JPWO2015056287A1 - Preheating method and preheating device for ladle for molten aluminum - Google Patents

Abstract

In addition to being able to efficiently preheat the inside of the ladle for molten aluminum, it is possible to minimize the reduction in the effective volume of the ladle even if it is repeatedly preheated and used, and non-metallic inclusions The present invention provides a preheating method of a ladle for molten aluminum and a preheating device using the method, which can reduce contamination of the molten metal due to the above. That is, the present invention is for an aluminum melt that preheats the inside of the ladle (12) with a flame (30) injected from a burner (24) attached to the opening (16) of the ladle for aluminum melt (12). In the preheating method and preheating apparatus for the ladle (12), the flame (30) is surrounded by a preheating pipe (26) made of a heat-resistant thin metal plate.

Description

  The present invention relates to a preheating method for a ladle for molten aluminum in which a molten aluminum or pure aluminum alloy is temporarily stored, and a preheating apparatus for carrying out the method.

  In the manufacturing process of pure aluminum or aluminum alloy (hereinafter collectively referred to simply as “aluminum”), a ladle is used to receive molten aluminum and pour it into a mold. And when accepting molten aluminum to this ladle, the ladle is heated beforehand so that the difference between the temperature inside the ladle and the temperature of the molten aluminum is minimized. By doing so, it is possible to prevent the temperature of the molten aluminum from being lowered and make the properties of the resulting aluminum casting uniform.

  Conventionally, as a method for preheating the ladle as described above, a ladle lid provided with a burner is put on the opening of the ladle, and the inside of the ladle is directly lit by the flame (combustion gas) injected from the burner (See, for example, Patent Document 1).

JP 2012-250238 A

If the inside of the ladle is heated directly by a flame of a burner as in the above prior art, the temperature inside the ladle can be efficiently raised to the target temperature.
However, in the case of a ladle that handles molten aluminum (i.e., a ladle for molten aluminum), if the inside of the ladle is heated directly with a flame from a burner, the molten aluminum remaining as residual droplets in the ladle solidifies. A heat of approximately 1000 ° C. is locally applied to the formed coagulum. Then, the non-metallic inclusions around the α-Al ₂ O ₃ from coagulum is produced, which becomes attached to and accumulates on the inner surface of the ladle becomes deposits. For this reason, there is a problem that the above deposits gradually accumulate on the inner surface of the ladle by repeating direct heating with a burner, the ladle weight gradually increases, and the effective volume inside the ladle decreases. It was. In addition, by depositing such deposits, some of the deposits fall into the molten aluminum stored in the ladle, and this (= non-metallic inclusions) is cast. There was also the problem of causing defects such as hard spots at times.

  Therefore, the main problem of the present invention is that the inside of the ladle for molten aluminum can be efficiently preheated, and even if the ladle is repeatedly preheated and used, the reduction in the effective volume of the ladle is minimized. An object of the present invention is to provide a preheating method for a ladle for molten aluminum and a preheating apparatus using the method, which can suppress the contamination of the molten metal by nonmetallic inclusions.

In order to solve the above problems, the present invention is configured as follows, for example, as shown in FIGS.
In the preheating method of the molten aluminum ladle 12 that preheats the inside of the ladle 12 with a flame 30 injected from a burner 24 attached to the opening 16 of the molten aluminum ladle 12, the flame 30 is made of a heat-resistant material. It is characterized by being surrounded by a preheating tube 26 made of a thin metal plate material.
Here, “heat resistance” of the thin metal plate material constituting the preheating tube 26 refers to heat resistance to such an extent that the shape of the material does not change even if the flame 30 injected from the burner 24 is surrounded in the vicinity thereof.

For example, as shown in FIGS. 1 to 3, the present invention operates as follows.
That is, since the periphery of the flame 30 injected from the burner 24 is surrounded by the preheating pipe 26, the inside of the ladle 12 is not directly heated but heated indirectly through the preheating pipe 26. For this reason, it is possible to prevent the formation of a high-temperature region near 1000 ° C. locally on the inner surface of the ladle 12 while maintaining the heating characteristics of the burner 24 such that the temperature rises quickly. As a result, it is possible to minimize adhesion of non-metallic inclusions centering on α-Al ₂ O ₃ on the inner surface of the ladle 12.

A preheating apparatus according to the second invention is an apparatus for carrying out the above-described method, and is configured as follows, for example, as shown in FIGS.
That is, the burner 24 which injects the flame 30 toward the inside from the opening part 16 of the ladle 12 for molten aluminum, and the preheating pipe | tube 26 which consists of a heat resistant metal thin plate material and surrounds the said flame 30 are provided. It is characterized by.

  According to the present invention, in addition to being able to efficiently preheat the inside of the ladle for molten aluminum, reduction in the effective volume of the ladle can be minimized even if the ladle is repeatedly preheated and used. In addition, it is possible to provide a preheating method for a ladle for molten aluminum and a preheating apparatus using the method, which can reduce contamination of the molten metal due to non-metallic inclusions.

It is a fragmentary sectional view which shows the ladle for molten aluminum equipped with the preheating apparatus of one Example of this invention. It is a fragmentary sectional view which shows the outline of the preheating apparatus of one Example of this invention. It is a graph which shows the relationship between the frequency | count of use of the ladle for molten aluminum, and its weight increase rate.

Embodiments of the present invention will be described below with reference to FIGS. FIG. 1 shows an example of a ladle 12 for molten aluminum equipped with a preheating device 10 of the present invention.
Here, first, the ladle 12 for molten aluminum will be described with reference to FIG. The ladle 12 for molten aluminum of the illustrated embodiment has a bottomed and cylindrical main body 14. An opening 16 is provided on the upper surface of the main body 14, and a large lid 18 is disposed in the opening 16. In addition, flanges (not shown) are provided on the outer circumferences of the main body 14 and the large lid 18, and the flanges are fastened with bolts (not shown) to fix them.

  The main body 14 has a metal casing 14a that forms the outer periphery thereof, and a heat insulating material 14b and a refractory material 14c are attached to the inside of the casing 14a in this order. A flow path 14 d for taking out the molten aluminum from the inside of the main body 14 is provided at one place on the outer periphery of the main body 14. Further, two fork insertion parts 20 having a predetermined length in a hollow rectangular shape in which a fork of a forklift is inserted are attached to the bottom surface of the main body 14 so as to be parallel to each other.

  Similarly to the main body 14, the large lid 18 has a refractory material 18 a attached to the inner surface thereof. At the center of the large lid 18, there is provided an opening 18b that communicates the outside of the large lid 18 with the opening 16 and serves as a hot water inlet. The opening 18b is a hatch that opens and closes the opening 18b. 22 is attached. The hatch 22 is attached to the large lid 18 via a hinge (not shown). And when preheating the inside of the ladle 12 for molten aluminum, the preheating apparatus 10 is inserted through the opening 18b from the opening 18b with this hatch 22 opened.

The preheating device 10 is generally composed of a burner 24, a preheating pipe 26, and a drive mechanism 28.
Among them, the burner 24 is a device for injecting a heating flame 30 into the main body 14 of the ladle 12 for molten aluminum, a gas fuel burner using city gas / liquefied petroleum gas (LPG) or the like as fuel, heavy oil / Any liquid fuel burner using light oil, kerosene, gasoline or the like as fuel can be used. In addition, a flange 24a is provided at a portion of the burner head where a flame injection port (not shown) of the burner 24 is provided, and a preheating pipe 26 is connected to the burner 24 via the flange 24a. In FIG. 1 and FIG. 2, illustration of a piping system and the like connected to the burner 24 is omitted.

  The preheating tube 26 is a bottomed cylindrical tube that surrounds the periphery of the flame 30 injected from the burner 24. The preheating tube 26 is a metal thin film having such a heat resistance that the material shape does not change even if the flame 30 injected from the burner 24 is surrounded in the vicinity thereof, such as heat resistant steel such as SUS309S or SUS310S in JIS standard. It consists of a plate material.

Further, a refractory material 26a such as castable is laid on the bottom of the preheating pipe 26, and one or a plurality of (two in the example shown in FIGS. 1 and 2) exhaust holes are provided on the side peripheral surface in the vicinity thereof. 26b is drilled.
Here, by providing the exhaust hole 26b at such a position, high-temperature combustion exhaust gas discharged together with the flame 30 by the burner 24 is supplied into the main body 14 of the ladle 12 for molten aluminum. And this combustion exhaust gas is discharged | emitted outside the ladle 12 for molten aluminum, after circulating through the inside of the main body 14, or directly via the flow path 14d. That is, by providing the exhaust hole 26b at such a position, in addition to the radiant heat generated when the flame 30 heats the preheating pipe 26, high-temperature combustion exhaust gas that reaches the entire internal space of the ladle 12 for molten aluminum is also included in the ladle 12. Contributes to preheating. As a result, the entire inside of the ladle 12 for molten aluminum can be preheated efficiently.

  Further, a refractory material 32a such as a castable is disposed on the lower surface of the upper outer periphery of the preheating pipe 26. When the preheating device 10 is attached to the ladle 12 for molten aluminum, as shown in FIG. A collar portion 32 that functions as a sealing lid that closes the 18 holes 18 b is provided.

  The drive mechanism 28 is a mechanism for vertically driving the burner 24 and the preheating pipe 26 connected thereto, and includes a pair of left and right arms 34 erected on the upper surface of the flange portion 32 and an upper end of the arms 34. A horizontal rod 36 installed on the horizontal rod 36, a hanging metal fitting 40 to which a hook 38 of a lifting device such as a hoist is attached, and a pair of left and right hanging arms 42 suspended from above. Therefore, the horizontal rod 36 is inserted into guide holes (not shown) drilled at both ends in the longitudinal direction, and is connected to the horizontal rod 36 via the arm 34 and the collar portion 32. And a hanging arm 42 for guiding the vertical movement of the preheating tube 26 and the burner 24.

Next, the operation and effect when the ladle 12 for molten aluminum is preheated using the preheating device 10 configured as described above will be described.
FIGS. 3A and 3B show a case where the molten aluminum ladle 12 is preheated only by a burner without using a preheating pipe (conventional example) and a case where the preheating device 10 having the above configuration is used (example). It is the graph which showed the relationship between the frequency | count of use (number of shipments) of the ladle 12 and the weight increase rate.
In both the above-described conventional examples and examples, the increase in the weight of the molten aluminum ladle 12 is a result of non-metallic inclusions centering on α-Al ₂ O ₃ being generated and adhered inside.

Further, in both the above-described conventional examples and examples, a gas burner having a maximum output of 100,000 kcal / h was used as a burner, and preheating was performed until the inside of the ladle 12 for molten aluminum reached 700 ° C.
Further, the preheating tube 26 of the embodiment is made of SUS310S (JIS) with a plate thickness of 5 mm, and has an outer diameter of 200 mm and an overall length of 1,115 mm, and a refractory material 26a made of castable with a thickness of 50 mm is laid inside the bottom surface. At the same time, a pair of φ120 mm exhaust holes 26b provided in contact with the upper end of the refractory material 26a was used.

As shown in FIG. 3, in the conventional example in which the ladle 12 for molten aluminum is heated directly with a flame of a burner, when the ladle 12 is used more than 500 times, the weight of the ladle 12 is approximately 25%. It will increase more. On the other hand, in this embodiment using the preheating tube 26, even if the ladle 12 is used more than 600 times, its weight increase rate does not exceed 10%. That is, this can prevent locally forming a high temperature region near 1000 ° C. locally on the inner surface of the ladle 12 for molten aluminum using the preheating method and the preheating device 10 of the present invention. As a result, it means that adhesion of non-metallic inclusions centering on α-Al ₂ O ₃ to the inner surface of the ladle 12 can be minimized.

  As described above, according to the preheating method and the preheating device 10 of the present invention in which the flame 30 is surrounded by the preheating pipe 26 when the ladle 12 for molten aluminum is preheated by the flame 30 of the burner 24, the ladle for molten aluminum is obtained. Even if the pan 12 is repeatedly preheated and used, a decrease in the effective volume of the ladle 12 can be minimized, and contamination of the molten metal due to non-metallic inclusions can also be reduced.

  In the illustrated embodiment described above, the exhaust hole 26b of the preheating pipe 26 is provided on the lower end side of the preheating pipe 26. However, the position of the exhaust hole 26b is not limited to this, and is not illustrated, for example. However, you may make it provide this exhaust hole in the position close | similar to the burner of a preheating pipe upper part. In this case, heat exchange may be performed between the high-temperature combustion exhaust gas discharged from the exhaust hole and the combustion air supplied to the burner.

  In the illustrated embodiment, a straight straight tube is used as the preheating tube 26. However, the preheating tube 26 has any shape that surrounds the flame 30 of the burner 24. Alternatively, for example, the shape may be such that the lower outer diameter and inner diameter are enlarged or reduced via a step provided in the middle of the circular tube.

  Furthermore, the case where the drive mechanism 28 of the preheating device 10 includes a pair of left and right arms 34, a horizontal rod 36, a hanging metal fitting 40 to which a hook 38 of a lifting device is attached, and a pair of left and right hanging arms 42 is shown. However, the drive mechanism 28 may have any form as long as the burner 24 and the preheating pipe 26 connected thereto can be driven up and down along a predetermined flow line. It is not limited.

Claims (2)

An aluminum molten ladle (12) that preheats the inside of the ladle (12) with a flame (30) sprayed from a burner (24) attached to an opening (16) of the molten aluminum ladle (12). In the preheating method,
A preheating method for a ladle for molten aluminum (12), wherein the flame (30) is surrounded by a preheating pipe (26) made of a heat-resistant thin metal plate.   A burner (24) for injecting a flame (30) from the opening (16) of the ladle for molten aluminum (12) toward the inside thereof, and surrounding the flame (30) made of a heat-resistant sheet metal material. A preheating device for a molten aluminum ladle (12), comprising a preheating pipe (26).

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