RU223857U1 - Device for collecting slag in the production of aluminum ingots by semi-continuous casting - Google Patents

Abstract

The utility model relates to the field of foundry production. A device for collecting slag in the production of aluminum ingots by semi-continuous casting contains a catching ring (1), which is placed in the mold (3) to receive the melt (4). The catching ring is made in one piece to form a closed contour on the surface of the melt (4) in the crystallizer and is made of refractory material, the density of which is less than the density of the aluminum melt, which ensures that the ring is retained on the surface of the melt in the crystallizer. A spring (2) made of wire for centering is installed on the catching ring, which helps to locate the catching ring in the center of the crystallizer. It is possible to obtain high-quality ingots from aluminum alloys by reducing oxide, slag and other inclusions in the volume of the ingot and on its surface. 5 ill., 2 pr.

Description

The utility model relates to non-ferrous metallurgy, in particular to the method of semi-continuous casting of ingots from aluminum alloys.

A device is known for filtering and distributing the melt (RU No. 118233, published July 20, 2012) for continuous casting of ingots from aluminum alloys, containing a chute for supplying the melt, a filter for cleaning the melt from non-metallic inclusions, a distribution funnel, an installation centering ring and a crystallizer, in in which the distribution funnel is made in the form of a metal ring, to which a wire frame made of titanium alloy is attached, on the surface of which a coating based on boron nitride is applied, while a shell in the form of a hollow cylinder with a lower base made of basalt fabric is installed on the frame.

The disadvantage of this model is the low reliability of the device due to the possibility of destruction of the basalt fabric due to its low structural strength, low heat resistance at the casting temperature of aluminum alloys, the high probability of non-metallic and intermetallic compounds entering the ingot due to the destruction/dissolution of the basalt fabric cylinder and /or a titanium wire frame during its interaction with a molten aluminum alloy, clogging of the basalt fabric with oxide, slag and other inclusions, preventing the melt from entering the crystallizer, a decrease in the temperature of the melt before entering the crystallizer due to contact with the basalt fabric and titanium frame, the temperature of which is lower melt temperature, as well as the presence of splashes and ripples on the surface of the melt mirror in the crystallizer, which are formed as a result of the melt draining from the filtration device, which leads to disruption of the meniscus structure. All this significantly reduces the quality of the ingots due to the presence of inclusions in the alloy and deteriorates the surface quality due to disruption of the meniscus structure.

The closest to the proposed technical solution is a device for filtering and distributing the melt (RU No. 160411, published March 20, 2016), consisting of a chute for supplying the melt, a distribution funnel, a centering ring and a crystallizer. According to the utility model, the distribution funnel is made in the form of a metal expansion frame of two half-rings connected to each other by means of spring elements, to which a shell with a bottom is attached from the outside, made of fiberglass 0.6÷1.1 mm thick with a surface density of at least 660 g/ ^m2 , while on the surface of the shell there are radial holes of rectangular cross-section, covered over the entire area with a fiberglass mesh with a mesh size of 3±1×3±1 mm, a filter element made of fiberglass mesh with a mesh size of 1±0 is coaxially attached to the inside of the shell, 2×1±0.2 mm, made in the form of an inverse hollow truncated cone with an angle at the imaginary vertex of 95÷120°, and the filter element along the perimeter of its larger base is connected to the shell at a distance of 1/2÷2/3 of the height from the bottom, and along the perimeter of the lower base the filter element is connected to the bottom at a distance of 1/3÷2/3 radius from the axis of the distribution funnel.

The disadvantage of the prototype is the low reliability of the device due to the possibility of destruction of the basalt fabric due to its low structural strength and heat resistance at the casting temperature of aluminum alloys and as a result of the ingress of oxide, slag and other inclusions into the ingot, the high heat capacity of the device made of metal parts, which promotes a decrease in the temperature of the melt, cooling, crystallization and sticking of the melt on it, leading to clogging of the filtration device and disruption of the supply of the melt to the crystallizer and deviation of the melt temperature from the set one, as well as rigid mounting of the device on the crystallizer, which makes it impossible to regulate the height of the melt in the crystallizer during the process casting, as well as the presence of splashes and ripples on the surface of the melt mirror in the crystallizer, which are formed as a result of the melt draining from the filtration device, which leads to disruption of the meniscus structure. All this significantly reduces the quality of the ingots due to the presence of inclusions in the alloy and deteriorates the surface quality due to disruption of the meniscus structure.

The task for which the utility model is designed is to improve the quality of aluminum alloy ingots.

The technical result achieved by implementing the utility model is to improve the quality of aluminum alloy ingots by reducing oxide, slag and other inclusions in the volume of the ingot and on its surface.

The problem is solved using the proposed device for collecting slag in the manufacture of aluminum ingots by semi-continuous casting, consisting of a catching ring configured to receive the melt, and it is made in one piece, ensuring the formation of a closed loop on the surface of the melt in the mold, made of refractory or any other material , capable of withstanding the effects of liquid aluminum and the air atmosphere during the casting process at elevated temperatures without losing its properties, with a density significantly lower than the density of the aluminum melt, which allows it to float on the surface of the melt in the mold and retain oxide, slag and other inclusions inside itself, floating on the surface of the melt; in addition, a centering system in the form of a wire spring is installed on the ring, ensuring that the catching ring is located in the center of the crystallizer.

The advantage of this device is that the catching ring is made of one piece, with a centering system installed on it in the form of a wire spring, due to this, floating oxide, slag and other inclusions, the density of which is lower than the density of the melt, arise as a result of contact of the melt with air and that fall on the surface of the melt in the crystallizer remain inside the ring. The pressure of a catching ring with a spring installed on it, for example, made of nichrome wire, on the surface of the melt has a beneficial effect on the formation of the meniscus, the shape of which becomes more rounded (its radius decreases). In addition, the ring dampens vibrations of the melt mirror in the crystallizer, which also has a beneficial effect on the structure and stability of the meniscus. As a result, the content of oxide, slag and other inclusions in the ingot is significantly reduced and a smoother and more even surface is formed, which helps to obtain a higher quality ingot.

The essence of the utility model is illustrated by drawings, where:

Figure 1 is a diagram of the device operation.

Fig. 2 - shows an ingot of aluminum alloy 6013, obtained without a catching ring with an installed alignment system, as a result of melting 1.

Fig. 3 - shows the surface of an ingot of aluminum alloy 6013 obtained without a catching ring with an installed alignment system as a result of melting 1.

Fig. 4 - shows an ingot of aluminum alloy 6013, obtained with a catching ring made of aerated concrete with a density of D400, with a centering system installed on it in the form of a spring made of nichrome wire, as a result of melting 2.

Fig. 5 - shows the surface of an ingot of aluminum alloy 6013, obtained with a catching ring made of aerated concrete with a density of D400, with a centering system installed on it in the form of a spring made of nichrome wire, as a result of melting 2.

The device contains (Fig. 1) a catching ring 1 made of refractory or any other material capable of withstanding high temperatures during the casting process, with a density significantly lower than the density of the aluminum melt with a centering system installed on it in the form of a wire spring 2, whose melting temperature is higher than the melt temperature, to center the position of the ring in the crystallizer.

An example of a description of the device's operation.

The catching ring 1 (Fig. 1) with a centering system installed on it in the form of a spring 2 is placed in the crystallizer 3 before the process of pouring the melt 4 into the crystallizer 3 begins. The melt 4 is fed through the pipe 5 into the center of the crystallizer 3. Due to the lower density, the catching ring 1 with a spring 2 floats on the surface of the melt 4, from which the ingot 6 is formed due to cooling upon contact with the crystallizer 3 and the cooling agent 7, washing the ingot with the flow 8 after the crystallizer 3. Floating oxide, slag and other inclusions 9, the density of which is lower than the density of the melt, resulting from contact of the melt with air and falling on the surface of the melt in the crystallizer 3, remain inside the catching ring 1. The pressure of the catching ring 1 with a centering system installed on it in the form of a spring 2, for example, made of nichrome wire, on the surface of the melt, has a beneficial effect on the formation of meniscus 10, the shape of which becomes more rounded (its radius decreases).

Examples of implementation.

Melt 1. The 6013 aluminum alloy ingot was produced by semi-continuous casting without using a catch ring 1 to reduce the amount of oxide, slag and other inclusions. The appearance of the ingot is shown in Fig. 2. The surface of the ingot is shown in Fig. 3.

Oxide films and slag inclusions are observed on the surface. In addition, there are irregularities and potholes formed as a result of disruption of the structure of the meniscus 11 due to the contact of the meniscus with oxide and slag inclusions and ripples on the surface of the melt mirror 4 in the mold 3 during the casting process.

Melt 2. The 6013 aluminum alloy ingot was produced by semi-continuous casting using a catch ring 1 made of aerated concrete with a density of D400, with a centering system installed on it in the form of a spring 2 made of nichrome wire. The appearance of the ingot is shown in Fig. 4. The surface of the ingot is shown in Fig. 5.

Visual inspection of the surface showed that the surface of the ingot is smooth with small depressions and minor oxide inclusions.

Thus, the proposed utility model will make it possible to produce ingots using the method of semi-continuous casting from aluminum alloys with a reduction in oxide, slag and other inclusions in the volume of the ingot and on its surface.

Claims (1)

A device for collecting slag in the production of aluminum ingots by semi-continuous casting, containing a catching ring configured to be placed in a crystallizer for receiving the melt, characterized in that it is equipped with a wire spring installed on the catching ring, made with the possibility of centering to ensure the location of the catching ring in the center of the crystallizer, while the catching ring is made one-piece, ensuring the formation of a closed contour on the surface of the melt in the crystallizer, from a refractory material with a density lower than the density of the aluminum melt, ensuring retention of the catching ring on the surface of the aluminum melt contained in the crystallizer.