mm ² or more 950 N / mm ² or less is volts. Thereafter, the head is formed by compressing the wire in the axial direction and the thread portion is formed by rolling.

Here, it has been found by the inventor's research that when the threaded portion is rolled, the hardness decreases and the tensile strength decreases within a range of about 20 N / mm ² or less. Therefore, the tensile strength is rolling the screw portion while forming the head by the austenitic stainless steel wire rod for 820N / mm ² or more 950 N / mm ² or less is a bolt, compressed in the axial direction in, can be a tensile strength of 800 N / mm ² or more 950 N / mm ² or less, i.e. tensile strength to produce 800 N / mm ² or more high-strength stainless bolts. Further, since the austenitic stainless steel wire has an axial residual stress, that is, a tensile residual stress, by wire drawing, it is easy to compress in the axial direction. A part can be shape | molded and the lifetime of a metal mold | die for shaping | molding can be lengthened.

In the austenitic stainless steel wire according to the present invention, the tensile strength is set to 550 N / mm ² or more and 700 N / mm ² or less by annealing and then the wire is drawn to have an axial residual stress. wherein the tensile strength is 650 N / mm ² or more 800 N / mm ² or less.

In the austenitic stainless steel bolt according to the present invention, compressing the austenitic stainless steel wire tensile strength and having an axial residual stress described above is 650 N / mm ² or more 800 N / mm ² or less in the axial direction And after forming the shaft portion by sealing and drawing the shaft portion, the shaft portion is formed by rolling the shaft portion and has a tensile strength of 800 N / mm ² or more. It is characterized by being.

Thus, the tensile strength is 650 N / mm ² or more 800 N / mm ² or less is austenitic stainless steel wire, and forming the shaft portion by deep drawing sealed in any working rate, then rolling the shaft portion by forming the threaded portion and forming processing can be tensile strength to produce 800 N / mm ² or more high-strength stainless bolts. In addition, since austenitic stainless steel wire has an axial residual stress, that is, a tensile residual stress, by wire drawing, it is easy to compress in the axial direction. Thus, the life of the molding die can be extended.

  Further, it is preferable that the austenitic stainless steel bolt described above is further subjected to zinc powder baking coating. As a result, the bolt can be further improved in corrosion resistance, salt spray resistance, potential difference corrosion resistance against aluminum, and the like.

As described above, according to the present invention, it is possible to provide a high-strength stainless steel bolt having a tensile strength of 800 N / mm ² or more and excellent corrosion resistance, and a wire used for manufacturing the same.

  The best mode for carrying out the present invention will be exemplarily described in detail below with reference to the drawings. However, the dimensions, materials, shapes, relative arrangements, and the like of the components described in this embodiment are not intended to limit the scope of the present invention only to those unless otherwise specified. .

FIG. 1 shows, by weight%, C: 0.030% or less, Si: 1.0% or less, Mn: 2.0% or less, P: 0.045% or less, S: 0.030% or less, Ni: 12 Of SUS316L, which is an austenitic stainless steel containing 0.0 to 15.0%, Cr: 16.0 to 18.0%, Mo: 2.0 to 3.0%, with the balance being Fe and inevitable impurities cold working the wire shows the result of obtaining the relationship between the working ratio in the case of (wire drawing, enclosed drawing, etc.) (%) and tensile strength (N / mm ^2). The processing rate is also referred to as a cross-section reduction rate. When the cross-sectional area of the wire before processing is A0 and the cross-sectional area of the wire after processing is A1, (A0−A1) / A0 × 100 ( %). FIG. 1 also shows the relationship between the processing rate and the tensile strength when a wire having a tensile strength of 550 N / mm ² or more and 700 N / mm ² or less is drawn by annealing.

  As shown in FIG. 1, the tensile strength increases as the processing rate increases. This is because dislocations increase as the wire is deformed by wire drawing, and dislocations are difficult to move due to interaction between dislocations, resulting in work hardening.

(Production method 1)
In view of the mechanical properties of SUS316L, which is the austenitic stainless steel described above, when manufacturing an austenitic stainless steel bolt having a tensile strength of 800 N / mm ² or more, the manufacturing method 1 described below is used.

  That is, in the manufacturing method 1, first, the drawn wire is cut into a predetermined length to obtain a header wire 11. Then, as shown in FIG. 2, while the wire 11 is supported by the punch 12, the wire 11 is inserted into the hole of the forming die 13 and abuts against the knockout pin 14 whose position is set in advance. And the head 10a is made into a preliminary shape by carrying out what is called a swaging process which compresses to an axial direction in that state (process 1). Thereafter, the header blank 16 is formed with the head 10a having a final shape by swaging using the punch 15 (step 2). Thereafter, the threaded portion 10b is formed by rolling the header blank 16.

The wire that has been hardened by wire drawing in this way is swept to form the head portion, and the thread portion is formed by rolling. However, strain energy is generated around the dislocation by wire drawing. Therefore, when a crystal having a high dislocation density is heated during upsetting or rolling, the structure changes to a low energy state and the hardness decreases. In other words, even if the tensile strength is increased by wire drawing, the tensile strength is decreased by swaging the head or rolling the screw portion. According to the research of the present inventor, it has been found that the tensile strength decreases in a range of about 20 N / mm ² or less by rolling the thread portion.

Therefore, when the the tensile strength of the final bolts 800 N / mm ² or more, it is necessary tensile strength of the drawn processed wire is 820N / mm ² or more. Therefore, based on the relationship shown in FIG. 1, a wire whose tensile strength is 550 N / mm ² or more and 700 N / mm ² or less by annealing is drawn at a processing rate of about 25%.

In other words, in this production method 1, first, the austenitic stainless steel wire is annealed so that the tensile strength becomes 550 N / mm ² or more and 700 N / mm ² or less, and then drawn at a processing rate of about 25%. by processing, the tensile strength and having an axial tensile residual stress and 820N / mm ² or more 950 N / mm ² or less is austenitic stainless steel wire. Thereafter, the austenitic stainless steel wire is compressed (upset) in the axial direction to form the head, and the threaded portion is formed by rolling. Thus, even the tensile strength was reduced by about 20 N / mm ² or less by rolling, the tensile strength to produce a 800 N / mm ² or more 950 N / mm ² or less is austenitic stainless steel bolt Can do.

  When a bolt is manufactured by such a manufacturing method, a tensile residual stress is generated in the axial direction due to the above-described wire drawing, so that it is easy to compress in the axial direction, and the head 10a is swept using the punches 12 and 15. In doing so, the head 10a can be formed with a relatively low load. Thereby, the lifetimes of the molding dies such as the molding die 13, the knockout pin 14, and the punches 12 and 15 can be extended.

(Manufacturing method 2)
Next, a case where an austenitic stainless steel bolt having a tensile strength of 1040 N / mm ² or more is manufactured in view of the mechanical characteristics of SUS316L, which is the austenitic stainless steel described above, will be described.

In tensile strength to produce the austenitic stainless steel bolt is 1040N / mm ² or more even, as well as to produce a tensile strength described above is 800 N / mm ² or more bolts, the tensile strength of the annealing A wire having a tensile strength of 1060 N / mm ² or more and 1210 N / mm ² or less is formed by drawing a wire made from 550 N / mm ^{2 to} 700 N / mm ^{2 at} a processing rate of about 48%, and thereafter It is also possible to manufacture by performing a head upsetting process and a thread rolling process.

However, when a head having a tensile strength of 1060 N / mm ² or more and 1210 N / mm ² or less is swept to form a head, even if a tensile residual stress is generated in the axial direction, a high load Therefore, it is necessary to compress the wire rod, and it is not a good idea considering the life of the molding die. In addition, since the tensile strength is 1060 N / mm ² or more, it is not a good idea to cut the drawn wire into the length of the header wire in consideration of the life of the cutting jig.

Therefore, the manufacturing method 2 described below is performed. That is, in the production method 2, first, the tensile strength is increased by annealing the wire to a tensile strength of 550 N / mm ^{2 to} 700 N / mm ² and drawing the wire at a processing rate of about 8%. There producing 650 N / mm ² or more 800 N / mm ² or less is austenitic stainless steel wire.

Thereafter, the tensile strength to the wire 21 for the header by cutting the 650 N / mm ² or more 800 N / mm ² or less is austenitic stainless steel wire to a predetermined length. Then, as shown in FIG. 3, the wire 21 is inserted into a forming die 23 in which a knockout pin 22 is set in advance at a predetermined position (step 1), and the shaft portion is formed by hermetically drawing with a punch 24. At the same time, a preliminary shape of the head 20a is formed (step 2).

  Thereafter, it is inserted into a forming die 26 in which a knockout pin 25 is set in advance at a predetermined position (step 3), and the head blank 20 is formed into a final shape by swaging using a punch 27. (Step 4). Then, the threaded portion 20b is formed by rolling the header blank 28.

Even when the manufacturing method 2 is used, as described above, when the thread portion is rolled, the tensile strength of the shaft portion of the header blank 28 is taken into consideration when the tensile strength is reduced to about 20 N / mm ² or less. Needs to be 1060 N / mm ² or more. For this purpose, a wire having a tensile strength of 550 N / mm ² or more and 700 N / mm ² or less by annealing based on the relationship of FIG. 1 is drawn at a processing rate of about 8%, and the tensile strength is 650 N / mm ^2. The shaft portion is formed by carrying out hermetic drawing at a processing rate of about 40% after that, and at 800 N / mm ² or less.

In other words, first, the austenitic stainless steel wire is annealed so that the tensile strength becomes 550 N / mm ² or more and 700 N / mm ² or less, and then drawn at a processing rate of about 8%. tensile strength and has a direction of tensile residual stress and 650 N / mm ² or more 800 N / mm ² or less is austenitic stainless steel wire. Thereafter, the austenitic stainless steel wire is hermetically drawn at a processing rate of about 40%, so that the tensile strength is 1060 N / mm ² or more and 1210 N / mm ² or less. And a head is shape | molded by compressing (a swaging process) to an axial direction, and a thread part is shape | molded by rolling. Thus, even the tensile strength by rolling is lowered in the range of about 20 N / mm ² or less, the tensile strength is 1040N / mm ² or more 1210N / mm ² or less austenitic stainless steel bolt produced can do.

When this process 2 by bolts production, in the axial direction by the wire drawing process has occurred tensile residual stress, because the tensile strength is 650 N / mm ² or more 800 N / mm ² or less, tends to compress in the axial direction When the head 20a is swept using the punches 24 and 27, the head 20a can be formed with a relatively low load. Thereby, the lifetimes of the molding dies such as the molding die 26, the knockout pin 25, and the punch 27 can be extended.

Also, using this production method 2, an austenitic stainless steel bolt having a tensile strength of 800 N / mm ² or more can be produced.

In this case, as described above, the tensile strength of the header blank 28 is 820 N / mm ² in consideration of the drop in tensile strength of about 20 N / mm ² or less when the thread portion is rolled. Try to be more.

For this purpose, first, the wire is annealed to have a tensile strength of 550 N / mm ² or more and 700 N / mm ² or less, and the wire is drawn at a processing rate of about 8%, whereby the tensile strength is 650 N / mm. ^An austenitic stainless steel wire that is ² or more and 800 N / mm ² or less is manufactured.

Thereafter, the tensile strength of the 650 N / mm ² or more 800 N / mm ² or less is austenitic stainless steel wire, based on the relationship of FIG. 1, further sealed drawn in approximately 14% of the working ratio (step 2).

  Thereafter, it is inserted into a forming die 26 in which a knockout pin 25 is set in advance at a predetermined position (step 3), and the head blank 20 is formed into a final shape by swaging using a punch 27. (Step 4). Then, the threaded portion 10 b is formed by rolling the header blank 28.

In other words, first, the austenitic stainless steel wire is annealed so that the tensile strength becomes 550 N / mm ² or more and 700 N / mm ² or less, and then drawn at a processing rate of about 8%. tensile strength and has a direction of tensile residual stress and 650 N / mm ² or more 800 N / mm ² or less is austenitic stainless steel wire. Thereafter, the austenitic stainless steel wire, and sealed drawing at a processing rate of about 14%, the tensile strength and 820N / mm ² or more 950 N / mm ² or less. And a head is shape | molded by compressing (a swaging process) to an axial direction, and a thread part is shape | molded by rolling. Thus, even the tensile strength by rolling is lowered in the range of about 20 N / mm ² or less, the tensile strength is 800 N / mm ² or more 950 N / mm ² or less austenitic stainless steel bolt produced can do.

In this way, if a wire rod that can be processed to the final bolt dimensions by arbitrarily selecting the processing rate at the time of wire drawing and the processing rate at the time of hermetic drawing is used, the tension An austenitic stainless steel bolt having an arbitrary tensile strength of 800 N / mm ² or more can be produced.

  Moreover, by further applying a rust-proof surface treatment to the austenitic stainless steel bolts manufactured using the above-described manufacturing method 1 and manufacturing method 2, the corrosion resistance, salt spray resistance, potential difference corrosion characteristics against aluminum, etc. are further improved. Can do. As a rust-proof surface treatment, zinc powder baking coating is suitable, and as a typical example, it should be realized by applying Geomet (registered trademark) treatment or dacrotized (registered trademark) treatment provided by Nippon Dacro Shamrock Co., Ltd. Can do.

Next, an M8 bolt (sample 1) of JIS B 1051 strength category 8.8 manufactured by the above-described manufacturing method 1 using an austenitic stainless steel (SUS316L) wire, and similarly an austenitic stainless steel (SUS316L) wire. Using M8 bolts (sample 2) of JIS B 1051 strength category 10.9 and a martensitic stainless steel (SUS410) wire with a tensile strength of 540 N / mm ² as a comparative example, manufactured by the manufacturing method 2 described above. FIG. 4 shows the results of the sulfur dioxide gas corrosion test and the salt spray test of M8 bolts (sample 3) of JIS B 1051 strength category 8.8, which were manufactured by quenching and tempering the bolts to a predetermined tensile strength. .

Here, the sulfurous acid gas corrosion test is performed based on the provisions of DIN 50018, and the conditions are as follows.
Gas concentration: SO ₂ gas 2L (liter) + moisture 2L (liter) + air 300L (liter)
Temperature and humidity: 40 ± 3 ° C, 95% RH
Test time: 8 hr test, 16 hours standing cycle 5 times

Moreover, a salt spray test is implemented based on prescription | regulation of JISZ2371, The conditions are as follows.
Solution concentration; 5 ± 1% saline temperature; 35 ± 2 ° C.
Test time: Continuous spray

Sample 1 is specifically manufactured as follows. That is, first, a wire having a diameter of 8.2 mm is made into a wire having a tensile strength of about 600 N / mm ² by annealing, and then drawn at a processing rate of 25% to obtain a diameter of 7.1 mm. A wire having a strength of 898 N / mm ² was used. Then, the austenitic stainless steel having a tensile strength of 888 N / mm ² is obtained by swaging the head portion of the wire having a tensile strength of 898 N / mm ² in the header process and rolling the thread portion. The bolt was (SUS316L).

In Sample 2, first, a wire having a diameter of 9.5 mm was annealed to obtain a wire having a tensile strength of about 600 N / mm ² , and then subjected to wire drawing at a processing rate of 8.2% to obtain a diameter of 9.1 mm. By doing so, a wire having a tensile strength of 700 N / mm ² was obtained. Thereafter, the shaft portion is formed by sealing and drawing the wire having a tensile strength of 700 N / mm ² at a processing rate (area reduction rate) of 40%, and the shaft portion is rolled to form a thread portion. In addition, the head was formed by swaging in the header process to obtain a bolt of austenitic stainless steel (SUS316L) having a tensile strength of 1132 N / mm ² .
In addition, the above-mentioned samples are not subjected to zinc powder baking coating.

  As shown in FIG. 4, the bolts (samples 1 and 2) manufactured using austenitic stainless steel have better corrosion resistance than the bolts (sample 3) manufactured using martensitic stainless steel. I understand.

It is a figure which shows the relationship between a process rate at the time of cold-working (wire drawing, hermetic drawing, etc.) and the tensile strength of the wire material of austenitic stainless steel (SUS316L). 1 is a diagram illustrating a manufacturing process according to manufacturing method 1. FIG. 5 is a diagram illustrating a manufacturing process according to manufacturing method 2. FIG. It is a figure which shows the result of having performed the sulfurous acid gas corrosion test and the salt spray test with respect to the austenitic stainless steel (SUS316L) bolt and the martensitic stainless steel (SUS410) bolt.

Explanation of symbols

10, 20 Bolt 10a, 20a Head 10b, 20b Screw part 11, 21 Wire rod for header 12, 15, 24, 27 Punch 13, 23, 26 Molding die 14, 22, 25 Knockout pin 16, 28 Header blank

Claims (5)

Tensile strength by being KoShinsen processed is to 550 N / mm ² or more 700 N / mm ² or less by annealing, the tensile strength and having an axial residual stress 820N / mm ² or more 950 N / mm ² or less An austenitic stainless steel wire, characterized in that A head portion formed by compressing the austenitic stainless steel wire rod according to claim 1 in the axial direction and a thread portion formed by rolling, and a tensile strength of 800 N / mm ² or more. An austenitic stainless steel bolt characterized by that. Tensile strength by being KoShinsen processed is to 550 N / mm ² or more 700 N / mm ² or less by annealing, the tensile strength and having an axial residual stress 650 N / mm ² or more 800 N / mm ² or less An austenitic stainless steel wire, characterized in that A head portion formed by compressing the austenitic stainless steel wire rod according to claim 3 in the axial direction and a shaft portion formed by hermetic drawing, and then formed by rolling the shaft portion. An austenitic stainless steel bolt having a threaded portion and a tensile strength of 800 N / mm ² or more.   The austenitic stainless steel bolt according to claim 2 or 4, further comprising zinc powder baking coating.

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