KR20130011739A - The interlayer inserting mothod for enhancing the bonding power at that time of combining al alloy with fe - Google Patents

Abstract

PURPOSE: An interlayer inserting method is provided to generate an aluminum alloy-cast iron reaction layer which has a weaker brittleness than aluminum alloy-cast iron reaction layer and to easily control the thickness of the reaction layer. CONSTITUTION: An interlayer inserting method comprises: a step of polishing the exterior of cast iron(S100); a step of immersing the polished cast iron into a pure aluminum melt solution which is melted at 720-850 °C(S200); a step of inserting the immersed cast iron into a preheated mold(S300); a step of injecting aluminum alloy which is melted at 720-850 °C into the mold(S400); and a step of heat-treating the mold in a heat-treatment furnace for 1-2 hours and cools the same(S500). [Reference numerals] (AA) Start; (BB) End; (S100) Polishing the exterior of cast iron; (S200) Immersing the polished cast iron into a pure aluminum melt solution; (S300) Inserting the immersed cast iron in a preheated mold; (S400) Injecting molten aluminum alloy into the mold in which the cast iron is inserted; (S500) Heat-treating the mold, in which the aluminum alloy is injected, in a heat-treatment furnace and cooling

Description

The interlayer inserting mothod for enhancing the bonding power at that time of combining Al alloy with Fe}

The present invention relates to a method for inserting an intermediate layer for improving the bonding strength during heterojunction between an aluminum alloy and a cast iron material, and more particularly, to reduce the bonding property due to an oxide film formed at the cast iron interface when the aluminum alloy and cast iron are melt-bonded at high temperature. In order to prevent this, the cast iron is immersed in the molten pure aluminum to produce an aluminum-iron reaction layer first, and the intermediate layer for improving the bonding strength in the heterojunction of the aluminum alloy and the cast iron material, which can improve the bonding strength by injecting the aluminum alloy melt into the mold. It relates to the insertion method.

Aluminum-based materials such as aluminum and aluminum alloys are used in various fields by utilizing light weight and excellent corrosion resistance, and in applications requiring strength, they satisfy the required strength by thickening. However, such thickening has been problematic in that it is not suitable as a structural member corresponding to a compact design that does not impair the lightness, which is an advantage of aluminum materials.

When iron-based materials having good mechanical strength can be joined with aluminum-based materials, the aluminum-based materials can be obtained without the need for thickening. For this purpose, bolt nuts, rivets, and fittings are used to join aluminum and iron-based materials. Mechanical coupling methods, such as these, have been adopted. However, such a mechanical coupling method is difficult to obtain excellent joints, there is a problem in low productivity.

When the melt bonding between the aluminum-based material and the iron-based material is possible, the productivity is very high compared to the mechanical bonding method, and may have good characteristics.

In the past, many studies have been made on a joining method between an aluminum-based material and an iron-based material (dissimilar metal material).

As an example, a technique of injecting an aluminum alloy after immersing the material of the cast iron material in the same aluminum alloy melt as the aluminum alloy to be joined during heterojunction between the aluminum alloy and the cast iron material has been proposed. 1 is a joint produced by the heterojunction method of the aluminum alloy ((a) Al-7% Si, (b) Al-12% Si, (c) Al-17% Si) and the cast iron material according to the prior art It is a figure which shows the bonding state of water. As shown in FIG. 1, according to the composition of the aluminum alloy 200 to be joined, the degree of formation of the aluminum alloy-cast iron intermediate layer 110, which is a brittle intermetallic compound, was different and uniform. There is a problem that it is difficult to obtain a reliable joint because the production of the joint having the bonding is not easy.

In these studies, it is important to prevent the melting and mixing of aluminum-based materials and iron-based materials as much as possible to suppress the formation of brittle intermetallic compounds, and to control the formation of brittle intermetallic compounds at the joints so as not to compromise the mechanical performance of the joints. In the conventionally studied joining methods, the stability of the quality cannot be secured due to poor versatility or complexity of the process, and the cost of joining increases, and the problem of lack of practicality is still not solved.

The present invention devised to solve the problems of the prior art as described above allows to produce an aluminum-cast iron reaction layer having a relatively weak brittleness compared to the aluminum alloy-cast iron reaction layer in the fusion bonding of aluminum alloy and cast iron, such a reaction layer The purpose is to facilitate the thickness control.

In addition, the aluminum alloy, which is a low melting point metal, has a very short time to be kept in a molten state, and has another purpose for securing a reaction time by immersing it in a pure aluminum melt.

In addition, there is another object to broaden the utilization by providing a solid bond with improved bonding strength due to the control of the thickness of the reaction layer and securing the reaction time.

The object of the present invention is a melt bonding method of an aluminum alloy and cast iron, the first step of polishing the outer surface of the cast iron, the second step of immersing the polished cast iron in the molten pure aluminum melt at 720 to 850 ℃, immersion Inserting the cast iron into a preheated mold, a fourth step of injecting the molten aluminum alloy at 720 to 850 ° C. into the mold into which the cast iron is inserted, and a mold into which the aluminum alloy is injected is preheated. Heat treatment for 1 to 2 hours, and is achieved by the interlayer insertion method for improving the bonding strength during heterojunction of the aluminum alloy and cast iron material comprising a fifth step of cooling it.

Preferably, the aluminum alloy is an aluminum-silicon alloy containing silicon in any one of 7, 12 or 17% by weight of aluminum.

Also preferably, in the second step, the immersion is performed for 2 to 7 minutes.

Also preferably, in the third step, the mold may be preheated to 350 to 450 ° C.

Also preferably, in the fifth step, the heat treatment furnace is preheated to 410 to 470 ° C.

The present invention devised to solve the problems of the prior art as described above allows to produce an aluminum-cast iron reaction layer having a relatively weak brittleness compared to the aluminum alloy-cast iron reaction layer in the fusion bonding of aluminum alloy and cast iron, such a reaction layer There is an effect that can facilitate the thickness control of.

In addition, the aluminum alloy, which is a low melting point metal, has a very short time to be maintained in a molten state, and there is another effect of securing a reaction time by immersing it in a pure aluminum melt.

In addition, the thickness control of the reaction layer and securing the reaction time has another effect of broadening its utilization by providing a solid bond with improved bonding strength.

1 is a joint produced by the heterojunction method of the aluminum alloy ((a) Al-7% Si, (b) Al-12% Si, (c) Al-17% Si) and the cast iron material according to the prior art Drawing showing the connection state,
Figure 2 is a flow chart showing an intermediate layer insertion method for improving the bonding strength when heterojunction of aluminum alloy and cast iron material according to the present invention,
Figure 3 is a joint produced by the heterojunction method of the aluminum alloy ((a) Al-7% Si, (b) Al-12% Si, (c) Al-17% Si) and the cast iron material according to the present invention Drawing showing the connection state,
Figure 4 is a view comparing the bonding force of the joint produced according to the prior art and the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

Hereinafter, preferred embodiments of the present invention will be described in detail.

Figure 2 is a flow chart showing an intermediate layer insertion method for improving the bonding strength when heterojunction of aluminum alloy and cast iron material according to the present invention. As shown in Figure 2, the present invention is initiated by the step (S100) of polishing the outer surface of the cast iron (100). The cast iron 100 exposed to the atmosphere has an oxide film or various foreign substances on the surface thereof, and the surface is uniformly coated by removing all of them by performing mirror polishing before performing the hot immersion.

Polished cast iron 100 is immersed (S200) in the pure aluminum molten liquid melted at 720 to 850 ℃. In hot immersion or melt-bonding dissimilar metals, temperature and process time have a profound effect. Both of these are correlated, so proper control is very important.

More specifically, the process time decreases as the temperature increases, but when the melting temperature is increased to shorten the process time, the mechanical properties decrease due to the formation of micropores after the joint solidifies as the gas blowing amount in the melt increases. . On the other hand, when the melting temperature is low, the aluminum coating layer formed on the surface of the cast iron 100 solidifies while inserting the cast iron 100 having been immersed into the mold and then injecting the aluminum alloy 200 melt, thereby inhibiting the bonding property.

On the other hand, when the immersion time is short, since the cast iron 100 is raised to the reaction temperature, the time for reacting with pure aluminum atoms is not sufficient, so that a uniform intermediate layer is difficult to form, and when the immersion time is long, the aluminum-cast iron intermediate layer As the thickness of the 120 is very thick, the bonding force decreases, and the cast iron 100 is eroded by the aluminum-cast iron intermediate layer 120, thereby causing a problem such as an increase in the loss of the cast iron 100 itself. .

Accordingly, in the present invention, it is preferable to limit the temperature to 720 to 850 ° C and the time to 2 to 7 minutes.

The immersed cast iron 100 is taken out of the molten metal and inserted into the preheated mold (S300).

At this time, the preheating of the mold is for suppressing rapid solidification of the coating layer formed on the immersed cast iron 100 surface, the preheating temperature is preferably 350 to 450 ℃.

When the cast iron 100 is inserted into the mold, the aluminum alloy 200 melted at 720 to 850 ° C. is injected into the mold into which the cast iron 100 is inserted (S400), and a positive pressure (pressure) is applied to the cast iron 100. Will create a joint.

At this time, during hot immersion, the coating layer of pure aluminum formed on the surface of the cast iron 100 is removed, and the aluminum-cast iron intermediate layer 120 and the molten aluminum alloy 200 directly contact each other to thereby bond the two materials.

In this case, when the temperature of the molten aluminum alloy 200 is too low, it is not easy to inject and is not suitable for orthopedic casting, so it is maintained at 720 to 850 ° C. to effectively remove the coating layer formed on the surface of the hot immersion cast iron 100. It is desirable to be.

When the aluminum alloy 200 is injected into the mold, the heat treatment is performed in a preheated heat treatment furnace for 1 to 2 hours, and cooled (S500). This process is to alleviate the shrinkage stress generated during solidification of the joint, the heat treatment is preferably preheated to 410 ~ 470 ℃.

Figure 3 is a joint produced by the heterojunction method of the aluminum alloy ((a) Al-7% Si, (b) Al-12% Si, (c) Al-17% Si) and the cast iron material according to the present invention It is a figure which shows the bonding state. As shown in FIG. 3, each aluminum alloy 200 ((a) Al-7% Si, (b) Al-12% Si, (c) Al-17% Si) and the cast iron 100 joint The intermediate layer has a wider range and is formed uniformly compared to that of Fig. 1 containing the same weight percent of silicon. This is the result of measuring the bonding surface by the Ultrasonic Test (Ultrasonic Test, UT), it is proved that the conventional technology is about 90-95%, the present invention is 98% or more.

In particular, the intermediate layer of the aluminum alloy 200 and the cast iron 100 joint (c) containing 17% by weight of silicon is relatively compared with those of other silicon compositions ((a), (b)) which have performed the same process. Stable distribution

Therefore, when the aluminum alloy 200 and the cast iron 100 is to be formed in accordance with the present invention, it is preferable that the aluminum alloy 200 is composed of 17 wt% silicon.

Figure 4 is a view comparing the bonding force of the joint produced according to the prior art and the present invention. This was measured by bonding the aluminum alloy 200 and the cast iron 100 containing the same weight percent silicon by the prior art and the process of the present invention, respectively, and was performed by the Chalmers Test. As shown in Figure 4, the conventional technology was measured to be 6 ~ 10MPa, the present invention is 8 ~ 19MPa, the bonding force is greatly improved by the process of the present invention.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Various changes and modifications will be possible.

100: cast iron
110: aluminum alloy-cast iron intermediate layer
120: aluminum-cast iron intermediate layer
200: aluminum alloy

Claims (5)

In the melt bonding method of aluminum alloy and cast iron,
A first step of polishing the outer surface of the cast iron;
A second step of immersing the polished cast iron in a pure aluminum melt melted at 720 to 850 ° C .;
Inserting the immersed cast iron into the preheated mold;
Injecting the molten aluminum alloy at 720 to 850 ° C. into the mold into which the cast iron is inserted; And
A fifth step of heat-treating the mold in which the aluminum alloy is injected in a preheated heat treatment furnace for 1 to 2 hours, cooling it
Interlayer insertion method for improving the bonding strength during heterojunction of aluminum alloy and cast iron material comprising a.
The method of claim 1,
Wherein the aluminum alloy is an aluminum-silicon alloy containing silicon in any one of 7, 12 or 17% by weight of aluminum, the intermediate layer insertion method for improving the bonding strength in the heterojunction of the aluminum alloy and cast iron material.
The method of claim 1,
In the second step
Wherein the immersion is an intermediate layer insertion method for improving the bonding strength during heterojunction of aluminum alloy and cast iron material, characterized in that for 2 to 7 minutes.
The method of claim 1,
In the third step
Wherein the mold is preheated to 350 to 450 ℃ the intermediate layer insertion method for improving the bonding strength during heterojunction of the aluminum alloy and cast iron material.
The method of claim 1,
In the fifth step
The heat treatment furnace is an intermediate layer insertion method for improving the bonding strength when the heterogeneous bonding of aluminum alloy and cast iron material, characterized in that preheated to 410 ~ 470 ℃.

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