KR20080057402A - Fe-based amorphous alloy - Google Patents

Abstract

An Fe-based amorphous alloy is provided to improve amorphous stabilizing ability and glass forming ability while adding inexpensive alloy elements. An Fe-based amorphous alloy comprises, by atomic percent, 11 to 13% of Cr, 1 to 3% of Mo,5 to 7% of C, 5 to 7% of B, 8 to 10% of P, and 0.5 to 3% of Si with the balance being Fe. The Fe-based amorphous alloy further comprises, by atomic percent, 1 to 3% of at least one selected from the group consisting of Co, Cu, Nb, and W. The content of Fe is 62 to 64 at.%, a sum of components except Fe is 36 to 38 at.%, a sum of C, B and P is 19 to 23 at.%. The alloy has a glass forming ability(Trg=Tg/Ti) of 0.44 to 0.75. The amorphous alloy has a shape selected from a ribbon, a rod, and a plate. The amorphous alloy is a sheet having a thickness of 0.5 to 2 mm and a width of 100 to 150 mm.

Description

Fe-based Amorphous alloy

1 is an XRD analysis result of the iron-based amorphous alloy according to an embodiment of the present invention.

Figure 2 is a graph showing the thermal analysis (DSC) curve for the iron-based amorphous alloy according to an embodiment of the present invention.

Figure 3 is a graph showing the compression test results for the Cu-based iron-based amorphous alloy.

4 is a photograph showing a rod-shaped specimen having a diameter of 2 mm manufactured using a suction caster equipment.

The present invention relates to an iron-based amorphous alloy, and more particularly to an iron-based amorphous alloy that can improve the amorphous stabilizing ability and the amorphous forming ability. Iron-based amorphous alloys having improved properties can be easily manufactured in bulk or as a sheet material.

Iron-based bulk amorphous alloy is a field in which a lot of research is being conducted because it is cheaper than other amorphous materials and excellent in strength and corrosion resistance. However, due to the characteristics of the iron-based amorphous alloys due to the high melting temperature, low amorphous formability and the resulting low fraction of the amorphous phase had a limitation in manufacturing.

Since the high melting point of the iron-based amorphous alloy requires a high cooling rate in the manufacturing process, it can be amorphous in the melt spin process having excellent quenching effect, but has a limitation in bulking. Therefore, there is a limit in the cooling capacity in the process, and if the alloy system having excellent amorphous forming ability is developed and applied to a process capable of mass production and continuous production, it is possible to develop materials having sufficient physical properties and price competitiveness.

Most of the iron-based amorphous alloys reported in the literature and the like are alloys made to enable amorphous formation ability up to several millimeters by the addition of expensive elements such as Y and Er. Most alloy systems designed using inexpensive elements do not have excellent amorphous forming ability and thus have not been put to practical use.

Accordingly, the present invention provides an iron-based amorphous alloy in which amorphous stabilizing ability and amorphous forming ability are improved while adding an inexpensive alloy element.

Iron-based amorphous alloy of the present invention for achieving the above object, in atomic%, Cr: 11-13%, Mo: 1-3%, C: 5-7%, B: 5-7%, P: 8- It contains 10%, Si: 0.5-3% and is composed of the remaining Fe.

According to one embodiment of the present invention, the iron-based amorphous alloy may further include at least one selected from the group of Co, Cu, Nb, and W.

According to an embodiment of the present invention, the iron-based amorphous alloy has an amorphous forming ability (Trg = Tg / Ti) of 0.44-0.75. The iron-based amorphous alloy of the present invention has any one shape selected from ribbons, rods, and plates. The amorphous alloy may have a plate material having a thickness of 0.5-2 mm and a width of 100-150 mm.

According to one embodiment of the present invention, the iron-based amorphous alloy of the present invention may have an amorphous characteristic by a casting process such as suction casting or twin roll casting.

Hereinafter, the present invention will be described in detail.

In the present invention, the present invention has been completed by optimizing the composition ratio and the combination of the basic components of the iron-based amorphous alloy in the research process for developing an iron-based amorphous alloy that can implement the amorphous properties without the addition of expensive rare earth elements.

In order to obtain the iron-based amorphous alloy according to the present invention, the basic component system is Fe-Cr-Mo-CBP-Si, the content of which is Cr: about 11%-about 13%, Mo: about 1%-about 3%, C: about 5- about 7%, B: about 5%-about 7%, P: about 8%-about 10%, Si: about 0.5%-about 3% and the remaining Fe. This will be described in detail later. In the following, the description of the composition range is omitted in the absence of a description of the drug. This drug contains stated values and includes the degree of error in measuring that particular value.

In the iron-based amorphous alloy, Cr and Mo are added in consideration of amorphous forming ability and strength, and 11-13% is preferable for Cr and 1-3% for Mo. The lower limit of the composition ranges of Cr and Mo is set in order to secure amorphous molding ability and strength, and the upper limit is set in terms of preventing the degradation of amorphous molding ability.

In iron-based amorphous alloys, C, B, and P are added in consideration of amorphous forming ability, 5-7% for C, 5-7% for B, and 8-10% for P. If it is out of range, it is difficult to secure amorphous forming ability.

In this iron-based amorphous alloy, Si is added in an amount of 0.5-3% to ensure castability.

According to an embodiment of the present invention, the most preferred composition of the basic component system is Fe ₆₄ Cr ₁₂ Mo ₂ C ₆ B ₆ P ₉ Si ₁ , wherein the content is atomic%.

Alloy elements are added to the basic component system as needed, such as Al, Co, Co, MM (mimetal), Nb, Ti, W, Zr, and the like. Among these, Co, Cu, Nb, and W are preferable. The content of these alloying elements is 1-3 atomic%. This is considering the amorphous stabilizing ability and the amorphous forming ability.

According to one embodiment of the present invention, when 2% of Cu is added to the base alloy system, the amorphous forming ability (Trg) value is the highest and the compressive strength or the elongation at break is greatly increased. This is much easier to amorphous due to the addition of the Cu element, thereby improving the mechanical properties.

According to one embodiment of the present invention, the iron content of the iron-based amorphous alloy of the present invention is 62-64%, the sum of the components other than Fe is 36-38%. The sum of C + B + P in components other than Fe is preferably 19-23%.

According to one embodiment of the present invention, the iron-based amorphous alloy may have an amorphous forming ability (Trg = Tg / Ti) of 0.44-0.75. The amorphous alloy may have any one shape selected from ribbons, rods, and plates. The amorphous alloy may be a plate having a thickness of 0.5-2 mm and a width of 100-150 mm.

Since the iron-based amorphous alloy of the present invention has improved amorphous forming ability (Trg), it can be cast by injection casting, suction casting, twin roll type casting, or the like.

As described above, the amorphous alloy of the present invention can overcome the manufacturing limitations of the iron-based amorphous alloy due to the high melting point of the iron-based amorphous alloy due to its excellent amorphous forming ability and mechanical properties. The high amorphous formability allows the high melting point to overcome the limitations of the high cooling rate required and the bulking of iron-based amorphous alloys. The amorphous iron-based amorphous alloy of the present invention will be applicable to many fields that require high strength, high corrosion resistance.

Hereinafter, the present invention will be described in more detail with reference to Examples.

<Example>

The amorphous formability and the mechanical property change of the iron-based amorphous alloy having the composition shown in Table 1 were measured.

First Fe ₆₄ Cr ₁₂ Mo ₂ C ₆ B ₆ P ₉ Si ₁ An alloy or an alloying element was added to the alloy as shown in Table 1 to prepare a master alloy. The prepared master alloy was remelted through arc melting to prevent segregation. The prepared alloy was rapidly quenched into a 2 mm rod using a suction casting machine, and then processed into a shape of height 3 mm and diameter 2 mm to perform a compression test. Based on the Tg (glass transition temperature), T _x (crystallization temperature) and T _l (liquid temperature) values measured through the thermal analysis curve, the amorphous forming ability (T _rg = T _g / T _l ) was calculated.

division Alloy Composition T _x (K) T _g (K) T _l (K) DT _x (T _x -T _g ) T _rg (T _g / T _l ) Compressive strength (GPa) Elongation at break (%) Hardness (Hv) A Fe ₆₄ Cr ₁₂ Mo ₂ C ₆ B ₆ P ₉ Si ₁ 669 605 1371 63 0.44 0.82 3.78 1075 B Fe ₆₂ Cr ₁₂ Mo ₂ C ₆ B ₆ P ₉ Si ₁ + Al ₂ - - 1335 - - 1.79 6.32 1068 C Fe ₆₂ Cr ₁₂ Mo ₂ C ₆ B ₆ P ₉ Si ₁ + Co ₂ 867 803 1369 64 0.59 1.26 4.74 1029 D Fe ₆₂ Cr ₁₂ Mo ₂ C ₆ B ₆ P ₉ Si ₁ + Cu ₂ 1037 1028 1367 9 0.75 1.29 5.46 1026 E Fe ₆₂ Cr ₁₂ Mo ₂ C ₆ B ₆ P ₉ Si ₁ + MM ₂ - - 1394 - - 1.89 6.85 908 F Fe ₆₂ Cr ₁₂ Mo ₂ C ₆ B ₆ P ₉ Si ₁ + Nb ₂ 810 787 1361 23 0.58 0.54 4.08 979 G Fe ₆₂ Cr ₁₂ Mo ₂ C ₆ B ₆ P ₉ Si ₁ + Nd ₂ - - 1398 - - 1.85 6.81 899 H Fe ₆₂ Cr ₁₂ Mo ₂ C ₆ B ₆ P ₉ Si ₁ + Ti ₂ - - 1345 - - 1.09 4.52 1015 I Fe ₆₂ Cr ₁₂ Mo ₂ C ₆ B ₆ P ₉ Si ₁ + W ₂ 964 932 1386 32 0.67 0.44 3.08 1081 J Fe ₆₂ Cr ₁₂ Mo ₂ C ₆ B ₆ P ₉ Si ₁ + Zr ₂ - - 1381 - - 0.93 4.68 1126

As shown in Table 1, the alloy system (F) to which Nb was added greatly improved (Trg to 0.58) the amorphous forming ability (Trg to 0.44) of the base alloy system (A). This is because the atomic radius of the Nb mixing enthalpy value with a large Fe 16% compared to the atomic radius of 1.26Å Fe to _{1.46Å ΔH Fe- Nb = -15 kJ /} mol to the glass than the amorphous-forming ability.

In particular, when 2% of Cu was added to the base alloy system (A), the amorphous forming ability (Trg) value rapidly increased to 0.75. The compressive strength (~ 1.29GPa) and fracture elongation (~ 5.46%) also increased significantly. This phenomenon made amorphous much easier due to the addition of Cu element, and therefore, it is believed that many amorphous fractions improved mechanical properties.

In order to confirm the above contents, Fe ₆₂ Cr ₁₂ Mo ₂ C ₆ B ₆ P ₉ Si ₁ Nb ₂ alloy was made into a 2 mm rod-shaped specimen, and the circular cross section was observed by using a scanning electron microscope (SEM). At this time, no crystal phase was observed in the SEM image because the specimens tended to be difficult to etch. This fact well illustrates the characteristics of general amorphous alloys. In order to perform more accurate amorphous analysis, it was observed using a transmission electron microscope (TEM), and it was confirmed that an amorphous region exists.

Figure 2 shows the DSC analysis results for the C, D, F, I alloy system of Table 1. 3 shows the compression test results for the D alloy system. And, Figure 4 is a specimen of the rod-shaped specimen for the alloy A.

In general, it is known that iron-based amorphous alloys can be bulked if they exhibit an amorphous forming ability of about 0.6 or more. Therefore, the iron-based amorphous alloy of the present invention can be bulked by the addition of various alloying components.

In the present invention, the above embodiment is only one example, and the present invention is not limited thereto. Anything that has substantially the same configuration as the technical idea described in the claims of the present invention and achieves the same operation and effect is included in the technical scope of the present invention. Accordingly, various forms of substitution, modification, and alteration may be made within the scope of the present invention by those skilled in the art without departing from the technical spirit of the present invention described in the claims of the present invention. Will belong. For example, modifications may be made to combine various alloying components in the amorphous iron-based alloy of the present invention as defined in claim 1.

As described above, the iron-based amorphous alloy of the present invention has improved amorphous forming ability (Trg), and has high compressive strength and excellent elongation at break. Furthermore, it has a level of amorphous forming ability that can be bulked, and thus commercialization is possible.

Claims (6)

In atomic%, containing Cr: 11-13%, Mo: 1-3%, C: 5-7%, B: 5-7%, P: 8-10%, Si: 0.5-3% Iron-based amorphous alloy composed of. The method of claim 1, Iron-based amorphous alloy, characterized in that it comprises 1-3 atomic% at least one selected from the group of Co, Cu, Nb, W. The method according to claim 1 or 2, The Fe content is 62-64%, the sum of the components other than Fe is 36-38%, the sum of the C + B + P is 19-23% iron-based amorphous alloy. The method according to claim 1 or 2, Iron-based amorphous alloy, characterized in that the amorphous forming capacity (Trg = Tg / Ti) of the alloy is 0.44-0.75. The method according to claim 1 or 2, The amorphous alloy has an iron-based amorphous alloy, characterized in that it has any one shape selected from a ribbon, rod-like, plate. The method according to claim 1 or 2, The amorphous alloy is an iron-based amorphous alloy, characterized in that the plate thickness of 0.5-2mm, width 100-150mm.

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