KR101355464B1 - Rolling method of carbon steels - Google Patents

Abstract

The present invention relates to a rolling method of carbon steel, and more particularly, to a rolling method of high carbon steel for warm rolling of carbon steel on tempered martensite. The rolling method of carbon steel according to the present invention manufactures high strength and high toughness carbon steel by controlling the initial structure just before warm rolling. The rolling method of carbon steel according to the present invention uses a tempered martensite structure as an initial structure just before warm rolling. The rolling method of the carbon steel according to the present invention comprises the steps of roughly rolling the carbon steel on the austenitic temperature above the A1 transformation temperature, quenching the roughly rolled carbon steel to obtain the carbon steel on the martensite, and the carbon steel on the martensite. Tempering and warm rolling the carbon steel on the tempered martensite. According to the rolling method of the carbon steel according to the present invention it is possible to produce a high strength and high toughness material.

Description

Rolling method of carbon steels

The present invention relates to a rolling method of carbon steel, and more particularly, to a rolling method of high carbon steel using carbon steel on tempered martensite as a microstructure immediately before warm rolling.

Several methods have been proposed to increase the strength of carbon steel materials.

The first method is to add alloying elements such as chromium (Cr), molybdenum (Mo) and nickel (Ni) to make high strength carbon steel materials. However, this method not only raises the manufacturing cost but also has a problem that the workability and toughness of the carbon steel material are lowered. Therefore, there is a problem that intermediate heat treatment such as low temperature annealing, spheroidizing annealing, etc. is required while processing the carbon steel material into the final product. In addition, the addition of a large amount of alloy, there is a problem that the alloy component remains as impurities when remelting and refining the carbon steel material for future recycling purposes. In addition, the cost of reprocessing to remove the alloying components is not only to increase the cost but also cause environmental problems.

The second method is to obtain a high strength and high toughness carbon steel by adding a trace amount of alloying component to the carbon steel material and then strictly controlling the manufacturing process. Carbon steel obtained in this way is called HSLA steel (High strength low alloy steel). Or micro-alloying steel.

The conventional method of rolling HSLA steel is to finish rolling at an A1 transformation temperature or more at which discontinuous recrystallization of austenite phase occurs, thereby improving final mechanical properties after phase transformation by miniaturizing the size of austenite grains. However, this method has a limitation in miniaturizing the grain size of the final microstructure due to the phase transformation accompanying cooling the grains below the A1 transformation temperature even if the grains of the austenite phase are refined. Therefore, there was a limit to improving the final mechanical properties.

Patent Publication Nos. 2006-20600 and 2006-35603 disclose microstructures of pearlite by slow cooling to 500 ° C. after rough rolling above the A1 transformation temperature at which discontinuous recrystallization of austenite phase occurs. A method of performing finish rolling in a region is disclosed. Although the present rolling method uses fine pearlite as an initial structure just before warm rolling, there is a limit in producing a high strength and high toughness material. The strength is 1000 MPa or less, and in particular, Charpy impact energy is only about 20J at room temperature.

The present invention aims to provide a new rolling method which can improve the strength and toughness of carbon steel by improving the problems of the conventional rolling method described above.

The rolling method of carbon steel according to the present invention manufactures high strength and high toughness carbon steel by controlling the initial structure just before warm rolling.

The rolling method of carbon steel according to the present invention uses a tempered martensite structure as an initial structure just before warm rolling.

The rolling method of carbon steel according to the present invention comprises the steps of quenching carbon steel on austenite to obtain carbon steel on martensite, tempering carbon steel on martensite and warm rolling on tempered martensite carbon steel. It includes a step.

Obtaining the carbon steel on the martensite may include roughly rolling the carbon steel on the austenitic at an A1 transformation temperature or higher, and quenching the roughly rolled carbon steel to obtain the carbon steel on the martensite.

According to the rolling method of the carbon steel according to the present invention it is possible to produce a high strength and high toughness material. In particular, carbon steel with Charpy impact energy at room temperature of 38 J or more can be produced.

In addition, the step of warm rolling includes rolling of at least two passes, rolling with a caliber roll having at least one elliptical shape, and having a ball having at least one circular shape. It is preferable that it is a step which goes through rolling by a roll.

Further, the step of warm rolling is more preferably a step of alternately passing rolling by a ball roll having an elliptic ball and rolling by a ball roll having a ball-shaped ball.

In the rolling method of the carbon steel according to the present invention, high strength and high toughness carbon steel can be obtained by adjusting the warm rolling initial structure to the tempered martensite structure. In addition, according to the rolling method of carbon steel according to the present invention, carbon steel having a Charpy impact energy at room temperature of 38 J or more can be manufactured.

1 is a view showing a temperature profile of the rolling method of carbon steel according to an embodiment of the present invention.
Figure 2 is a schematic diagram showing the ball of the ball roll used in the rolling method of carbon steel according to an embodiment of the present invention.
3 is a view showing a temperature profile of a conventional hot rolling method.
4 is a view showing a temperature profile of a conventional warm rolling method.
5 is a photograph showing a contrast between the microstructure of the carbon steel according to the embodiment and the carbon steel according to an embodiment of the present invention.
FIG. 6 is a diagram illustrating a nominal stress-nominal strain curve of carbon steels according to an embodiment of the present invention and carbon steels according to comparative examples. FIG.
FIG. 7 is a view illustrating a Charpy impact energy-temperature curve of carbon steels according to an embodiment of the present invention and carbon steels according to comparative examples. FIG.
Figure 8 is a photograph showing the shape of the specimen after the Charpy impact energy test of carbon steel according to an embodiment of the present invention and carbon steels according to Comparative Examples.

Hereinafter, the present invention will be described in detail.

The rolling method of carbon steel according to the present invention comprises the steps of roughly rolling the carbon steel on the austenitic temperature above the A1 transformation temperature, quenching the roughly rolled carbon steel to obtain the carbon steel on the martensite, and tempering the carbon steel on the martensite. ), Warm rolling the carbon steel on the tempered martensite.

The present invention can use high strength and high toughness carbon steel by using carbon steel on tempered martensite as an initial structure just before warm rolling.

In the present invention, the high carbon steel billet is reheated to about 1050 to 1150 ° C. which is higher than the A1 transformation temperature at which recrystallization of austenite phase occurs in a heating furnace, and then rough rolling is performed under normal conditions.

Next, the quenched wire rod is quenched and rapidly cooled to room temperature, thereby obtaining carbon steel on martensite. Quenching the austenitic steel through quenching transforms the martensite phase into a non-diffusion transformation. To obtain the martensite phase, it must be quenched so that the formation of pearlite or bainite nuclei does not start. Martensite is formed in austenite because quenching prevents carbon atoms from escaping and is trapped in crystals.

Next, the carbon steel on martensite is tempered to an appropriate temperature below the Al transformation temperature. Carbon steel on martensite has high hardness but low toughness, which makes it difficult to warm. Therefore, the residual stress of the carbon steel on the martensite is removed, and the tempering is performed to lower the hardness and increase the toughness. Tempering is performed at 450 ~ 650 ℃ for 1 ~ 5 hours.

Next, the tempered martensitic carbon steel is rolled warmly. Rolling temperature is 450-650 degreeC. The rolling proceeds in two or more passes, and it is preferable that the rolling is carried out by at least one pass by a rolling roll having an elliptical ball. It is more preferable to alternate the rolling by the ball roll having an elliptical ball and the rolling by the ball roll having a circular ball.

Hereinafter, the present invention will be described in detail by way of examples.

<Examples>

1 is a view showing a temperature profile of the rolling method of carbon steel according to an embodiment of the present invention. Hereinafter, a rolling method according to the present embodiment will be described with reference to FIG. 1.

In this example, a high carbon steel billet containing 0.8 wt% carbon was used as an intermediate material. The billet was heated at 1100 ° C. for 1 hour and then air cooled to 900 ° C.

Next, the air-cooled billet was rough-rolled in a wire mill and processed into a rod shape.

Next, the roughly rolled rod-shaped material was quenched and rapidly cooled to room temperature to obtain a martensite phase microstructure. Then, by heating to 500 ℃ and tempered for 1 hour to obtain a microstructure on the tempered martensite phase.

Next, warm rolling was performed using a ball roll having an elliptic ball at 500 ° C. The reduction rate after one pass was 20%. Then, using a ball roll having a circular ball again, warm rolling was performed. The reduction rate after 2 passes was 19.5%. The method was repeated to proceed with a total of eight passes of warm rolling.

2 shows the ball mold of the ball roll used in this embodiment. (A) of FIG. 2 shows an elliptical ball, and (b) shows a circular ball.

&Lt; Comparative Example 1 &

This comparative example corresponds to the conventional hot rolling process. Hereinafter, a rolling method according to the present comparative example will be described with reference to FIG. 3. In this comparative example, a high carbon steel billet containing 0.8 wt% carbon was used as an intermediate material as in the example. The billet was heated at 1100 ° C. for 1 hour and then air cooled to 900 ° C.

Next, hot rolling was performed at 900 ° C., and air cooled to room temperature.

Comparative Example 2

This comparative example corresponds to the conventional warm rolling process. Hereinafter, a rolling method according to the present comparative example will be described with reference to FIG. 4. In this comparative example, a high carbon steel billet containing 0.8 wt% carbon was used as an intermediate material as in the example. The billet was heated at 1100 ° C. for 1 hour and then air cooled to 900 ° C.

Next, the air-cooled billet was rough-rolled in a wire mill and processed into a rod shape.

Next, the roughly rolled rod-shaped material was cooled to 500 ° C. in air to obtain a microstructure of pearlite.

Next, a total of 8 passes of warm rolling were performed at the same method as in Example at 500 ° C.

Hereinafter will be described by comparing the mechanical properties of the carbon steel according to the embodiment of the present invention and the carbon steel according to the comparative examples.

5 is a photograph showing a contrast between the microstructure of the carbon steel according to the embodiment and the carbon steel according to an embodiment of the present invention. 5A is an SEM photograph of carbon steel according to an embodiment of the present invention, FIG. 5B is an SEM photograph of carbon steel according to Comparative Example 1, and FIG. 5C is an SEM photograph of carbon steel according to Comparative Example 2. In FIG. 5, RD indicates a rolling direction, and TD means a direction perpendicular to both the rolling direction and the reduction direction ND. Reduction reduction direction ND means the direction in which reduction reduction is performed by the roll at the time of rolling.

As can be seen in Figure 5a, in the carbon steel according to an embodiment of the present invention, the spherical cementite particles (white particles on the photo) of the carbon steel according to Comparative Example 2 and other forms are distributed in the rolling direction. This means that the quenched vaccinated steel (referred to as high carbon steel with a carbon content of 0.8% by weight, which is the type of steel used in this example) has a relatively low energy of carbon in martensite or residual austenite during the holding time at the warm rolling temperature of 500 ° C. This is because it precipitates in cementite form at high grain boundaries. That is, since the surface energy is increased and the driving force for spheroidization is increased due to many irregularities generated at the cementite interface due to slip during deformation, a spheroidized cementite having a different shape from that of Comparative Example 2 is formed. The cementite particles formed at the grain boundaries thus serve to delay the displacement of dislocations during plastic deformation, thereby improving hardness and strength.

As can be seen in Figure 5b, in the carbon steel according to Comparative Example 1 non-coarse coarse and complete form of pearlite colonies are observed. At this time, the lamellar spacing of the pearlite colony is approximately 0.5 μm-1 μm, forming a sparse lamellar structure.

As can be seen in Figure 5c, the microstructure of the carbon steel subjected to the warm rolling according to Comparative Example 2, the cementite particles are distributed in the form of a band in the rolling direction (RD). Although such cementite particles form a layered structure in part, they do not form a complete form of pearlite colonies, but are segmented and spherical. These segmented and spheroidized particles act as obstacles to grain boundary movement by zener pinning, contributing to the improvement of stiffness and toughness of the material. The spacing between cementite is about 0.1 mu m, which is narrower than the layer spacing of the pearlite colony at the same position of Comparative Example 1. As a result, in view of the fact that cementite is a barrier to dislocation transfer, the carbon steel according to Comparative Example 2 having a more compact cementite interval shows higher hardness, tensile strength and yield strength than carbon steel of Comparative Example 1.

FIG. 6 is a diagram illustrating a nominal stress-nominal strain curve of carbon steels according to an embodiment of the present invention and carbon steels according to comparative examples. FIG. As can be seen in Figure 6, the shape of the nominal stress-nominal strain curve for each process (by initial structure) obtained through the tensile test shows a marked difference between the Examples and Comparative Examples. This is related to the size of the ferrite grains.

This difference in grain size acts as a major factor, which leads to a difference in yield strength and tensile strength. Example and Comparative Example 2 compared to Comparative Example 1 (yield strength: 517 MPa, tensile strength: 942 MPa) yield strength is as high as 422 MPa and 460 MPa, respectively. Tensile strength is as high as 118 MPa and 46 MPa, respectively. Yield ratio, which is the ratio of yield strength and tensile strength, is 0.55, 0.89, and 0.99 in Comparative Example 1, Comparative Example 2, and Example 9, respectively, to which hot rolling is applied to reproduce the hot rolling process. Comparative Example 1 shows a big difference. The yield ratio close to Comparative Example 2 and Example 1 applying the warm hollow rolling process means that the plastic instability, ie, necking, occurred with almost no hardening after work as a characteristic of the ultrafine grain structure.

The toughness of a material can be determined to some extent by the tensile test, a static test, under the stress-strain curve. In the static state, the toughness of Comparative Example 1, Comparative Example 2 and Example was 147 MN / m ² , 145 MN / m ^2, and 145 MN / m ² , respectively, and did not show a difference between processes. However, the impact toughness was very excellent in the Examples compared to the comparative examples. This can be confirmed through the Charpy impact test results below.

FIG. 7 is a view illustrating a Charpy impact energy-temperature curve of carbon steels according to an embodiment of the present invention and carbon steels according to comparative examples. FIG. The Charpy impact energy is a value obtained by dividing the energy absorbed when the impact force is given to the carbon steel in the cross-sectional area, and indicates the toughness and brittleness of the carbon steel.

Looking at the Charpy impact energy of each process obtained through the Charpy impact test according to the temperature change, the impact energy of the Example was 38.9J at room temperature, about 4 times compared to Comparative Example 1 (9.9J) and Comparative Example 2 (19.8J), respectively. 2 times higher. The reason why the Charpy impact energy of Example and Comparative Example 2 is higher than that of Comparative Example 1 is that first, the grain size of the microstructures of Comparative Example 2 and Example is reduced compared to Comparative Example 1. Second, as can be seen in Figure 5, in the case of Comparative Example 1 pearlite colonies do not have a specific direction, in the case of Comparative Example 2 and Example cementite particles arranged in parallel with the rolling direction affects the development of cracks due to impact Because it is crazy. That is, in the case of Comparative Example 1, since the complete pearlite colony generated after the rolling at the A3 transformation temperature or more has no specific orientation, when the crack progresses due to the impact, the crack advances perpendicularly to the rolling direction and fracture occurs. This is because in the case of Example 2 and Example, the impact of the impact is dispersed by cementite long distributed in the rolling direction due to the rolling under the A1 transformation temperature after the transformation. This can be confirmed through the shape of the specimen after the Charpy impact test shown in FIG. 8 (a) is a specimen according to the embodiment, (b) is a specimen according to Comparative Example 1, (c) is a specimen according to Comparative Example 2.

Although Example and Comparative Example 2 have cementite particles distributed in parallel with the rolling direction in the same manner, the reason why the Charpy impact energy is very large compared to Comparative Example 2 is that the Example is in the middle of the fracture surface of the Example as shown in FIG. This is due to delamination at the location.

As described above, the carbon steel according to the embodiment of the present invention was superior in mechanical properties such as yield strength, tensile strength, Charpy impact energy compared to the carbon steel of Comparative Example 1. Moreover, Charpy impact energy was very high compared with the carbon steel of the comparative example 2.

Using these drawings, in the step of warm rolling the carbon steel on tempered martensite, considering the yield strength and elongation at break required for the carbon steel, the tempering temperature, time and rolling temperature can be adjusted.

Claims (5)

In the rolling method of carbon steel,
Quenching carbon steel on austenite to obtain carbon steel on martensite,
Tempering carbon steel on martensite,
A method of rolling carbon steel, comprising the step of warm rolling carbon steel on tempered martensite. The method of claim 1,
Obtaining carbon steel on the martensite,
And roughly rolling the carbon steel on the austenite at an A1 transformation temperature or higher, and quenching the rolled carbon steel to obtain carbon steel on martensite. 3. The method of claim 2,
The rough rolling step is a step of rough rolling the carbon steel on the austenite above the A3 transformation temperature. The method of claim 1,
The warm rolling step may include two or more passes of rolling, and rolling by a caliber roll having at least one elliptical shape (caliber) and a ball having a ball having at least one circular shape. Rolling method of carbon steel, characterized in that the step of undergoing rolling by. 5. The method of claim 4,
The warm rolling step is a rolling method of the carbon steel, characterized in that the step of rolling by a ball roll having an elliptic ball and a ball roll having a ball-shaped ball alternately.

Images