KR20210131725A - Free-Cutting Steel Round Bar with Improved Electomagnetic Property - Google Patents

Abstract

The present invention relates to a granite free-cutting steel round bar, which adds a small amount of alloying elements, composed of 0.5-1.0 wt% of carbon, 1.5-3.0 wt% of silicon, 0.005-0.30 wt% of manganese, equal to or less than 0.01 wt% of phosphorus, equal to or less than 0.01 wt of sulfur, 0.0002-0.04 wt% of titanium, 0.001-0.04 wt of aluminum, 0.001-0.006 wt% of boron, and 0.006-0.011 wt% of nitrogen, to improve machinability of a steel material and improves machinability and electromagnetic property of the manufactured round bar.

Description

Graphite Free-cutting Steel Round Bar with Improved Electromagnetic Property}

The present invention relates to a graphite steel round bar as a material of electromagnetic components such as solenoids, and more specifically, 0.5 to 1.0 wt% of carbon, 1.5 to 3.0 wt% of silicon, 0.005 to 0.30 wt% of manganese, 0.01 wt% of phosphorus Below, sulfur 0.01 wt% or less, titanium 0.0002 ~ 0.04 wt% or less, aluminum 0.001 ~ 0.04 wt%, boron 0.001 ~ 0.006 wt%, nitrogen 0.006 ~ 0.011 wt% of trace alloy elements are added to improve the workability of the material steel and , to a graphite free-cutting steel round bar with improved machinability and electromagnetic performance of the manufactured round bar.

In general, parts applied to industrial machines and automobiles are processed into necessary shapes by cutting, casting, or forging processes. Since the amount is large, when the material machinability such as chip handleability and machining surface roughness generated during cutting is deteriorated, loss of parts may occur and product production cost may be greatly increased.

In addition, when parts are processed through casting or forging processes, products with complex shapes cannot be precisely implemented compared to parts manufacturing methods by cutting, so intermediate products close to the shape of final parts are processed by casting or forging processes. Then, by processing into the shape of the final product through a cutting process, only one process of cutting, casting, or forging is performed to solve the problem caused by processing the product.

As the strength of the steel material of the product increases, the wear of the cutting tool increases and the energy consumption during the machining process increases due to the difficulty of cutting. , 22, 23), SUM (22L, 24L), and free-cutting steel such as SUM (31, 41, 44) are used.

In particular, in the case of manufacturing a product through forging and cutting, the material steel must have forging performance as well as machinability for smooth cutting. It was difficult.

However, in the case of conventional free-cutting steel using a machinability imparting element, cold forgeability is very low, and it may cause environmental pollution problems during the manufacturing process, and has a problem of low manufacturing efficiency.

In addition, among the parts produced by cutting, an electromagnetic material used for an electric system of an automobile or a part of a home appliance mainly uses a Si-containing steel material having a high magnetic field response speed so as to have high electromagnetic properties.

In order to obtain the coercive force, which is the magnitude of the magnetic field in the opposite direction, which is the magnitude of the magnetic field in the opposite direction, and the magnetic flux density at a specific frequency, required for the residual magnetic value to be 0 when the magnetic field is removed from a ferromagnetic material having a magnetic field in a saturated state by applying a magnetic field as the electromagnetic characteristic required by the component. There are iron loss, which is defined as energy loss that occurs in the process of magnetizing an iron core, and magnetic flux density, which means the amount of magnetic flux passing through a unit area.

Elements added to steel to improve machinability and electromagnetic performance, respectively, have opposite characteristics from the point of view of chemical composition. However, the addition of a solid solution strengthening element such as Si causes a decrease in coercive force, iron loss, magnetic flux density, and the like, and thus is not preferable from the viewpoint of electromagnetic properties.

In order to solve this problem, graphite free-cutting steel such as graphite steel with excellent machinability, coercive force and iron loss characteristics of Republic of Korea Patent Publication No. 10-1674826 (registered on November 3, 2016) was developed, and graphite steel contains a large amount of Si in steel. Precipitation of fine graphite grains was induced in the ferrite matrix or inside the ferrite and pearlite matrix.

The fine graphite grains formed in the internal microstructure of graphite steel act as a source of cracks during cutting and serve as a chip breaker to improve machinability and cold forgeability. It improves electromagnetic performance such as iron loss and magnetic flux density.

However, when carbon is added to steel, since it is precipitated as metastable cementite, it is difficult to precipitate graphite grains in steel without additional heat treatment, and decarburization occurs during a long heat treatment process, which may adversely affect product performance.

In addition, when graphite grains in steel are precipitated through graphitization heat treatment for a long time, the possibility of cracking increases as the graphite grains are coarsely precipitated, thereby lowering the cold short burning performance, and when the graphite grains precipitated in an irregular shape are unevenly distributed During cutting, the distribution of physical properties is not uniform, so chip breakability and surface roughness are greatly deteriorated, and thus the lifespan of the tool may be shortened.

Therefore, there is a need to provide graphite steel in which fine graphite grains formed during graphitization heat treatment are uniformly distributed in a regular shape in the microstructure, and the heat treatment time can be shortened.

In addition, when manufacturing electromagnetic components such as hydraulic solenoid valves, drawing must be performed to process the graphite free-cutting steel wire rod into a round bar bar of the standard required by the component producer. Since a large amount of breakage may occur during operation, drawing is performed after graphitization heat treatment.

However, as shown in FIG. 1 , ferrite, which is the base material structure of graphite free-cutting steel with ferrimagnetism properties, exhibits magnetism in atoms, molecules, or lattice units, and is arranged in opposite directions between neighboring magnetic units, but the size is different. However, if the dislocation density in ferrite increases due to cold working, etc., the electromagnetic properties may decrease, improving the workability of graphite free-cutting steel, which is the material steel, while improving the machinability and electromagnetic properties. It is required to provide a round bar with improved performance at the same time.

Republic of Korea Patent Publication No. 10-1674826 (Registered on Nov. 3, 2016)

In an embodiment of the present invention, an object of the present invention is to provide a round bar bar that is easily manufactured through graphite free-cutting steel with improved workability.

In an embodiment of the present invention, by improving machinability, an object of the present invention is to provide a round bar bar capable of improving machining precision when manufacturing an electromagnetic component through cutting.

An embodiment of the present invention aims to provide a round bar with improved electromagnetic performance.

According to an embodiment of the present invention, in a round bar applied to an electromagnetic component, the material steel of the round bar is carbon (C) 0.5 to 1.0 wt%, silicon (Si) 1.5 to 3.0 wt%, manganese (Mn) 0.005 to 0.30 wt% wt%, phosphorus (P) 0.01 wt% or less, sulfur (S) 0.01 wt% or less, titanium (Ti) 0.0002 to 0.04 wt% or less, aluminum (Al) 0.001 to 0.04 wt%, boron (B) 0.001 to 0.006 wt% %, nitrogen (N) 0.006~0.011 wt% of trace alloy elements and the remainder iron (Fe) and other unavoidable impurities, but the addition ratio between trace alloy elements in the steel material is 0.3 ≤ {7.4N ₂ - (1.1Ti + 1.9) Al + 5.1B}} x 100 ≤ 1.5 satisfies the relation.

According to an embodiment of the present invention, the round bar is manufactured through a process consisting of a raw material steel homogenization heat treatment process, a raw steel hot rolling process, a cooling process, a heat treatment process, a drawing process, and a cutting process.

According to an embodiment of the present invention, the material steel homogenization heat treatment process is performed at a temperature in the range of 1100 to 1300 °C, and the hot rolling process for the material steel is performed at a temperature in the range of 800 to 1000 °C.

According to an embodiment of the present invention, the heat treatment process is performed at a temperature in the range of 730 to 770° C. for less than 2 hours.

According to an embodiment of the present invention, the steel of the round bar bar has a microstructure of ferrite and graphite grains formed, the graphite grains in the microstructure are formed to a size of 5 μm or less, and the phase fraction of the graphite grains is in the range of 1.5 to 3%. area fraction.

According to an embodiment of the present invention, the ferrite dislocation density of the microstructure in the steel of the round bar bar is formed to ^{be 1.5x10 14} m ^{-2 or less.}

According to an embodiment of the present invention, the drawing process is performed at a temperature in the range of 80 ~ 300 ℃.

According to an embodiment of the present invention, when the drawing process is performed, the reduction rate of the cross-section of the round bar is formed within the range of 15 to 25%.

According to an embodiment of the present invention, in the cutting process, the die clearance between the cutting punch and the mold is formed within 1 to 8% of the drawn round bar blank diameter, and the incidence angle between the mold and the round bar blank diameter is in the range of 0.2 to 1.5°. It is formed within and is carried out at a temperature of 100° C. or higher.

According to an embodiment of the present invention, there is an effect that, when manufacturing a round bar bar, rolling or drawing processing can be performed more easily by improving the workability of graphite free-cutting steel.

According to an embodiment of the present invention, by improving the machinability of the round bar made of graphite free-cutting steel, there is an effect of processing the round bar and improving the processing precision when manufacturing the electromagnetic component.

According to an embodiment of the present invention, there is an effect that can improve the electromagnetic performance of the manufactured round bar.

1 is a view showing the arrangement of magnetism formed inside a device having a quasi-ferromagnetic property.
2 is a view showing a phase diagram of the Fe-C (graphite) stable system.
3 is a view showing the impact toughness change according to the processing temperature condition of the drawn steel material.
Figure 4 is a view showing the position of the gap (clearance) formed between the mold, the punch, and the round bar during cutting of the round bar.
5 is a view comparing the shape of the cut surface between the good product and the bad product of the round bar bar in which the cutting processing is completed.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

It will be described in detail focusing on the parts necessary to understand the operation and operation according to the present invention.

While describing the embodiments of the present invention, descriptions of technical contents that are well known in the technical field to which the present invention pertains and are not directly related to the present invention will be omitted.

This is to more clearly convey the gist of the present invention without obscuring the gist of the present invention by omitting unnecessary description.

In addition, in describing the components of the present invention, different reference numerals may be assigned to components of the same name according to the drawings, and the same reference numerals may be given even though they are different drawings.

However, even in this case, it does not mean that the corresponding components have different functions depending on the embodiment or that they have the same function in different embodiments, and the function of each component is the corresponding embodiment. It should be judged based on the description of each component in

In addition, the technical terms used in this specification should be interpreted in the meaning generally understood by those of ordinary skill in the art to which the present invention belongs, unless otherwise specifically defined in this specification, and excessively comprehensive It should not be construed as meaning or in an excessively reduced meaning.

Also, as used herein, the singular expression includes the plural expression unless the context dictates otherwise.

In the present application, terms such as "consisting of" or "comprising" should not be construed as necessarily including all of the various components or various steps described in the specification, some of which components or some steps are It should be construed that it may not include, or may further include additional components or steps.

The graphite free-cutting steel round bar with improved electromagnetic properties according to an embodiment of the present invention is applied to electromagnetic components such as hydraulic solenoid valves, and at the same time improves electromagnetic performance such as improved coercive force, magnetic flux density, and low core loss, In order to improve the cutting performance, trace alloy elements are added in addition to iron (Fe) and other unavoidable impurities in the raw material steel of the round bar bar.

Trace alloying elements added to the steel are 0.5 to 1.0 wt% of carbon (C), 1.5 to 3.0 wt% of silicon (Si), 0.005 to 0.30 wt% of manganese (Mn), and 0.01 wt% or less of Phosphorus (P), 0.01 wt% or less of sulfur (S), 0.0002 to 0.04 wt% or less titanium (Ti), 0.001 to 0.04 wt% aluminum (Al), 0.001 to 0.006 wt% boron ( B) and 0.006-0.011 wt% of nitrogen (N).

The changes in the electromagnetic and cutting performance characteristics of steel due to the trace alloy elements added to the raw material of the round bar bar and the reasons for limiting the amount of each trace alloy element are explained as follows.

1) Carbon (C)

Carbon is an essential element for forming graphite grains in the microstructure of the steel material.

In the material steel of the present invention, it is necessary to graphitize the cementite of pearlite in the steel through graphitization heat treatment to form graphite steel having a microstructure including ferrite and graphite.

When pearlite is present in addition to ferrite and graphite in the microstructure of steel, the hardness of the manufactured round bar increases and machinability decreases during cutting of the round bar, resulting in increased cutting tool wear, and electromagnetic fields such as coercive force and iron loss. Characteristics may deteriorate rapidly.

In addition, the generated graphite grains improve the impact toughness and ductility of the raw material steel, and serve as a crack source during machining of the raw material to serve as a chip breaker during cutting of the steel, thereby improving the machinability of the raw material.

In order to form a sufficient amount of graphite grains, the cementite generated during cooling of the material steel is graphitized as quickly as possible by directly precipitating graphite during hot rolling of the material steel or by increasing the carbon activity. It is preferable to add more than wt% of carbon, but when the carbon content exceeds 1.0 wt%, the effect of increasing carbon activity is saturated and the hot rolling property is reduced, so it is preferable to limit the amount of carbon to 0.5 to 1.0 wt% do.

2) Silicon (Si)

Silicon acts as a deoxidizer in manufacturing steel, and is a graphitization promoting element that destabilizes iron oxide (cementite) in the steel so that carbon in the microstructure can be precipitated as graphite.

In addition, silicon improves the electromagnetic properties of the manufactured round bar bar, and it is preferable to limit the addition ratio in the steel material to 1.5 to 3.0 wt%.

When the content of silicon is less than 1.5 wt%, the effect of adding silicon cannot be sufficiently obtained.

When the silicon content exceeds 3.0 wt%, the effect of promoting graphitization is saturated, and the improved effect cannot be obtained due to the additional addition. .

In addition, as the number of non-metallic inclusions increases, the manufactured round bar is brittle, and excessive decarburization is induced in the material steel when the hot rolling process is performed.

3) Manganese (Mn)

Manganese is an element that affects the strength improvement and impact properties of the material steel. It improves the rolling performance of the material steel, reduces brittleness, and inhibits abnormal grain growth in the microstructure of the material steel by forming MnS.

The manganese content is preferably limited to 0.005 to 0.30 wt%.

When the manganese content is 0.005 wt% or less, the effect of improving the strength of the steel material is insufficient, and MnS is not formed, which may cause high-temperature deformation cracking due to the sulfur (S) contained in the steel material during processing of the material steel.

When the manganese content exceeds 0.30 wt%, the coarsely formed MnS may act as a nucleus from which BN is precipitated, and the composite precipitate of MnS and BN reduces the electromagnetic performance of the material steel and lowers the graphite generation rate in the microstructure. This increases the heat treatment cost of the material steel.

4) Phosphorus (P)

Phosphorus serves to promote the graphitization of carbon in the microstructure of the material steel, but at the same time increases the hardness of ferrite, reduces the toughness of the round bar produced by segregation at grain boundaries, reduces the resistance to delayed fracture, and promotes the occurrence of surface defects. Since it has side effects, it is preferable to limit the content to 0.01 wt% or less.

5) Sulfur (S)

Sulfur not only inhibits the graphitization of carbon in the microstructure of the material steel, but also reduces the toughness of the round bar bar produced by segregation at grain boundaries, and forms a low melting point emulsion, which causes difficulties in performing the hot rolling process of the material steel. It is preferable to limit it to 0.01 wt% or less.

6) Titanium (Ti)

Titanium combines with nitrogen in the steel to form TiN, thereby destabilizing the cementite in the steel, and at the same time providing a site for nucleation of graphite grains to promote graphitization of carbon in the microstructure, and to act as a deoxidizer in the steel. do.

In order to obtain the effect of the addition of titanium, an amount of 0.0002 wt% or more, more preferably 0.01 wt% or more, should be added. , rather, since it may interfere with the graphitization of carbon in the microstructure of the steel material, it is preferable that the content be limited to 0.0002 to 0.04 wt%.

7) Aluminum (Al)

Aluminum, as a strong deoxidizing element, not only contributes to the deoxidation action, but also promotes the decomposition of cementite during graphitization heat treatment of material steel, and has a function of preventing the stabilization of cementite by combining with nitrogen to form ALN, and is formed in steel The resulting aluminum oxide acts as a precipitation nucleus for BN.

When the content of aluminum added to the steel is less than 0.001 wt%, the effect of the addition is insignificant, and when it exceeds 0.04 wt%, the effect of promoting graphitization is saturated and the deformability during hot working of the steel material is greatly reduced. It is preferable that the content of aluminum is formed within the range of 0.001 to 0.04 wt%.

8) Boron (B)

Boron combines with nitrogen to produce boron nitride (BN), and the produced BN acts as a nucleus for the formation of graphite grain crystals while interfering with the stabilization of cementite in steel, thereby promoting graphitization and hardenability of the manufactured round bar bar. will improve

When the boron content is less than 0.001 wt%, the effect of the addition of boron is insufficient, and when the boron content exceeds 0.006%, the effect does not increase due to the additional addition of boron. Since the precipitation lowers the grain boundary strength, thereby inhibiting the hot workability of the steel material, the content of boron is preferably formed within the range of 0.001 to 0.006 wt %.

9) nitrogen (N ₂ )

Nitrogen combines with titanium, boron, and aluminum to form a nitride, and uses the produced nitride as a nucleus to promote crystallization of graphite.

In order to generate a nitride that accelerates the crystallization of graphite, nitrogen must be stoichiometrically added in chemical equivalents of titanium, boron, and aluminum and bisacid. It is preferable to form

In addition, it is advantageous to increase the amount of nitrogen to be added because it improves chip processability during processing of round bar bars manufactured by dynamic strain aging, and it is necessary to add 0.006 wt% or more, but the content is 0.011 When it exceeds wt%, the content of nitrogen is preferably formed within the range of 0.006 to 0.011 wt% because the effect generated by the addition of nitrogen is saturated.

At this time, it is preferable that the amount of nitrogen added in the steel material forms an addition ratio that satisfies the following relation with the addition amount of titanium, aluminum and boron among the trace alloy elements.

0.3 ≤ {7.4N ₂ - (1.1Ti + 1.9Al + 5.1B}} x 100 ≤ 1.5

When the nitrogen addition constant according to the above relation is formed to be less than 0.3, the amount of TiN, AlN or BN-based nitride, which is the nucleation site of graphitization, is insufficient, so the graphitization rate is lowered, and when the nitrogen addition constant exceeds 1.5, in the steel As the amount of dissolved nitrogen is excessively formed, age hardening and toughness of the steel material may be deteriorated. Therefore, it is preferable to form the nitrogen addition constant within the range of 0.3 to 1.5.

The material steel of the round bar according to the embodiment of the present invention contains iron (Fe) and other unavoidable impurities in addition to the trace alloy elements, and the impurities are mixed from the raw material of the steel material or the surrounding environment in the normal steel material manufacturing process, A person skilled in the art knows that the mixing of impurities cannot be completely excluded during the manufacturing process of steel, so the description of the content of impurities and occurrence of changes in properties of steel due to mixing of impurities is omitted.

The manufacturing process of the round bar bar according to an embodiment of the present invention proceeds as the raw material steel homogenization heat treatment process, the raw steel hot rolling process, the cooling process, the heat treatment process, the drawing process, and the cutting process are sequentially progressed.

In order to manufacture a graphite steel ingot that becomes a material steel, in the material steel homogenization heat treatment process, the steel material is subjected to homogenization heat treatment at a temperature in the range of 1100 to 1300 ° C. A hot-rolling process of hot-rolled material steel is performed at a temperature in the range of °C, and in the cooling process, the hot-rolled material steel is cooled through air cooling.

At this time, since the temperature condition during the homogenization heat treatment and hot rolling of the material steel is a normal condition for forming the graphite steel ingot, the explanation of the reason for limiting the temperature will be omitted.

In the heat treatment process, the homogenization heat treatment and the hot-rolled ingot are subjected to graphitization heat treatment at a temperature in the range of 730 to 770 ° C., more preferably at 760 ± 5 ° C. for less than 2 hours. Graphite steel with improved cutting performance such as machinability and machinability is formed.

When the graphitization heat treatment is performed, the cementite of pearlite in the steel is graphitized, and in order to shorten the graphitization time, it is preferable to perform the heat treatment in a temperature region corresponding to a nose in the isothermal transformation curve.

As shown in Fig. 2, the graphitization heat treatment temperature in the temperature range (Tcu ~ Tcl) having a three-phase structure of ferrite + austenite + graphite (α + γ + G) was derived using the Thermo-calc program. According to the -C (graphite) stability diagram, the most ideal heat treatment was performed in the Tcl- (10~40℃) range, and the Tcl temperature was derived based on the commonly known formula below.

Tcl = 727 + 21.6Si + 0.023Si ₂ - 21Cu - 25Mn + Mo +13Cr - 33Ni

Through the heat treatment process, all of the cementite in the steel can be graphitized to achieve a graphitization rate of 100%. do.

Graphitization rate (%) = {Content of carbon in the graphite state in steel (wt%) / Carbon content in steel (wt%)} x 100

100% graphitized means that all of the carbon added in the steel is consumed to produce graphite, and the microstructure in the steel consists of ferrite and graphite grains, and it means a state in which undecomposed pearlite does not exist. , the amount of solid solution carbon in ferrite having an extremely small amount is not considered.

In order to secure the performance such as machinability, coercive force, magnetic flux density, and iron loss characteristics required for the manufactured round bar, it is necessary to secure a certain amount of graphite in the steel. The area fraction of graphite grains formed in the microstructure of the formed graphite steel should be 1.5% or more.

At this time, when the area fraction of the graphite grains exceeds 3%, the improvement effect is not only saturated, but in order to secure the area fraction of the graphite grains exceeding 3%, it is necessary to add carbon in excess of 1 wt% in the steel, Since the increase in the amount of carbon added lowers the hot-rollability and causes difficulties in the manufacturing process of the round bar bar, it is preferable that the area fraction of the graphite grains be formed within the range of 1.5 to 3%.

In addition, the average diameter of the graphite grains is preferably formed in a size of 5 μm or less, the time required for graphitization is shortened through fine graphite grains, and the surface roughness of the cut surface during cutting of the manufactured round bar bar can improve

In the drawing process, the reduction in the area of the round bar (W) generated by the drawing process is formed within the range of 15 to 25%, and the dislocation density generated during the drawing process has a detrimental effect on the electromagnetic performance of the manufactured round bar bar. Therefore, it is preferable to perform graphitization heat treatment after drawing processing so that the ferrite dislocation density of the microstructure in the steel ^{is formed to be 1.5x10 14} m ^{-2 or less.}

Graphitization heat treatment after drawing processing is performed for less than 2 hours, and graphitization heat treatment of hot rolling is performed for 3 to 5 hours. It is preferable to perform the graphitization heat treatment for 2 hours or less for the drawn material and 5 hours or less for the hot-rolled material.

Graphite steel is a steel grade with very low impact toughness at room temperature, and since it is difficult to perform drawing processing, there is a need to prepare a plan to overcome this.

When an impact test is performed while changing the temperature for a certain material, the temperature at which the absorbed impact energy changes rapidly or the property of the fracture surface changes rapidly from ductile to brittle or brittle to ductile is called the transition temperature. The temperature when the maximum value is 1/2 or the brittle fracture factor becomes 1/2 becomes the transition temperature of the impact value.

As a result of the present inventor's research to secure the pull-out workability, it was confirmed that the pull-out workability was improved when an impact toughness value of 10J/cm2 or more was secured. It was confirmed that the drawing process temperature should be carried out at 80°C or higher.

At a temperature of 80° C. or less, the impact toughness is formed at 10 J/cm 2 or less, and low toughness appears, making it difficult to perform the drawing process. At a temperature of 300° C. or more, the effect of improving the impact toughness is saturated.

Therefore, it is preferable that the pultrusion process be performed at a temperature in the range of 80 to 300 ° C. Since the impact transition temperature is formed around 140 ° C. higher than room temperature, it is more preferable that the pultrusion process be performed at a temperature in the range of 140 to 200 ° C.

In the cutting process, the drawn round bar (W) is cut to an appropriate length according to the purpose to form a round bar, and at temperatures below 100°C, the cutting workability may be reduced due to low toughness, so the temperature is maintained at 100°C or higher It is preferable to do it in one state.

Factors affecting the cutting of steel include clearance from the mold (D), stock thickness, and the type and strength of materials. It directly affects the shape of the cut surface of

As shown in FIG. 4, the distance between the mold D is divided into the die clearance between the punch P and the mold D and the angular clearance between the mold D and the round bar W. The gap between the punch (P) and the mold is formed within 1 to 8% of the drawn round bar (W) work diameter, and the incident angle between the mold (D) and the round bar (W) work span is within the range of 0.2 to 1.5°. It is preferable to form

If the gap between the punch (P) and the mold (D) is less than 1% or more than 8% of the diameter of the round bar (W), shear cracks are generated and propagated along the shear band formed during the material cutting process. The cutting process may not occur uniformly, and cutting processability may be reduced.

In addition, if the incident angle between the mold (D) and the round bar (W) material span is less than 0.2° or exceeds 1.5°, the generation direction of the shear deformation band formed in the material cutting process is formed non-uniformly, and cutting processability may be reduced. have.

Component composition of material steel for each test example test example Ingredients (wt%) C Si Mn P S Ti Al B N ₂ 1A 0.7 2.4 0.01 0.005 0.001 0.03 0.005 0.001 0.007 2A 0.9 1.8 0.3 0.005 0.001 0.02 0.01 0.001 0.008 3A 0.8 2.7 0.4 0.005 0.001 0.001 0.038 0.001 0.011 4A 1.0 1.5 0.1 0.005 0.001 0.04 0.001 0.001 0.008 5A 0.5 2.0 0.5 0.005 0.001 0.04 0.001 0.006 0.011 6A 0.6 3.0 0.29 0.005 0.001 0.001 0.003 0.006 0.007 7A 0.55 2.3 0.31 0.005 0.001 0.0002 0.034 0.0002 0.01 8A 0.7 2.32 0.01 0.005 0.001 0.032 0.004 0.003 0.005 9A 0.9 1.91 0.37 0.005 0.001 0.023 0.02 0.002 0.004 10A 0.8 2.59 0.43 0.005 0.001 0.001 0.034 0.001 0.003 11A 1.0 1.58 0.17 0.005 0.001 0.025 0.001 0.002 0.005 12A 0.51 2.15 0.5 0.005 0.001 0.035 0.002 0.006 0.004 13A 0.63 2.89 0.35 0.005 0.001 0.01 0.005 0.006 0.005 14A 0.58 2.24 0.31 0.005 0.001 0.0005 0.031 0.0002 0.004

After casting into an ingot using Test Examples 1A to 14A of a steel having a component composition according to Table 1 as a sample, homogenization heat treatment was performed at 1250 ° C. for 8 hours, and then hot rolling and air cooling at 800 to 1000 ° C. to have a diameter of 25 mm. Steel was manufactured.

Table 2 shows the measurement results of ferrite and graphite grain area fraction, machinability, coercive force and iron loss characteristics among the microstructures of graphite steel prepared by performing graphitization heat treatment of Test Examples 1A to 14A at 760° C. for 2 hours.

Microstructure and Free Machining of Material Steel by Test Example

test example
Trace alloy element addition constant microstructure free machinability microstructure
Configuration Graphitization rate
(%) black smoke
area fraction
(%) graphite granules
average size
(μm) tool
wear depth
(μm)
chip segmentability 1A 0.37 F+G 100 2.45 1.5 115 Great 2A 1.26 F+G 100 2.82 1.3 105 Great 3A 0.22 F+G 100 2.86 1.6 110 Great 4A 0.76 F+G 100 2.77 1.4 100 Great 5A 0.45 F+G 100 1.73 1.5 130 Great 6A 1.45 F+G 100 2.09 1.6 120 Great 7A 0.74 F+G 100 1.91 1.5 125 Great 8A -2.16 F+G+P 60 2.45 1.4 192 commonly 9A -4.42 F+G+P 35 2.82 1.6 300 error 10A -4.90 F+G+P 30 2.86 1.7 367 error 11A -0.29 F+G+P 80 2.77 1.3 170 commonly 12A -4.35 F+G+P 40 1.76 1.5 325 error 13A -1.42 F+G+P 70 2.19 1.6 171 commonly 14A -3.20 F+G+P 50 2.01 1.5 250 error

(F: ferrite, P: pearlite, G: graphite)

In Table 2, the tool wear depth of each test example is after graphitization heat treatment, turning a steel material processed into a rod shape with a diameter of 30 mm to a diameter of 20 mm, and then measuring the worn depth of the tool. It was carried out under cutting conditions in which a feed rate and a cutting speed of 0.05 mm/rev were applied.

The chip segmentability results were evaluated by dividing them into three stages: good, average, and poor, respectively, excellent when chips were divided in 2 volumes or less, average when chips were divided in volumes 3 to 6, and 7 or more volumes. It was judged as defective when the chip was divided.

As shown in Tables 1 and 2 above, in the case of Test Examples 1A to 7A, which satisfy the component composition and the addition constant ratio of the trace alloy elements proposed in the present invention, the microstructure of the steel is composed of ferrite and graphite, and the graphitization rate is 100%, fine graphite grains could be sufficiently formed, and thus, the free cutting properties such as tool wear and chip breakability were significantly improved compared to Test Examples 8A to 14A, which did not satisfy the component composition and the addition constant ratio of trace alloy elements. It can be seen that excellent values are shown.

Ferrite dislocation density and electromagnetic force by test example test example drawing processing
section reduction rate
(%) in ferrite
dislocation density
(m ^-2 ) electromagnetic coercive force
(A/m) iron loss
(W/kg) magnetic flux density
(T) 1B 15 1.2 x 10 ¹⁴ 1000 25 1.5 2B 20 1.5 x 10 ¹⁴ 1040 28 1.6 3B 25 1.1 x 10 ¹⁴ 1080 25 1.5 4B 16 1.3 x 10 ¹⁴ 1010 30 1.6 5B 20 1.5 x 10 ¹⁴ 1050 29 1.5 6B 25 1.1 x 10 ¹⁴ 1090 32 1.7 7B 25 1.4 x 10 ¹⁴ 1100 30 1.6 8B 15 5.2 x 10 ¹⁴ 1500 55 0.9 9B 20 6.6 x 10 ¹⁴ 1700 60 0.8 10B 25 7.1 x 10 ¹⁴ 2000 85 0.6 11B 15 5.3 x 10 ¹⁴ 1600 50 0.9 12B 20 6.9 x 10 ¹⁴ 1800 60 0.8 13B 25 7.9 x 10 ¹⁴ 1950 77 0.7 14B 25 7.7 x 10 ¹⁴ 1900 80 0.6

According to Table 3, Test Examples 1B to 7B are wire rods subjected to graphitization treatment after drawing, Test Examples 8B to 14B are wire rods subjected to graphitization treatment and then drawing processing, and Test Examples 1B to 7B are Test Examples 8B to 14B and When compared, it can be seen that the dislocation density, which affects the electromagnetic performance, is distributed low, indicating superior electromagnetic properties.

Electromagnetic properties were measured by taking a ring solenoid specimen from graphitized heat-treated steel, and winding a copper wire 100 times in primary and 20 times in secondary to determine the BH (magnetic flux density - magnetic field strength) curve and iron loss value. were measured, and the coercive force, iron loss, and magnetic flux density were compared based on the value at 1.0T (tesla).

Drawing processability by test example
test example drawability wire diameter
(mm) drawing processing
Section reduction rate (%) warm drawing
Processing temperature (℃) drawability Number of breaks (number of times/ton) Judgment 1D 20 20 80 0 Good 2D 25 25 100 0 Good 3D 30 15 150 0 Good 4D 30 20 200 0 Good 5D 30 25 250 0 Good 6D 20 15 300 0 Good 7D 20 15 0 18 error 8D 25 20 25 15 error 9D 30 25 50 10 error 10D 30 30 60 5 error 11D 20 20 80 0 Good 12D 25 25 100 0 Good 13D 30 15 150 0 Good 14D 30 20 200 0 Good 15D 30 25 250 0 Good 16D 20 15 300 0 Good 17D 20 15 0 18 error 18D 25 20 25 15 error 19D 30 25 50 10 error 20D 30 30 60 5 error

In each test example of Table 4, wire rods having a diameter of 25 to 30 mm according to Examples 1A and 4A of Tables 1 and 2 were used, and the drawing process was performed under normal conditions at a temperature of 0 to 300 ° C through induction heating. It was carried out so as to show a reduction in section in the range of ~25%.

Test Examples 1D to 6D and 11D to 16D in Table 4 show test values with zero breakage during pultrusion, and have superior drawability compared to Test Examples 7D to 10D and 17D to 20D in which breakage occurred, and thus 80 ℃ It can be seen that the possibility of breakage increases when drawing is performed at a temperature below the temperature.

Cutting property by test example test example parting machinability die clearance
(%) cutting test material
Temperature (℃) broken cutting edge
Occurrence rate (%) cotton crack
Generation rate (%) Judgment 1E 2.5 100 0 0 Good 2E 2.5 150 0 0 Good 3E 2.5 200 0 0 Good 4E 2.5 220 0 0 Good 5E 2.5 300 0 0 Good 6E 7.5 100 0 0 Good 7E 7.5 150 0 0 Good 8E 7.5 200 0 0 Good 9E 7.5 220 0 0 Good 10E 7.5 300 0 0 Good 11E 2.5 25 50 55 error 12E 2.5 50 33 40 error 13E 2.5 70 20 30 error 14E 2.5 90 10 20 error 15E 7.5 25 75 80 error 16E 7.5 50 63 70 error 17E 7.5 70 50 60 error 18E 7.5 90 20 35 error

The test example used for the evaluation of cutability of Table 5 was applied to the steel material according to the test example of 2B of Table 3, and Test Examples 1E to 18E were subjected to a cutting workability test using a commonly used shearing machine.

At this time, in the test example of each cutting process, the temperature condition in the range of 0~300℃ is applied to the material drawn through induction heating, and the die clearance between the punch (P) and the mold (D) is 1 of the workpiece diameter. At ~8%, the test was conducted under the condition that the angular clearance between the mold (D) and the round bar (W) was 1.0°.

During cutting, cracks or cracks may occur on the cut surface as shown in FIG. 5, and it can be seen that in Test Examples 11E to 18E, the cut surface cracking rate and the cut surface cracking rate are higher than those of Test Examples 1E to 10E. In order to improve cutting workability through the comparison of the rate of breakage at the cutting edge and the rate of cracking at the cutting edge, which are the criteria for evaluating the cutting workability of the drawn material during the test period, it can be confirmed that the cutting processing is preferably performed while maintaining a temperature of 100 ° C or higher. .

Although embodiments of the present invention have been described with reference to the above, those skilled in the art to which the present invention pertains will understand that the present invention may be embodied in other specific forms without changing the technical spirit or essential characteristics thereof.

Therefore, the embodiments described above are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention described in the above detailed description is indicated by the following claims, meaning and All changes or modifications derived from the scope and its equivalents should be construed as being included in the scope of the present invention.

W: round bar
D: mold
P: punch

Claims (9)

In the round bar applied to the electromagnetic component,
The material steel of the round bar is carbon (C) 0.5 to 1.0 wt%, silicon (Si) 1.5 to 3.0 wt%, manganese (Mn) 0.005 to 0.30 wt%, phosphorus (P) 0.01 wt% or less, sulfur (S) 0.01 wt% or less, titanium (Ti) 0.0002 to 0.04 wt% or less, aluminum (Al) 0.001 to 0.04 wt%, boron (B) 0.001 to 0.006 wt%, nitrogen (N) 0.006 to 0.011 wt% balance iron (Fe) and other unavoidable impurities,
A graphite free-cutting steel round bar bar with improved electromagnetic properties, characterized in that the addition ratio between the minor alloy elements of the steel material _{satisfies the relational expression of 0.3 ≤ {7.4N 2 - (1.1Ti + 1.9Al + 5.1B}} x 100 ≤ 1.5.} According to claim 1,
The round bar is
material steel homogenization heat treatment process;
material steel hot rolling process;
cooling process;
heat treatment process;
drawing process;
cutting process;
Graphite free-cutting steel round bar with improved electromagnetic properties, characterized in that it is manufactured through a process consisting of 3. The method of claim 2,
Graphite free-cutting steel round bar bar with improved electromagnetic properties, characterized in that the material steel homogenization heat treatment process is performed at a temperature in the range of 1100 to 1300 ° C, and the material steel hot rolling process is performed at a temperature in the range of 800 to 1000 ° C. 3. The method of claim 2,
Graphite free-cutting steel round bar bar with improved electromagnetic properties, characterized in that the heat treatment process is carried out for less than 2 hours at a temperature in the range of 730 to 770 ° C. 5. The method of claim 4,
The steel of the round bar has a fine structure of ferrite and graphite grains,
Graphite free-cutting steel round bar with improved electromagnetic properties, characterized in that the graphite grains in the microstructure are formed in a size of 5 μm or less, and the phase fraction of the graphite grains constitutes an area fraction in the range of 1.5 to 3%. 5. The method of claim 4,
Graphite free-cutting steel round bar bar with improved electromagnetic properties, characterized in that the ferrite dislocation density of the microstructure in the steel of the round bar is 1.5x10 ¹⁴ m ^{-2 or less.} 3. The method of claim 2,
Graphite free-cutting steel round bar bar with improved electromagnetic properties, characterized in that the drawing process is carried out at a temperature in the range of 80 ~ 300 ℃. 8. The method of claim 7,
Graphite free-cutting steel round bar bar with improved electromagnetic properties, characterized in that the reduction in section of the round bar is formed within the range of 15 to 25% during the drawing process. 3. The method of claim 2,
In the cutting process, the die clearance between the cutting punch and the mold is formed within 1~8% of the drawn round bar blank diameter, the incidence angle between the mold and the round bar blank diameter is formed within the range of 0.2~1.5°, and 100℃ Graphite free-cutting steel round bar with improved electromagnetic properties, characterized in that it is carried out at a temperature above.

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