KR101961468B1 - Al-Mg-Ca MASTER ALLOY FOR ALUMINUM ALLOY AND MANUFACTURING METHOD THEREOF - Google Patents

Abstract

The present invention relates to a parent alloy used for improving an aluminum alloy and a method of manufacturing the same. The parent alloy includes a base material Al; Wherein the additive components Mg and Ca are mixed in a weight ratio of 1.3: 1 to 2.0: 1, and the additive component Mg is 1.2 to 26% by weight based on the parent alloy. (A) forming a base material Al melt; (b) adding the additive components Ca and Mg; And (c) dewetting after solidification. In this case, the step (b) may include the steps of: (b-1) firstly adding the addition component Ca, which is performed sequentially; (b-2) adding Mg as an additive component; And (b-3) secondarily adding the addition component Ca. According to the present invention, it is possible to provide a master alloy having superior main constitution and mechanical properties at the time of modification treatment of an aluminum alloy, reducing the processing cost in production of parent alloy, and having excellent fish property, and a production method thereof.

Description

TECHNICAL FIELD The present invention relates to an Al-Mg-Ca master alloy for aluminum alloys and a method for producing the same.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a parent alloy used for improving an aluminum alloy and a method of manufacturing the same. More particularly, the present invention relates to a parent alloy used for improving an Al-Mg system or an Al-Si system aluminum alloy and a method for manufacturing the same.

Generally, aluminum alloy has excellent corrosion resistance and moldability while maintaining a predetermined strength, and is widely used in various fields such as automobile industry, electronic industry, and aviation industry. Most of these aluminum alloys contain Si or Mg as an additive component and are manufactured by modifying the problems accompanying the additive components by a predetermined method.

For example, when the Al-Si alloy in the aluminum alloy contains a high Si content, Si forms a mixed structure of the primary α (α) dendrite and the process Si. In particular, the Si of the needle (three- (Na), strontium (Sr), calcium (Ca), antimony (Sb) and the like are used in the manufacture of alloys, since the mechanical properties such as mechanical strength, However, since the components are volatilized within a few hours and can not remain in the molten metal, there is a problem that the effect of the improved treatment is inferior.

The Al-Mg based alloy in the aluminum alloy has been traditionally added with magnesium in an SF6 gas atmosphere to improve the casting due to Mg oxide, deterioration in mechanical properties, cracking during processing, , A calcium-based compound, a metal calcium, or the like, so as to prevent oxidation of Mg. However, the effect of inhibiting the oxidation of SF6 by the gas is not high, and the use thereof is extremely limited due to environmental problems and mass production. Al-Be is extremely toxic and very volatile in the molten state, making it difficult to maintain for a long time. Calcium-based compounds such as CaO, CaCN ₂ and CaC ₂ are difficult to react when added to molten aluminum, and the effect of modifying is insignificant. In addition, metal calcium reacts with moisture at room temperature to generate hydrogen, which is difficult to handle in the field, and since magnesium is more oxidative than magnesium in the molten aluminum, the quality of the molten metal deteriorates, which limits its application .

Korean Patent Laid-Open Publication No. 10-2012-0129717 discloses a mother alloy containing magnesium oxide or a silicon-containing oxide as a magnesium master alloy for an improved treatment of an aluminum alloy. However, the density of the molten metal of magnesium aluminum master alloy is added to molten aluminum in accordance with the process of the Republic of Korea Patent Publication No. 10-2012-0129717 No. (2.7g / cm ³⁾ and the density of the magnesium mother alloy (1.84g / cm ³⁾ The magnesium master alloy is suspended on the surface of the molten metal and exposed to the atmosphere for a certain period of time to cause surface oxidation. As a result, the magnesium oxide increases and the casting and mechanical properties of the aluminum alloy may be deteriorated. In addition, the mother alloy manufacturing process is performed in such a manner that calcium oxide (CaO) is injected from the magnesium melt surface to generate intermetallic compounds such as Al ₂ Ca, Al ₄ Ca and Mg ₂ Ca by the heat of reaction and dispersed in the magnesium melt. generated during a manufacturing process CaO, MgO, Al ₂ O ₃ Etc. are released into the atmosphere, there is a risk of environmental pollution, poor working environment and high safety accidents. In addition, in the process of forming an intermetallic compound in Al ₂ Ca, Al ₄ Ca and Mg ₂ Ca by reacting the magnesium molten metal with calcium oxide (CaO), only about 60 to 70% of the total input weight of magnesium, aluminum, Alloy and the remainder is discarded as sludge or drag in the form of oxides such as MgO and CaO, the recovery rate (alloying rate) of magnesium, aluminum and CaO to be charged is low and only about 60 to 70% . As a result, there is a problem that the overall process cost increases and the productivity decreases. Mg-Al-Ca parent alloys and Mg-Al-CaO based parent alloys may also be used as the parent alloys based on Mg, but they contain a large amount of internal inclusions and oxides, to be.

Korean Patent Publication No. 10-2012-0129717

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the conventional art described above, and it is an object of the present invention to provide an aluminum alloy which can impart excellent casting and mechanical properties during the modification treatment of aluminum alloy, Alloy and a method of manufacturing the same.

DISCLOSURE OF THE INVENTION The present invention has been made as a result of intensive studies to solve the above-mentioned problems, and the gist of the present invention is as follows.

(1) A method for producing a parent alloy for an aluminum alloy, comprising the steps of: (a) forming a base material Al melt; (b) adding the additive components Ca and Mg; And (c) a step of dipping after solidification, wherein the mixing ratio of the additive components Mg and Ca is from 1.3: 1 to 2.0: 1 by weight, and the additive component Mg is added in an amount of 1.2 to 26% by weight based on the parent alloy By weight based on the total weight of the Al-Mg-Ca master alloy.

(2) In the step (b), the step (b-1) of adding the addition component Ca is carried out in sequence; (b-2) adding Mg as an additive component; And (b-3) adding an additional component Ca to the Al-Mg-Ca parent alloy.

(3) The method for producing an Al-Mg-Ca parent alloy according to (2), wherein the amount of Ca added in the step (b-1) is 10 to 30% of the total amount of Ca.

(4) The method for producing an Al-Mg-Ca parent alloy according to (2) above, wherein the alloying process is performed while stirring the surface layer portion of the molten metal in at least one of the steps (b-1) .

(5) The method for producing an Al-Mg-Ca parent alloy according to (1), wherein the degassing process is carried out while stirring the bottom of the molten steel in at least one of the steps (a) to (c) .

(6) The method for producing an Al-Mg-Ca parent alloy according to any one of the above (b-1) to (b-3), wherein degassing is performed while stirring the bottom of the molten metal.

(7) The method for producing an Al-Mg-Ca parent alloy according to (1), wherein the base metal Al, the additive components Mg and Ca are provided from pure metals of 98% or more in purity, their alloys or scrap.

(8) The method for producing an alloy according to (2), wherein the recovery rate of the additive component Ca in the step (b-1) is 95% or more based on the amount of the additive and includes at least one of Al ₂ Ca and Al ₄ Ca. A method for manufacturing a Ca alloy.

9, the a (b-2) the recovery of additional ingredients Mg amount based on 98% or more _{in, Mg 2 Ca, Al 3 Mg} 2, Al 12 Mg 17, Al 2 Ca, Al 4 Ca, Mg 2 one of Ca (2), wherein the Al-Mg-Ca molybdenum alloy is produced by a method comprising the steps of:

10, the (b-3), and the recovery rate of addition component Ca amount based on 98% or more _{in, Mg 2 Ca, Al 3 Mg} 2, Al 12 Mg 17, Al 2 Ca, Al 4 Ca, Mg 2 one of Ca Mg-Ca molybdenum alloy according to (2), wherein the Al-Mg-

(11) Base metal Al; Wherein the additive components Mg and Ca are mixed in a weight ratio of 1.3: 1 to 2.0: 1, and the additive component Mg is 1.2 to 26% by weight based on the parent alloy. Parent alloy.

(12) The Al-Mg-Ca parent alloy according to (11), wherein the needle-like Al ₄ Ca intermetallic compound is distributed in a network structure.

(13) Al-Mg-Ca parent alloy produced according to any one of (1) to (7) above.

The parent alloy according to the present invention contains at least impurities such as internal inclusions, oxides, and pores at a minimum, and Ca, which is an additive component of the parent alloy, forms a dense CaO layer on the surface of the molten alloy. Thereby preventing Mg from being dissolved / mixed in the molten metal, thereby improving the casting and flowability and improving the mechanical properties of the modified aluminum alloy.

Further, the parent alloy manufacturing method according to the present invention is excellent in the recovery ratio (alloying rate) to Ca and Mg as additive components of the parent alloy, and can effectively suppress the generation of noxious gas generated during the process, Ignition or explosion can be prevented in the alloying process of Ca and Mg, thereby preventing safety accidents and providing a good working environment, thereby reducing the overall process cost and greatly improving productivity.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a process for producing a mother alloy for an aluminum alloy according to the present invention. FIG.
2 is a structural view of a stirring apparatus according to the present invention.
Fig. 3 is a comparative explanatory view of the action mechanism of the parent alloy according to the present invention. Fig.
4 is a microstructure photograph of the Al-Mg-Ca parent alloy according to the present invention.
FIG. 5 is a graph showing the distribution of Al and Ca in the Al-Mg-Ca parent alloy according to the present invention
Fig. 6 is an analysis table of the chemical composition of AC4C containing Al-Mg-Ca parent alloy according to the present invention.
FIG. 7 is an analysis table of the chemical composition of the aluminum alloy casting manufactured by the 'die-casting method' using the AC4C containing the Al-Mg-Ca parent alloy according to the present invention, the conventional AC4C, and the conventional AC4C containing the Sr.
FIG. 8 is a table comparing the mechanical properties of the aluminum alloy casting manufactured by the 'die-casting method' using the AC4C with the Al-Mg-Ca parent alloy according to the present invention, the conventional AC4C, and the conventional AC4C with the Sr added.
FIG. 9 is an analysis table of the chemical composition of the aluminum alloy casting manufactured by the 'die casting method' using the AC4C with the Al-Mg-Ca parent alloy according to the present invention and the conventional AC4C.
FIG. 10 is a table comparing the mechanical properties of the aluminum alloy casting manufactured by the 'die casting method' using the AC4C with the Al-Mg-Ca parent alloy according to the present invention and the conventional AC4C.
11 is an analysis table of chemical composition of the aluminum alloy casting manufactured by the 'casting method using AC4C with Al-Mg-Ca parent alloy according to the present invention and conventional AC4C.
FIG. 12 is a table comparing the mechanical properties of the aluminum alloy casting manufactured by the 'casting method using AC4C with Al-Mg-Ca parent alloy according to the present invention and conventional AC4C.
13 is an analysis table of the chemical composition of the aluminum alloy casting manufactured by the centrifugal casting method using the AC4C and Sr added AC4C with Al-Mg-Ca parent alloy according to the present invention.
FIG. 14 is a table comparing the mechanical properties of the aluminum alloy casting manufactured by the centrifugal casting method using the AC4C and Sr added AC4C with Al-Mg-Ca parent alloy according to the present invention.
Fig. 15 is an analysis table for the chemical composition of AC7A containing Al-Mg-Ca parent alloy according to the present invention.
16 is an analysis table of the chemical composition of the aluminum alloy casting manufactured by the 'low pressure casting method' using the Al-Mg-Ca parent alloy added AC7A and Al-Be parent alloy AC7A according to the present invention.
17 is a comparative table on the mechanical properties of the aluminum alloy castings manufactured by the 'low-pressure casting method' using the Al-Mg-Ca parent alloy added AC7A and Al-Be parent alloy AC7A according to the present invention.

Hereinafter, the present invention will be described in detail based on examples. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately The present invention should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention. Therefore, it is to be understood that the constituent features of the embodiments described herein are merely the most preferred embodiments of the present invention, and are not intended to represent all of the inventive concepts of the present invention, so that various equivalents and variations Examples should be understood.

First, a parent alloy for an aluminum alloy according to the present invention will be described. The mother alloy is used in the production and refinement of aluminum alloys. The master alloys are aluminum alloys standardized in KS, JIS, ASTM and the like, in particular Al-Mg alloys containing Mg and Al-Si alloys containing Si Can be usefully applied.

The parent alloy according to the present invention is an Al base material and includes Mg and Ca as additive components. Basically, the Al base material and the additive component Mg heat the components and the content of the aluminum alloy to be modified, and the additive component Ca serves to suppress or minimize the oxidation of Mg in the modification process. The parent alloy of the present invention is characterized in that chemically stable Al is used as a base material. That is, the molten metal surface as having an improved manufacture and processed with the density of the conventional Mg-based base material, if the master alloy is a low Mg 1.84g / cm ³ than that of the aluminum alloy of density 2.4 ~ 2.8g / cm ³ of an aluminum alloy with the parent alloy However, in the case of the mother alloy based on Al base of the present invention, Al is not different in density from the aluminum alloy to be manufactured and improved, so that the oxide is suspended on the surface of the melt, So that the casting, fluidity and mechanical properties of the aluminum alloy can be greatly improved.

The content of each of Al, Mg and Ca, which are components of the parent alloy, can be determined according to the mixing ratio and content of Mg and Ca, and the remaining components other than the specified additive components Mg and Ca include Al and unavoidable impurities . In this case, the mixing ratio of Mg and Ca is preferably 1.3: 1 to 2.0: 1 by weight and the additive component Mg is preferably contained in an amount of 1.2 to 26% by weight based on the parent alloy. If the mixing ratio of Mg to Ca is less than 1.3, Mg ₂ Ca can not be formed and if calcium is left in the aluminum, crystallization occurs and the uniform chemical composition can not be formed in the parent alloy, There is a risk of occurrence of magnesium oxide, which is not preferable. When the additive component Mg is less than 1.2 wt% based on the parent alloy, it is not preferable because it does not fall within the Mg ₂ Ca formation range, and when it is more than 26 wt%, an Al-Mg based compound is formed and the uniform chemical composition is not preferable.

Further, the master alloy according to the present invention can maximize the recovery rates of Mg and Ca as additive components through the control of the parent alloy manufacturing process as described later, and also can provide an oxide or inclusions of Mg and Ca By improving the impurity content to a minimum of less than 500 ppm, it is possible to improve the improved processing ability of the aluminum alloy.

The parent alloy according to the present invention is characterized in that the needle-like Al ₄ Ca intermetallic compound is distributed in a network structure.

Next, a method for manufacturing a mother alloy for aluminum according to the present invention will be described. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a process diagram for a method for manufacturing a parent alloy for an aluminum alloy according to an embodiment of the present invention (hereinafter referred to as a parent alloy). Fig. 2 shows a structural diagram of a stirring apparatus 10 used in the production of parent alloy. The stirring device 10 includes silica (SiO ₂ ) or a graphite material rotor 110 driven by a motor 140 to mix the molten metal in the melting furnace 20, Is introduced into the melting furnace 20 and is supported by the support arm 130 during the manufacturing process and can be moved up and down by the lifter 120. [ The rotor 110 is provided with a hollow portion 112 through which process gases such as argon, nitrogen, SF6, SO2 and the like can be introduced. The melting furnace 20 is provided with a thermal insulation cover 22 and metal components constituting the parent alloy can be introduced through the opening 222 of the thermal insulation cover 22. [ The mother alloy molten metal is taken out to the external ingot mold (30) through the casting device (150) and solidified.

The parent alloy manufacturing method according to the present invention basically comprises the steps of: (a) forming a base material Al melt; (b) adding the additive components Ca and Mg; And (c) dewatering after solidification. The step (b) is preferably a step (b-1) of initially adding an additive component (Ca) as an alloying process of the parent alloy component; (b-2) adding Mg as an additive component; And (b-3) secondarily adding the addition component Ca. Wherein the mixing ratio of the additive component Mg and Ca is from 1.3: 1 to 2.0: 1 by weight and the additive component Mg is added by not more than 26% by weight based on the parent alloy. Are as described above. In this case, the step (b), which is an alloying process of the parent alloy component, includes the steps of (b-1) firstly adding the addition component Ca; (b-2) adding Mg as an additive component; And (b-3) an addition of Ca component may comprise the step of the second injection, the melt by using the agitator 10 And the surface layer portion is stirred. In addition, each step between the step and the alloying step of this process before and after using the stirrer the molten metal Can be carried out while stirring the bottom portion . In the alloying step, the addition of Ca is carried out in two steps (b-1) and (b-3) before and after the addition of Mg. In this case, It is preferable that the charging amount is 10 to 30% based on the input amount, and it is preferable that the charging amount is made with respect to the remaining amount after (b-3). Hereinafter, each step will be described in more detail.

In the step (a), a step of dissolving Al as a base material to form a molten metal is performed ( S10 ). Specifically, pure aluminum of 98 wt% or more in purity or Al provided in the form of KS standard, JIS standard, aluminum alloy and scrap disclosed in ASTM standard is dissolved in the range of 580 to 760 캜 using a melting furnace 20, And sludge are removed.

Next, the degassing process is selectively performed using the Al melt by using the stirring device 10 of FIG. 2 ( S100 ). Specifically, the temperature of the Al melt is set in the range of 650 to 700 ° C., the rotor 110 of the stirring device 10 is preheated for about 10 to 30 minutes, placed at 10 to 50 cm from the bottom of the melt, Set and rotate. An inert gas such as Ar and N _{2 is} flowed into the hollow portion 112 of the rotor 110 at a rate of 5 to 20 L / min and the stirring is continued for about 10 to 30 minutes while a degassing agent is added at a rate of 0.2% desirable.

Next, in the step (b-1), the addition component Ca is first charged and alloyed ( S20 ). The step of primarily charging Ca is carried out for the purpose of suppressing the oxidation of other added components Mg introduced in the subsequent step (S30), the step (S40) of adding Ca to be described later, . The Ca may be supplied from a pure metal having a purity of 98% or more, an alloy thereof, or scrap. The amount of Ca to be firstly charged is preferably 10 to 30% based on the total amount of Ca, It is not preferable since the effect of inhibiting oxidation may be somewhat insufficient when magnesium is added. If it exceeds 30%, it may not be uniformly mixed with the molten magnesium and segregation may occur. Specifically, the temperature of the Al melt was set in the range of 616 to 750 ° C, the rotor 110 according to the S100 was positioned 10 to 30 cm from the surface layer of the melt, and the high-speed rotation state of 100 to 600 rpm was maintained, And the mixture is sufficiently mixed at a high speed of about 100 to 600 rpm for about 10 to 30 minutes. Subsequently, the rotor 110 of the stirrer 10 is placed at 20 to 40 cm from the bottom of the molten metal, and rotated at a low speed of 50 to 300 rpm for 5 to 10 minutes while flowing inert gas at 5 to 20 L / min, After removing the inclusions, oxides, and hydrogen generated inside, the molten metal is stabilized. In the primary alloying process for Ca, it is preferable that the rotor is placed on the surface portion of the molten metal and the molten metal and calcium are brought into contact with each other to generate instantaneous reaction heat so that the Al ₄ Ca intermetallic compound formed is sufficiently stirred and dispersed uniformly in the molten metal . On the other hand, in the step (b-1), the stirring device 10 is rapidly rotated at the surface portion of the molten metal to minimize the contact of the introduced calcium with the atmosphere, so that the recovery rate of the added component Ca can be increased to 95% In this case, Ca may be included in the parent alloy in at least one form of Al ₂ Ca and Al ₄ Ca.

Next, the degassing process is selectively performed using the Al-Ca molten metal having been charged with the primary Ca using the stirring device 10 of FIG. 2 ( S200 ). S200 is performed in a manner similar to that of S100, and it is preferable that the rotor 110 of the stirring device 10 is placed in the vicinity of the bottom of the molten metal and the bottom of the molten metal is stirred at low speed.

Next, in the step (b-2), an addition component Mg is added and alloyed (S30) . The Mg may be supplied from a pure metal having a purity of 98% or more, an alloy thereof, or scrap (AZ91, AM80, etc.), and Mg to be contained in the parent alloy is 100% Specifically, the temperature of the Al-Ca molten bath was set in the range of 480 to 680 ° C, the rotor 110 according to S200 was positioned 10 to 30 cm inward from the surface layer of the molten metal, and the high-speed rotation state of 100 to 600 rpm was maintained, And the mixture is sufficiently mixed by keeping it at a high speed of 100 to 600 rpm for about 10 to 30 minutes. Subsequently, the rotor 110 of the stirrer 10 is placed at 20 to 40 cm from the bottom of the molten metal, and rotated at a low speed of 50 to 300 rpm for about 5 to 10 minutes while flowing inert gas at 5 to 20 L / min The inclusions, oxides, and hydrogen generated in the molten metal are removed, and the molten metal is stabilized. In order to prevent oxidation when Mg is added to the surface portion of the molten metal, it is preferable to minimize the contact with the atmosphere and stir the molten magnesium so as to rapidly dissolve into the molten metal. On the other hand, in the step (b-2), magnesium can be rapidly introduced into the molten metal by using the stirring device 10, and the recovery rate of the additive component Mg can be made as high as 98% Mg ₂ Ca, Al ₃ Mg ₂ , Al ₁₂ Mg ₁₇ , Al ₂ Ca, Al ₄ Ca, and Mg ₂ Ca, may be included in the parent alloy.

Next, the degassing process is selectively performed using the Al-Mg-Ca molten metal having been completely charged with Mg by using the stirring device 10 of FIG. 2 ( S300 ). S300 is performed in a manner similar to that of S100 and S200, and it is preferable that the rotor 110 of the stirring device 10 is placed in the vicinity of the bottom of the molten metal to stir the bottom of the molten metal at a low speed.

Next, in the step (b-3), a step of secondary addition of the addition component Ca and alloying is performed ( S40 ). The step of secondly introducing Ca is carried out for the purpose of satisfying the target content and also forming Mg ₂ Ca. This Ca can be provided from pure metal of 98% or more in purity, its alloy or scrap And the input amount thereof is 70 to 90% based on the total Ca input amount which is obtained by subtracting the input amount in S20. Specifically, the temperature of the molten Al-Mg-Ca was set in the range of 540 to 700 ° C., and the rotor 110 according to the above S300 was positioned 10 to 30 cm from the surface layer of the molten metal to a high speed rotating state of 100 to 600 rpm, Ca is added and mixed thoroughly by keeping it at a high speed of 100 to 600 rpm for about 10 to 30 minutes. Subsequently, the rotor of the stirring device 10 is placed at a distance of 20 cm to 40 m from the bottom of the molten metal, and rotated at a low speed of 50 to 300 rpm for 5 to 10 minutes while flowing an inert gas at a rate of 5 to 20 L / min After removing the inclusions, oxides, and hydrogen, the molten metal is stabilized. The secondary alloying process for Ca is preferably carried out at the surface portion of the molten metal for the purpose of inhibiting Ca oxidation and uniformly dispersing the same as in the case of the primary alloy for Ca. On the other hand, in the step (b-3), since the agitation device 10 is rapidly rotated in the surface layer portion of the molten metal to minimize the contact of the introduced calcium with the atmosphere, the recovery rate of the additive component Ca can be increased to 95% In this case, Ca may be included in the parent alloy as at least one of Mg ₂ Ca, Al ₃ Mg ₂ , Al ₁₂ Mg ₁₇ , Al ₂ Ca, Al ₄ Ca, and Mg ₂ Ca.

Finally, in the step (c), the stabilized Al-Mg-Ca molten metal is discharged to the outer vessel 30 through the discharge port 150 and then injected into a casting machine (not shown) (S50) .

As described above, in the parent alloy manufacturing method according to the present invention, Mg and Ca, which have been completely removed from the surface water by using the stirring device 100, are introduced into the molten metal at high speed, MgO, CaO, CaOH ₂ produced by contact with oxygen in the atmosphere by inhibiting Ca from moving to the surface of the molten metal Etc., and it is possible to uniformly mix the additive components, so that residual inclusions, oxides, and pores in the inside can be controlled to 500 ppm or less. Addition of the Al-Mg-Ca parent alloy proposed in the present invention during the production and improvement of the aluminum alloy can inhibit oxidation of Mg to ensure the cleanliness of the molten metal and improve Mg oxidation such as flowability, casting, dross, It is possible to effectively improve and improve the physical properties that can be deteriorated due to the above-mentioned problems. The Al-Mg-Ca parent alloy in which the impurities are reduced as described above is an aluminum alloy standardized in KS, JIS, ASTM, etc., and is particularly applicable to an Al-Mg alloy and an Al-Si alloy including Mg

For example, in the process of melting / maintaining / casting the ingot made of an Al-Mg based alloy for sand casting, die casting and die casting, as shown in FIG . 3 (a) The MgO layer formed by oxidation of Mg is not densely formed on the surface of the molten metal to form a continuous oxide, thereby changing the chemical composition and deteriorating the casting, fluidity, and mechanical properties. On the other hand, in the case of the Al-Mg based alloy modified with the Al-Mg-Ca based parent alloy according to the present invention shown in FIG. 3 (b), Ca is oxidized to form CaO and the CaO layer is densely And inhibits the penetration of oxygen into the inside of the atmosphere by suppressing the oxidation of Mg which is dissolved / mixed in the molten metal to improve the casting, flowability, mechanical properties and the like.

Further, the parent alloy manufacturing method according to the present invention is excellent in recovery rate (alloying ratio) to Ca and Mg as additive components of the parent alloy, and can effectively suppress the generation of noxious gas generated during the process, The ignition or explosion can be prevented in the alloying process of Ca and Mg, thereby preventing safety accidents and providing a good working environment. As a result, the overall process cost can be reduced and the productivity can be greatly improved.

Hereinafter, the present invention will be described more specifically based on preferred manufacturing examples and experimental examples of the present invention. However, it should be understood that the technical spirit of the present invention is not limited thereto, and various modifications may be made by those skilled in the art.

 [Al-Mg-Ca Parent alloy  Microstructure photograph]

The Al-Mg-Ca mother alloy manufactured according to the present invention using a scanning electron type microscopy (Scanning Electron Microscope) was observed microstructure, also a result of progress of the analysis using EDS (Energy Dispersive X-ray Spectometer ) 4 shows the. In the microstructure, the intermetallic compound was uniformly distributed in the interstitial formation, the fine intermetallic compound appeared to be uniformly twisted in a net shape, the intermetallic compound in the interstitial formation was expected to be Al ₄ Ca, It was impossible to make a qualitative prediction by finely compounding the shape. In addition, as a result of EDS mapping in FIG. 5 , Al and Ca distributions were shown, and oxides, inclusions and pores were not detected. Thus, it was confirmed that the Al-Mg-Ca parent alloy produced according to the present invention had a high quality without inclusions, oxides, pores and the like.

[ Example  1] Al-Mg-Ca Parent alloy  Aluminum alloy for addition casting AC4C  Produce

First, aluminum scrap was melted in a 10 ton reflex furnace at 650 ~ 730 ℃, and iron (Fe) distributed in the molten metal was removed through a magnet. Then, the Al-13 wt% Mg-10 wt% Ca parent alloy according to the present invention was supplied to 0.06 ~ 0.1 wt% of the total weight, mixed thoroughly, and then added and mixed according to the added amount of Mg. Then, the Al-Mg-Ca parent alloy of the present invention was applied to the bottom of the AC4C molten metal for about 40 minutes and the stabilization time was continued for about 30 minutes, Si based AC4C ingot was prepared. The chemical composition is shown in Fig .

[ Experimental Example  One] Example  1 AC4C , existing AC4C  And Sr added AC4C  Analysis of Chemical Composition and Mechanical Properties of Cast Aluminum Alloy Made by Die Casting Method

The AC4C ingot, the conventional AC4C ingot, and the conventional AC4C ingot prepared according to Example 1 of the present invention were dissolved in a 500 kg class electric furnace, respectively, and then the chemical composition and mechanical properties of the castings were compared by die casting. Are shown in Figs. 7 and 8. Fig. As shown in FIG. 7, the contents of Si, Mg, and Ti as control elements were similar to those of conventional AC4C, Sr-added AC4C and AC4C produced in Example 1, and Sr-added AC4C had a Sr content of 0.008 wt.%, and the AC 4C prepared according to Example 1 had a Ca content of 0.028 wt%. To 8, exhibited a AC4C is 201N / mm ² according to the case of the tensile strength in Example 1, was improved by 17% compared to conventional AC4C, Sr added AC4C was improved compared to 6.5%. The elongation percentage of the AC4C according to Example 1 was 6%, which was 33% higher than that of the conventional AC4C and 35% higher than that of the Sr4-added AC4C. As a result, in the case of the die casting casting, the mechanical properties such as the tensile strength and the yield ratio of the AC4C aluminum alloy produced by adding Al-Mg-Ca parent alloy according to Example 1 of the present invention were analyzed to be excellent .

[ Experimental Example  2] Example  1 AC4C  And Existing AC4C  Analysis of Chemical Composition and Mechanical Properties of Aluminum Alloy Castings Manufactured by Die Casting Process

The AC4C ingot and the conventional AC4C ingot manufactured according to Example 1 of the present invention were dissolved in a 300 kg class electric furnace to be degassed and stabilized for 30 minutes to prepare a casting. After removing the injection port, bathtub, after T6 (quenched after 525 ℃, keeping 8hrs proceeds after sample treatment holding 160 ℃, 6hrs) as compared to the chemical composition and mechanical properties of the casting proceeds the heat treatment. the results are shown in Figs. Referring to FIG. 9, the chemical components of the control elements Si, Mg, and Ti showed similar contents to those of the conventional AC4C and the AC4C produced according to Example 1, and the Ca content was 0.004 wt.%. 10, the tensile strength after T6 heat treatment was measured as 310.4 N / mm ² of AC 4C prepared according to Example 1, which was improved by 4.5% compared to the conventional AC 4C, and the elongation was 4.44%, which was 38.5% And it was confirmed that it was greatly improved.

[ Experimental Example  3] Example  1 AC4C  And existing AC4C Casting casting method  Analysis of chemical composition and mechanical properties of cast aluminum alloy

The AC4C ingot and the conventional AC4C ingot manufactured according to Example 1 of the present invention were dissolved in a 300 kg class electric furnace to be degassed and stabilized for 30 minutes to prepare a casting. After removing the injection port, bathtub, The chemical composition and mechanical properties of the post casting were compared, and the results are shown in FIGS. 11 and 12 . Referring to FIG. 11, the contents of Si, Mg, and Ti of the control elements were similar to those of the AC4C prepared in Example 1, and the content of Ca in the AC4C prepared in Example 1 was 0.0032 wt% Much was detected in comparison with AC4C. Referring to FIG. 12, the tensile strength of the mechanical properties of AC4C prepared according to Example 1 was measured to be 118.3 N / mm ^{2, which} was 3.7% higher than that of conventional AC 4C and elongation was 0.88%, which was 35.2% And it was confirmed that it was greatly improved.

[ Experimental Example  4] Example  1 AC4C  And Sr addition  existing AC4C  Analysis of Chemical Composition and Mechanical Properties of Aluminum Alloy Castings Prepared by Centrifugal Casting Method

The AC4C ingot and the conventional AC4C ingot prepared according to Example 1 of the present invention were dissolved in a 300 kg class electric furnace to be degassed and stabilized for 30 minutes to prepare a casting, And the chemical components and mechanical properties of the castings were compared. The results are shown in FIGS. 13 and 14. FIG. 13, the control elements Si, Mg, Ti, and the like showed similar contents to both the existing AC4C containing Sr and the AC4C prepared according to Example 1, and the Sr content was slightly increased to 0.008 wt% from the existing AC4C , And the Ca content was found to be as high as 0.0030 wt% in AC4C prepared according to Example 1. 14, the tensile strength of AC4C according to Example 1 was measured to be 190.8 N / mm < ^{2 &} gt ;, which was improved by 7.5% compared to the conventional AC4C containing Sr, and the elongation was improved to 7% It is confirmed that it is greatly improved.

[ Example  2] Al-Mg-Ca Parent alloy  Aluminum alloy for addition casting AC7A  Produce

First, aluminum scrap was melted in a 10 ton reflex furnace at 650 ~ 730 ℃, and iron (Fe) distributed in the molten metal was removed through a magnet. Then, the Al-13wt% Mg-10wt% Ca parent alloy according to the present invention is supplied and mixed in a proportion of 0.1 to 0.3wt% based on the total weight. The mixture is added and mixed according to the added amount of Mg, 0.5 to 0.3 wt%, and the mixture was thoroughly mixed. In this case, the total weight of the mother alloy is set to 0.5 to 0.7 wt%. Thereafter, 0.2 wt% of the powder degassing agent on the basis of the total weight was allowed to stand on the bottom of the AC7A molten metal for about 40 min and the stabilization time was continued for about 30 min, followed by casting to obtain Al-Mg Based AC7C ingot. The chemical composition is shown in Fig.

[ Experimental Example  5] Example  2 AC7A , Al-Be Parent alloy  Original added AC7C  Analysis of Chemical Composition and Mechanical Properties of Aluminum Alloy Castings Produced by Low Pressure Casting Process

Two kinds of AC7A ingots prepared according to the above Example 2 and Al-Be alloys were added to a 500 kg-weight tumbling furnace, respectively, at 650-700 ° C., and a rotor was installed at the center of the molten metal by using a degassing apparatus . Thereafter, the rotor was preheated for 5 to 10 minutes, and the hydrogen gas was supplied at a rate of 8 L / ~ 15 L / min through the center of the rotor by rotating the rotor at about 250 ~ 350 rpm. Thereafter, the molten metal stabilization time was continued for about 30 minutes, and the molten metal was transferred to a 300 kg class heating furnace. The degassing treatment was carried out through a bubble pipe in order to remove inclusions and hydrogen generated during the transfer. The stabilization time was about 30 min and the casting was continued. The chemical composition and mechanical properties of the castings were compared, and the results are shown in FIGS. 16 and 17. FIG. Referring to FIG. 16, the control elements Si and Mg were similar, and the AC7A prepared according to Example 1 showed a Ca content of 0.038 wt%. Referring to FIG. 17, in the case of tensile strength, AC7A prepared according to Example 2 was 222.12 N / mm ² , about 1.14% higher, and elongation was 21.73%, which was found to be 13.98%. As a result, the AC7C ingot according to Example 2 has a higher magnesium oxide oxidation inhibiting effect than the conventional AC7A ingot added with Al-Be parent alloy, and has a sufficient inhibition of oxide formation in the course of dissolution, degassing, transfer, casting and solidification, Was produced.

The results of Examples and Experimental Examples above show that Al-Mg-Ca parent alloy according to the present invention can be used for Al-Be, Compared with Mg-Ca based alloys, it has a high magnesium oxidation inhibition effect and low volatility in the molten state. Therefore, even if the molten metal is maintained for a long time, the inhibition of magnesium oxidation is minimized, thereby improving the casting composition, And the Al-Mg-Ca parent alloy according to the present invention has a high recovery rate during the manufacturing process and is not so complicated, so that it is highly competitive with the manufacturing cost compared to the conventional parent alloy, .

The preferred embodiments of the present invention have been described in detail with reference to the drawings. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, the scope of the present invention is intended to be limited by the following claims rather than the foregoing detailed description, and all changes or modifications derived from the meaning, scope, and equivalence of the claims are intended to be embraced within the scope of the present invention Should be interpreted as being.

10: stirring device
110: Rotor
112: hollow
120: lifter
130: Support arm
140: motor
150: Casting device
20: melting furnace
22: cover
222: open mouth
30: Ingot mold

Claims (13)

A method of manufacturing a parent alloy for an aluminum alloy, comprising the steps of: (a) forming a base material Al melt; (b) adding the additive components Ca and Mg; And (c) a step of dipping after solidification, wherein the mixing ratio of the additive components Mg and Ca is from 1.3: 1 to 2.0: 1 by weight, and the additive component Mg is added in an amount of 1.2 to 26% by weight based on the parent alloy By weight based on the total weight of the Al-Mg-Ca master alloy.
The method according to claim 1, wherein the step (b) comprises: (a) firstly introducing the addition component Ca of (b-1), which is performed sequentially; (b-2) adding Mg as an additive component; And (b-3) adding the additive component Ca in a second step.
The method for producing an Al-Mg-Ca parent alloy according to claim 2, wherein the amount of Ca added in the step (b-1) is 10 to 30% of the total amount of Ca.
The method for producing an Al-Mg-Ca molybdenum alloy according to claim 2, wherein the alloying process is performed while stirring the surface layer of the molten metal in at least one of the steps (b-1) to (b-2).
The method for producing an Al-Mg-Ca parent alloy according to claim 1, wherein the degassing process is performed while stirring the bottom of the molten metal in at least one of the steps (a) to (c).
3. The method according to claim 2, wherein the degassing process is performed while stirring the bottom of the molten metal in at least one of the steps (b-1) to (b-3) Gt;
2. The method of claim 1, wherein the base material Al, the additive components Mg and Ca are provided from pure metals of at least 98% purity, their alloys or scrap.
The method according to claim 2, wherein the recovery rate of the additive component (Ca) in the step (b-1) is at least 95% based on the amount of the additive, and comprises at least one of Al ₂ Ca and Al ₄ Ca. Gt;
3. The method according to claim 2, wherein the recovery rate of the additive component Mg in the component (b-2) is 98% or more based on the amount of the additive, and Mg ₂ Ca, Al ₃ Mg ₂ , Al ₁₂ Mg ₁₇ , Al ₂ Ca, Al ₄ Ca, Mg ₂ Ca, or a mixture thereof.
3. The method according to claim 2, wherein the recovery ratio of the additive component Ca in the step (b-3) is 98% or more based on the amount of the additive, and Mg ₂ Ca, Al ₃ Mg ₂ , Al ₁₂ Mg ₁₇ , Al ₂ Ca, Al ₄ Ca, Mg ₂ Ca, or a mixture thereof.
Base metal Al; Wherein the additive components Mg and Ca are mixed in a weight ratio of 1.3: 1 to 2.0: 1, and the additive component Mg is 1.2 to 26% by weight based on the parent alloy. Parent alloy.
The Al-Mg-Ca parent alloy according to claim 11, wherein the needle-like Al ₄ Ca intermetallic compound is distributed in a network structure.
A Al-Mg-Ca parent alloy produced according to any one of claims 1 to 7.

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