JPH0762491A - Steel for metallic mold - Google Patents

Abstract

PURPOSE:To provide a steel for metallic mold used for a plastic formation having extremely excellent machinability and providing excellent grinding finishing property and wear resistance, too. CONSTITUTION:This steel for metallic mold has the characteristic composed of, by weight 0.10-0.25wt.%. C, <=1.00% Si, <=2.00% Mn, >1.00-2.50% Cr, <=1.00% Mo+1/2W by single or duplex of Mo and w, 0.03-0.15% V, 0.10-1.00% Cu, <=0.05% S and the balance Fe with inevitable impurities and if necessary, adding Ni and Ca.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a die steel which is characterized by having extremely excellent machinability and has excellent polishing finish and abrasion resistance and which is mainly used for plastic molding. Is.

[0002]

2. Description of the Related Art (1) As a steel for a plastic molding die, (1) it has a good mirror finish and has a small tendency to generate pinholes and other fine pits. (2) Good texture processing. (3) Good corrosion and rust resistance. (4) Good strength, wear resistance and toughness. (5) Good machinability. Is required. Conventionally, the C-Mn-Cr-Mo-Fe system, such as SCM440, has been used for the steel for molds for plastic molding, but the above demand has increased, and in recent years, in particular, shortening the production lead time is particularly important. Have been strongly raised as a strong customer requirement. In order to reduce the processing man-hours in response to this demand, for example, the low C-M proposed in Japanese Patent Publication No. 52-1372.
n-Cr-Mo-S-Fe system and Ni to supplement hardenability
The steel of Japanese Examined Patent Publication No. 56-21063, etc., which has been added with the addition of Cu without the addition of S to improve the machinability.
The steels disclosed in Japanese Patent No. 700 and Japanese Patent Laid-Open No. 60-204869 are generally used.

[0003]

However, the aforementioned low C-
Mn-Cr-Mo-S-Fe system or low C-Mn-Ni-Cr-Mo
-For S-Fe plastic molding steel, for example, when a large mold with a maximum length of about 2 m is manufactured, segregation of sulfides, etc. deteriorates polishing finish, wear resistance, and toughness. However, there is a problem that a sufficient mold life cannot be obtained. In addition, low C-Mn disclosed in JP-B-60-41700 containing no S added
In the -Cr-Cu-Fe system, the softening resistance during quenching and tempering is small, and the hardness decreases when nitriding is performed at around 550 ° C, and the low C-value disclosed in JP-A-60-204869.
Since the Mn-Ni-Cr-Mo (1 / 2W) -Cu-Fe system has a low C content, sufficient precipitation strengthening cannot be obtained, which is not always satisfactory. The present invention satisfies the various requirements of the above-mentioned plastic molding die steel even when a large die is manufactured, and by sufficient precipitation strengthening by Cr, Mo (1 / 2W), Cu and V, The purpose of the present invention is to provide a die steel having extremely excellent strength and machinability.

[0004]

Among the steels of the present invention, the first invention is, in weight%, C 0.10 to 0.25%, Si 1.00% or less,
Mn 2.00% or less, Cr 1.00% or more and 2.50% or less, Mo and W alone or in combination Mo + 1 / 2W 1.00% or less, V 0.03 to 0.1
5%, Cu 0.10 to 1.00%, S 0.05% or less, balance Fe and unavoidable impurities, and a second invention is a die steel, wherein the second invention is C 0.10 to 0.25% by weight, Si 1.
00% or less, Mn 2.00% or less, Ni 2.0% or less, Cr 1.00% to 2.50% or less, Mo and W are Mo + 1 / 2W alone or in combination.
It is a die steel characterized by comprising 1.00% or less, Cu 0.50 to 3.00%, the balance Fe and unavoidable impurities. Moreover, 0.0005 to 0.010% of Ca can be added to the die steel according to the first or second invention, if necessary.

The present invention will be described in more detail below. The present invention steel is a low C-Mn-Cr-Mo (W) -V-Cu-Fe alloy system,
Alternatively, it is an alloy that has a low C-Mn-Ni-Cr-Mo (W) -V-Cu-Fe alloy system as a basic component and aims to appropriately suppress S and promote uniform dispersion of sulfides by adding Cu. . These alloys produce a uniform upper bainite structure by quenching, and are further tempered at a temperature of 550 ° C or higher to adjust the hardness to around 30 HRC, so that Fe-Cu solid solution and Cr, Mo (W), V
By precipitating the carbides and further aggregating them, high strength is imparted and at the same time embrittlement is caused appropriately, and extremely good machinability is imparted to the matrix itself. Therefore, normally, even if a large amount of S added as a means for imparting free-cutting property to steel is limited to a small amount, it is possible to obtain extremely excellent machinability. It is characterized by the following points. In addition, when S is 0.05% or less, and Ca is added, segregation of sulfide causes segregation of sulfides, which causes problems such as occurrence of binhole during welding, roughening of electric discharge machined surface, deterioration of polishing finish, wear resistance and toughness. Is avoided, and excellent corrosion resistance and rust resistance are obtained in combination with the inclusion of Cr, Mo, W, Cu or even Ni.

Thus, there is a significant difference from Japanese Patent Publication No. 52-1372 in that S has been reduced by imparting good machinability to the base itself. In the present invention, Mo and W are added individually or in combination, and the Mo amount and the 1/2 W amount have equivalent addition effects.
In the present invention, Mo and W increase the softening resistance at the time of quenching and tempering, and further Fe-Cr oxide film or Cr on the die surface.
It is an important element because it forms a solid solution in the oxide film to strengthen the film and improve the corrosion resistance of the mold. The steel of the present invention is supplied in a pre-hardened state having a hardness of about 30 HRC (generally, after tempering and tempering at 550 ° C. or higher), and is used as it is after die-cutting and polishing finish. Therefore, it does not require heat treatment after the die-cutting process, brings good machinability, excellent polishing finish, and even in a large-sized die,
It is a new mold steel that allows long life without the concern of wear.

Since the steel of the present invention is intended to reduce free-cutting elements such as S, it is not necessary to worry about the occurrence of significant segregation accompanying the enlargement of the die. Therefore, the steel of the present invention is effectively applied not only to dies for small articles, but also to dies having a particularly large size, for example, dies having a maximum length of one side of the die of about 2000 mm.

[0008]

Next, the reasons for limiting the components of the steel of the present invention will be described. C keeps the quenching structure of the steel of the present invention in the upper bainite structure with good machinability, and Cr and Mo in tempering.
(W), V It is a basic additional element necessary for strengthening by precipitation of carbide. If it is too much, it reduces the machinability by forming a martensite structure in the matrix and reduces the machinability by forming excessive carbides, so it is 0.25% or less, and if it is too low, it causes precipitation of ferrite and is 0.10% or more. To do. Mn is added in order to enhance the bainite hardenability of the steel of the present invention, to suppress the formation of ferrite, and to give an appropriate quenching and tempering hardness. If it is too large, the bainite structure is excessively refined, and the viscosity of the matrix is increased to reduce the machinability, so the content is made 2.00% or less.

Si is added to enhance the corrosion resistance to the atmosphere when the mold is used. If it is too large, it will lead to the formation of ferrite. Cr enhances the corrosion resistance of the steel of the present invention, suppresses rusting during polishing or storage in a mold, and enhances the hardness of the nitride layer during nitriding, and precipitates fine carbides in the tempering treatment. It is added to agglomerate and form the strength of the steel of the present invention. If it is too large, the bainite structure is refined, the viscosity of the matrix is increased and the machinability is lowered, and if it is too low, the effect of the above addition cannot be obtained, so the range was made to exceed 1.00% and not more than 2.50%. As described above, in order to improve the strength of the mold, a large amount of Cr may be added, but the machinability deteriorates as the amount of Cr increases, so there is a limit to the addition of Cr. Considering that the mold is nitrided before use, 55
It is necessary to guarantee resistance to temper softening above 0 ° C,
Also in this respect, addition of Cr alone is not sufficient, and addition of Mo and W is necessary.

Therefore, the effect of Mo and W in the present invention is that fine carbides are precipitated and aggregated in the tempering treatment,
In order to improve the strength of the steel of the present invention and increase the softening resistance in quenching and tempering, it is added alone or in combination. Further, some Mo and W also form a solid solution in the oxide film on the surface of the mold to improve the corrosion resistance against corrosive gas generated from plastic during use of the mold. is there. In the case of this application, it is not necessary to add a large amount,
If it is too large, the machinability will deteriorate, so Mo + 1 / 2W
It was 1.00% or less. V increases tempering softening resistance, suppresses coarsening of crystal grains, and contributes to improvement of toughness. Further, it has the effect of forming hard carbide minutely and improving wear resistance. For this purpose, at least 0.03% or more is required, but if it is too large, the machinability deteriorates, so 0.
It was set to 15% or less.

Cu is used in the tempering treatment of the steel of the present invention.
The Fe-Cu solid solution is precipitated and aggregated, and is added in order to impart excellent machinability to the steel of the present invention together with the upper bainite structure and to bring excellent corrosion resistance. If it is too much, the hot workability is reduced, the bainite structure is refined, and the machinability is reduced, so 1.00%
If the amount is below, the effect of the above addition cannot be obtained if it is too low.
0.10% or more. Ni enhances the bainite hardenability of the steel of the present invention and suppresses the formation of ferrite, so Ni is added as necessary. If it is too large, the bainite structure is excessively refined, the viscosity of the matrix is increased, and the machinability is reduced, so it is preferable to be 2.00% or less. INDUSTRIAL APPLICABILITY The steel of the present invention can be avoided from deterioration of polishing finishability, wear resistance, toughness and the like caused by segregation of S sulfide and the like, which has been conventionally added for the purpose of improving machinability, and further temper temper softening Due to its high resistance and corrosion resistance, by combining the above composition with bainite quenching treatment, for example, even in a large plastic molding die whose longest part reaches 2000 mm, good machinability and The required characteristics can be sufficiently satisfied.

[0012]

EXAMPLES The present invention will be described below based on examples. Table 1 shows the chemical compositions of the inventive steels and the conventional steels. Conventional steels U and V are plastic mold steels corresponding to the above-mentioned Japanese Patent Publication Nos. 52-1372 and 60-41700, respectively. Conventional steel W is SCM440. Table 1 shows the invention steels of 30 to 32
The machinability index when heat-treated with HRC as the target and cut with an end mill is based on SCM440 of conventional steel Y (10
Shown as 0). Table 2 shows a comparison of the rust resistance, the surface roughness indicating the polishing finish and the wear resistance of the steel of the present invention and the conventional steel.

S exists as a nonmetallic inclusion MnS,
It has a great effect on improving the machinability. However, a large amount of M
The presence of nS is not only an adverse effect during die machining, such as pinhole formation during welding, pinhole formation during polishing, and rough surface of the electrical discharge machining surface, but it also serves as a starting point for rusting and mechanical property It is also a factor that deteriorates the performance of the mold itself, such as promoting Especially in a large-sized mold, the above-mentioned adverse effects due to segregation of MnS become particularly remarkable. Therefore, in order to suppress these problems, it is necessary to limit S to at least 0.05% or less. Ca acts as an oxide as a nucleus at the time of crystallization of MnS, suppresses segregation, and has the effect of making MnS finer and uniformly dispersed, and is added as necessary. In order to improve the effect of eliminating the adverse factors caused by MnS in a particularly large mold, addition of Ca together with the limitation of the amount of S is effective, and at least 0.0005% or more is required for this purpose. However, when the content is 0.010% or more, Ca oxide exists as a single substance and adversely affects the machinability. Therefore, it is preferable to set this to the upper limit.

[0014]

[Table 1]

[0015]

[Table 2]

[0016]

[Table 3]

The rust resistance mainly evaluates the corrosion resistance to chlorine ions and is the result of the rust resistance test in a salt water atmosphere. After polishing the 25 mm × 25 mm surface of the sample with emery paper, buff mirror finish and place these in a salt spray tester.
The number of rusts when exposed to time is 10 for the conventional steel W.
It is shown as an index of 0. The surface roughness was used to evaluate the polishing finish of the die, and the maximum surface roughness ratio after the # 8000 diamond compound finish (the conventional steel W was 100) was shown. Abrasion resistance is the wear reduction ratio of the rotary abrasion test in sand.
(Conventional steel W is set to 100). Abrasion test is 3mm x 15mm
A 70 mm test piece was spun at 1280 rpm in fine grain (9.2 mesh or less) sand for 1 hour.

The steel of the present invention is superior to the conventional steel U in rust resistance, polishing finish indicated by surface roughness, and wear resistance. This is because the conventional steel U contains a large amount of sulfide-based nonmetallic inclusions, and this sulfide causes the generation of corrosion holes. Further, the sulfide is much softer than the matrix, and pits are easily generated from the sulfide during polishing. This is the same as in the wear resistance, which is a place to promote the progress of wear.

Table 3 shows the steels B and Q of the present invention and the conventional steel U of 30 to 32 HR using a forged material having a cross sectional size of 50 mm × 150 mm.
The results of the tensile test and the Charpy impact test (2 mm U notch) of the test piece taken in parallel (L) and right angle (T) directions with respect to the forging direction after quenching and tempering with the target of C are shown.
The steels B and Q of the present invention show less variation in toughness depending on the direction of the test piece as compared with the conventional steel U, and the conventional steel U has a large difference in toughness in the direction perpendicular to the forging direction. This is because the conventional steel U contains a large amount of sulfide-based non-metallic inclusions in comparison with the steels B and Q of the present invention and is distributed in the form of fibers in the forging direction, so the toughness in the forging direction is higher than that in the vertical direction. It can be seen that the toughness of is significantly reduced.

The degree of segregation of sulfide tends to increase as the size of the die increases, and in the case of S-added steel, the directionality of toughness is expected to expand further. The effect of improving the toughness of the steel according to the present invention, which is achieved by making the steel more uniform and more uniformly dispersed, is particularly exerted in a large mold. Table 4 shows the results of measuring the change in hardness before and after the nitriding treatment by performing gas nitriding treatment at 570 ° C. on Inventions A and M and Conventional Steel X. In each of the steels of the present invention, Mo, W, and V are added in addition to Cr, and the temper softening resistance is large.
It can be seen that there is no decrease in hardness after nitriding treatment, which is a significant improvement over conventional steel.

[0021]

[Table 4]

[0022]

As described above in detail, the steel of the present invention contains a large amount of free-cutting elements such as S by appropriately combining the matrix structure and the precipitation product and adjusting the hardness to about 30 HRC during heat treatment. It retains extremely excellent machinability even if it is not added to, and has excellent rust resistance, abrasion resistance, and polishing finish. In addition, segregation, which is a problem in the case of a large mold, is significantly reduced by optimizing the S content and uniformly dispersing it. The steel of the present invention has a high resistance to tempering and softening, so that even if the mold is subjected to nitriding treatment, the hardness does not decrease, and it has sufficient strength and wear resistance, and is particularly effective for large plastic molds. Can be demonstrated.

Claims (3)

[Claims] 1. By weight%, C 0.10-0.25%, Si 1.00%
Below, Mn 2.00% or less, Cr over 1.00% and 2.50% or less, Mo
And W alone or in combination Mo + 1 / 2W 1.00% or less, V 0.0
A die steel comprising 3 to 0.15%, Cu 0.10 to 1.00%, S 0.05% or less, the balance Fe and unavoidable impurities. 2. By weight%, C 0.10 to 0.25%, Si 1.00%
Below, Mn 2.00% or less, Ni 2.0% or less, Cr over 1.00%
2.50% or less, Mo and W alone or in combination Mo + 1 / 2W 1.0
0% or less, V 0.03 to 0.15%, Cu 0.10 to 1.00%, S 0.05%
Hereinafter, a steel for molds, which is characterized by comprising the balance Fe and unavoidable impurities. 3. The die steel according to claim 1, wherein a part of Fe is replaced by Ca 0.0005 to 0.010%.