KR101569359B1 - Apparatus for supporting nozzle - Google Patents

Abstract

The nozzle support apparatus according to the present invention includes: a nozzle housing installed while surrounding a molten metal supply nozzle; And a housing support portion supporting the nozzle housing and configured to absorb thermal expansion of the nozzle housing due to high temperature of the melt supply nozzle heated from the melt.
As described above, according to the present invention, since the housing supporting portion is formed to have a non-fixed shape so as to absorb the thermal expansion of the nozzle housing due to the high temperature of the molten metal supply nozzle, the downward bending deformation of the nozzle housing is prevented, and the downward bending deformation does not occur in the molten metal supply nozzle Accordingly, it is possible to uniformly supply the molten metal through the molten metal supply nozzle, thereby preventing the defects of the profile of the magnesium plate, thereby improving the product quality.
In addition, since the reinforcing member for connecting and fixing the upper and lower portions of the nozzle housing to the support plate together with the downward bending deformation prevention of the nozzle housing described above is constituted, it is possible to prevent deflection of the melt supply nozzle on the side of the front side, As a result, the lower roll of the roll type casting machine is prevented from being excessively pressed, thereby reducing the degree of abrasion and reducing the damage of the melt supply nozzle.

Description

[0001] APPARATUS FOR SUPPORTING NOZZLE [0002]

The present invention relates to a nozzle support apparatus, and more particularly, to a nozzle support apparatus for preventing downward bending deformation of a nozzle housing so as to uniformly supply molten metal through a melt supply nozzle.

Magnesium has a density of 1.74 g / cm3 and is the lightest among all commonly used structural metals. Magnesium, which is used industrially, is made of an alloy mainly composed of aluminum, zinc, manganese, rare earth metals and the like, thereby making an alloy having a high strength to weight ratio.

These magnesium alloys are used for aircraft, missiles, machinery, tools, material handling devices, and automobile parts. In recent years, excellent vibration and shock absorbing properties and electromagnetic shielding properties have been recognized, The demand is expanding.

In addition, most of the magnesium components have been manufactured by the die casting method because the magnesium alloy has a low atomic structure (HCP) except for a very small part, and the rolling property and the formability are poor. However, studies on the production of magnesium alloy sheets through the rolling process due to the high rejection rate and post-treatment process of labor-intensive die casting products have been actively carried out, and as a result, 160 to 300 degrees Celsius) and rolling under the appropriate kneading conditions.

On the other hand, strip casting is a process that is currently in the limelight as another method of manufacturing a magnesium alloy sheet material. This process is a very effective process that can transfer the molten magnesium alloy through a pump and flow it between two rolls, so that the plate material can be manufactured rapidly by rapid cooling at the part touching the roll. The magnesium alloy It has the advantage that the plate can be manufactured as a coil.

The strip-cast plate has a minimum thickness of about 4 mm to 6 mm, which is actually thick for application as a component material in an industrial field. Therefore, most of the coils produced by strip casting can be subjected to warm rolling process to obtain a plate having a thickness of 1 mm or less.

1, the magnesium ingot hardened by the ingot case 1 is introduced into the casting furnace 2, and in the casting furnace 2, the magnesium ingot is again cast into the casting furnace 2, It is dissolved and transformed into magnesium in a molten state.

The molten magnesium is moved to the supply line 4 connected to the nozzle portion 7 by the molten metal pump 3 mounted on the casting furnace 2. At this time, a heating device 5 is installed in the supply line 4 so as not to lower the temperature of the molten magnesium. Accordingly, the molten magnesium can be delivered to the nozzle unit 7 while maintaining the melting temperature. The magnesium that has passed through the heating device 5 passes through the nozzle section 7 after passing through the head box 6 which is the level of the molten magnesium and the temperature control facility and is fed to the twin roll caster 8, Through various rolling processes, and is made of a magnesium plate having a desired thickness.

Since the molten magnesium in the molten state of the nozzle unit 7 is heated to 650 ° C., the molten metal supply nozzle 7 a, which is in direct contact with the molten metal in the nozzle unit 7, is made of a ceramic material.

However, since the nozzle housing 7b that covers and supports the molten metal supply nozzle 7a is made of steel, the molten metal is supplied with high heat from the molten metal supply nozzle 7a, and thermal expansion is performed. That is, since the conventional nozzle housing 7b is completely fixed to the fixing member 7c to be mounted, the shape of the nozzle housing 7b is deformed during thermal expansion.

In this case, the upper portion of the nozzle housing 7b undergoes downward bending deformation due to its own weight during thermal expansion. As a result, the molten metal supply nozzle 7a disposed in the nozzle housing 7b is also downwardly pressed, There is a problem in that quality of the magnesium plate material is deteriorated due to uneven supply of the molten metal in the width direction of the steel plate 7a.

It is an object of the present invention to provide a nozzle support device for preventing a downward bending deformation of a nozzle housing to uniformly supply molten metal through a melt supply nozzle.

According to an aspect of the present invention, there is provided a nozzle support apparatus including: a nozzle housing enclosing a melt supply nozzle; And a housing support portion supporting the nozzle housing and configured to absorb thermal expansion of the nozzle housing due to high temperature of the melt supply nozzle heated from the melt.

Specifically, the housing support includes: a support plate mounted on both lower sides of the nozzle housing in the width direction; And a stationary base fixed to the support plate so as to be movable along the width direction of the nozzle housing.

For example, a rail may be formed along the width direction of the nozzle housing at one of the support plates and the fixed base, and a rail groove may be formed at the other of the joints to receive the rail.

The rail groove and the rail may be spaced apart from each other along the longitudinal direction of the nozzle.

The housing support portion may further include a stopper disposed on the support plate and spaced apart from the support plate in the width direction of the nozzle housing and fixed to the fixation base so as to restrict movement of the support plate.

The housing support portion may further include a reinforcing member connected and fixed to upper and lower portions of the nozzle housing with the melt supply nozzle therebetween and connected and fixed to the support plate.

The nozzle support device according to the present invention is configured such that the housing support portion is non-uniformly configured to absorb the thermal expansion of the nozzle housing due to the high temperature of the melt supply nozzle, thereby preventing downward bending deformation of the nozzle housing, As a result, the supply of the molten metal through the molten metal supply nozzle is made uniform, thereby preventing the malfunction of the profile of the magnesium plate, thereby enhancing the product quality.

In addition, since the reinforcing member for connecting and fixing the upper and lower portions of the nozzle housing to the support plate together with the downward bending deformation prevention of the nozzle housing described above is constituted, it is possible to prevent deflection of the melt supply nozzle on the side of the front side, As a result, the lower roll of the roll type casting machine is prevented from being excessively pressed, thereby reducing the degree of abrasion and reducing the damage of the melt supply nozzle.

1 is a schematic view showing a process of manufacturing a magnesium plate.
FIG. 2 is a side view showing a molten metal supply nozzle for supplying a molten metal for manufacturing the magnesium plate of FIG. 1, and a nozzle support device for supporting the molten metal supply nozzle.
FIG. 3 is a view showing a downward bending deformation of the nozzle housing due to thermal expansion due to high temperature of the melt supply nozzle in the nozzle support apparatus of FIG. 2. FIG.
FIG. 4 is a view showing the top downward bending deformation of the nozzle housing of FIG. 3;
Fig. 5 is a view showing the wear surface of the tip portion in the molten metal supply nozzle of Fig. 3;
6 is a side view showing a molten metal supplying nozzle and a nozzle supporting device according to an embodiment of the present invention for supporting the molten metal supplying nozzle.
FIGS. 7A and 7B are views showing the connection between the nozzle support apparatus of FIG. 6 and the head box connected to the melt supply nozzle for supplying the melt.
FIG. 8 is a view showing that the nozzle housing is not bent downward even in thermal expansion due to high temperature of the melt supply nozzle in the nozzle support apparatus of FIG. 6;
Fig. 9 is a view showing that the upper portion of the nozzle housing of Fig. 8 is not downwardly bent.
Fig. 10 is a view showing the wear surface of the tip portion in the molten metal supply nozzle of Fig. 8; Fig.

The nozzle support apparatus of the present invention prevents the downward bending deformation of the nozzle housing in order to prevent the defects of the profile of the magnesium plate and to improve the product quality by making the supply of the molten metal uniform through the molten metal supply nozzle, The housing supporting part is configured to be non-fixed so that the thermal expansion of the nozzle housing due to the high temperature of the molten metal supply nozzle can be absorbed so that the downward bending deformation does not occur in the supply nozzle.

Before describing the present invention in detail, the nozzle support apparatus according to the related art will be described with reference to the drawings.

FIG. 2 is a side view showing a molten metal supply nozzle for supplying a molten metal for manufacturing the magnesium plate of FIG. 1 and a nozzle holding device for supporting the molten metal supply nozzle, FIG. 3 is a cross- FIG. 4 is a view showing a downward bending deformation of an upper part of the nozzle housing of FIG. 3. FIG.

Referring to the drawings, a conventional nozzle support apparatus may include a nozzle housing 12, a support plate 13, a fixing base 14, and a connection fixing member 15.

The nozzle housing 12 is a member that encloses the molten metal supply nozzle 11. The support plate 13 and the fixed base 14 are connected to the nozzle housing 12 in the order of the nozzle housing 12 And the connection fixing member 15 is connected to the rear portion of the nozzle housing 12 located on the front side of the support plate 13 and is connected to the nozzle housing 12 and the support plate 13, (14).

At this time, the fixing pin 19 is inserted into the supporting plate 13 and the fixing base 14 sequentially from the upper surface of the connecting fixing member 15 to thereby fix the connecting fixing member 15, the supporting plate 13, The base 14 is connected and fixed so that the nozzle housing 12 is firmly fixed to the fixing base 14.

Since the nozzle housing 12 which surrounds and supports the molten metal supplying nozzle 11 is made of steel different from the molten metal supplying nozzle 11 made of a ceramic material, the molten metal supplying nozzle 11 is heated by the molten metal As the high temperature of the molten metal supply nozzle 11 is transferred, the molten metal is deformed due to thermal expansion.

In other words, by adopting a structure in which the nozzle housing 12 is firmly fixed to the fixed base 14 by the fixing pin 19, the nozzle housing 12 is constrained in the width direction, And therefore bending deformation occurs.

Particularly, since the nozzle housing 12 has a structure in which the lower portion 12b is in contact with the support plate 13 and the connection fixing member 15, the heat conduction is easily performed toward the fixed base 14, However, since the other member except the melt supply nozzle 11 is not in contact with the upper portion 12a at all, the bending deformation largely occurs as shown in Fig. In addition, when the upper portion 12a of the nozzle housing 12 is flexibly deformed, the downward bending deformation can be more easily performed due to its own weight.

As a result, the molten metal supply nozzle 11 disposed in the nozzle housing 12 is also downwardly biased by the nozzle housing 12 to undergo downward bending deformation, The supply of the molten metal to the center portion is relatively small in the molten metal supply nozzle 11. As a result, an uneven amount of molten metal is supplied to the rolling roll, resulting in defective shape of the magnesium plate material, .

In addition, as the lower portion 11b of the molten metal supply nozzle 11 deformed downwardly is excessively pressed against the lower roll of the twin roll casting machine as compared with the upper portion 11a, the lower portion 11b The degree of wear of the tip portion becomes large and the degree of damage increases.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are displayed on different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 6 is a side view showing a molten metal supply nozzle and a nozzle support apparatus according to an embodiment of the present invention for supporting the molten metal supply nozzle. FIGS. 7A and 7B are views showing the nozzle support apparatus of FIG. And a head box connected to the supply nozzle.

8 is a view showing that the nozzle housing is not bent downward even in thermal expansion due to high temperature of the melt supply nozzle in the nozzle support apparatus of Fig. 6, and Fig. 9 is a cross- Fig.

Referring to the drawings, a nozzle support apparatus of the present invention includes a nozzle housing 12 installed to surround a molten metal supply nozzle 11, and a housing support unit for supporting the nozzle housing 12.

Here, the housing support portion may be non-fixedly configured to absorb the thermal expansion of the nozzle housing 12 due to the high temperature of the molten metal supply nozzle 11 heated from the molten metal, while supporting the nozzle housing 12.

Specifically, the housing support part includes a support plate 130 mounted on both lower sides of the nozzle housing 12 in the widthwise direction, and the support plate 130 is fastened to the upper part of the nozzle housing 12 so as to be movable along the width direction of the nozzle housing 12. [ (Not shown). For reference, the width direction of the nozzle housing 12 is the same as the width direction of the molten metal supply nozzle 11, and refers to a direction perpendicular to the molten metal supply direction through the molten metal supply nozzle 11, It also encompasses directions that intersect obliquely close to vertical.

The support plate 130 has a structure in which two but not one of the support plates 130 are mounted on the nozzle housing 12 and all of the lower surface of the nozzle housing 12 is fastened to the nozzle housing 12 The nozzle housing 12 is fixed to the lower portions of both sides in the width direction of the nozzle housing 12. This is because the molten metal supply nozzle 11 inserted into the center of the nozzle housing 12 is not interfered with the connection space at the time of connection with the headbox connection portion disposed at the rear side, to be.

The fixing base 140 is a portion connected and fixed to the head box 6 so that the supporting plate 130 can be moved along the width direction of the nozzle housing 12 As a preferable example, a rail moving system can be utilized as a non-fixed system. 6, a rail groove 192 is formed in the lower portion of the support plate 130 along the width direction of the nozzle housing 12 and the rail groove 192 is formed in the upper portion of the fixed base 140. [ A rail 191 can be formed. One of the lower portions of the support plate 130 and the upper portion of the fixed base 140 has a rail groove 192 formed along the width direction of the nozzle housing 12, A rail 191 can be formed.

Each of the rail grooves 192 and the rail 191 having the above-described structure may be formed on the lower portion of the support plate 130 or the fixed base (not shown) so as to stably support the nozzle housing 12 having a high weight, 140 may be spaced apart from one another along the longitudinal direction of the nozzle.

According to the present invention, since the nozzle housing 12 is not fixed to the fixed base 140 by the rail moving method as described above, it is not deformed in the process of thermal expansion, but is simply extended in the width direction to a certain extent, The thermal expansion of the nozzle housing 12 due to the high temperature of the molten metal supply nozzle 11 can be absorbed. 9, it is possible to prevent the nozzle housing 12 from being bent downwardly, so that the supply of the molten metal through the molten metal supply nozzle 11 is made uniform, It is possible to prevent the defects of the profile of the plate material and to improve the quality.

In addition, the nozzle housing 12 is not bent downwardly, so that the molten metal supply nozzle 11 is not pressed downward, and the downward bending deformation of the molten metal supply nozzle 11 does not occur. The lower roll of the twin roll type casting machine is not excessively pressed against the lower roll, so that the degree of wear of the lower end portion becomes smaller as shown in FIG. 10 as compared with FIG. 5, so that the damage of the melt supply nozzle 11 can be reduced.

The housing support may further include a stopper 160 disposed to be spaced apart from the support plate 130 in the width direction of the nozzle housing 12 so as to restrict movement of the support plate 130.

The stopper 160 restricts the movement of the support plate 130 relative to the fixed base 140 within an appropriate range due to the thermal expansion of the nozzle housing 12 in the above-described rail movement mode. That is, when the support plate 130, which is movably coupled to the fixed base 140, is moved beyond the proper range to one side, the stopper 160 is moved to the rear side of the melt supply nozzle 11 Tight connection between the connecting portion of the box, which is the path through which the molten metal is supplied, and the molten metal supply nozzle 11, or may be separated from the fixed base 140.

The housing support portion is connected and fixed to the upper portion 12a and the lower portion 12b of the nozzle housing 12 with the melt supply nozzle 11 interposed therebetween, (150).

Hereinafter, a nozzle support apparatus according to the related art will be described with reference to the drawings.

2, in the conventional nozzle support apparatus, only the lower portion 12b of the nozzle housing 12 is fixed in association with the fixed base 14, so that the nozzle housing 12 is thermally expanded, and the downward bending deformation The front end side (front end side) of the nozzle housing 12 goes down. That is, only the lower portion 12b of the nozzle housing 12 is connected and fixed by the connecting and fixing member 15, so that the overall position in the longitudinal direction is constant in the course of downward bending deformation of the upper portion 12a of the nozzle housing 12. [ It can be rotated in the counterclockwise direction. Of course, since the nozzle housing 12 is heavy in weight at this time, the occurrence of sagging of the nozzle housing 12 due to the connection and fixing structure of the lower portion 12b of the nozzle housing 12 described above can be increased.

The lower portion 11b of the molten metal supplying nozzle 11 is bent in the direction of the side of the twin roll casting machine 11 as compared with the upper portion 11a. As a result of the excessive rubbing against the lower roll, the degree of wear of the front end portion of the lower portion 11b becomes larger as shown in Fig. 5, and the degree of damage becomes larger.

In order to prevent this, the present invention may further include a reinforcing member 150 in the housing supporting portion as shown in FIG.

Specifically, the reinforcing member 150 is connected and fixed to the support plate 130, and is fixedly connected to the upper portion 12a and the lower portion 12b of the nozzle housing 12, This can eventually prevent deflection of the melt supply nozzle 11 on the side of the tip portion.

As a result, the lower portion 11b of the molten metal supply nozzle 11 is not excessively pressed against the lower roll of the twin roll caster as compared with the upper portion 11a, The degree of abrasion of the tip end portion of the upper end portion 11b is reduced, thereby reducing the damage.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

11: molten metal supply nozzle 11a: upper (of molten metal supply nozzle)
11b: (of molten metal supply nozzle), bottom 12: nozzle housing
12a: upper (of nozzle housing) 12b: lower (of nozzle housing)
130: support plate 140: fixed base
150: reinforcing member 160: stopper
191: rail 192: rail groove

Claims (6)

A nozzle housing 12 enclosing the molten metal supply nozzle 11 and including an upper portion 12a and a lower portion 12b with a cross section of symmetry with the molten metal supply nozzle 11 interposed therebetween; And a housing support configured to absorb the thermal expansion in the width direction of the nozzle housing (12) due to the high temperature of the molten metal supply nozzle (11) heated from the molten metal while supporting the nozzle housing (12)
The housing support portion is provided at a position facing the width direction of the nozzle housing (12) in the same direction as the width direction of the molten metal supply nozzle (11) as a direction perpendicular to the supply direction of the molten metal through the molten metal supply nozzle A support plate 130 separately mounted on each of the lower portions; And a fixing base (140) movably coupled to the support plate (130) along the width direction of the nozzle housing (12)
A rail 191 is formed along the width direction of the nozzle housing 12 at one of the supporting plate 130 and the fixing base 140 and the rail 191 is attached to the other fixing portion. A rail groove 192 to be fitted is formed,
The nozzle support unit includes a reinforcing member 150 connected to and fixed to an upper portion 12a and a lower portion 12b of the nozzle housing 12 and fixed to the support plate 130.
delete delete The method according to claim 1,
Wherein a plurality of the rail grooves (192) and the rails (191) are spaced apart from each other in the longitudinal direction of the nozzle.
The method according to claim 1,
The housing-
A stopper 160 mounted on the fixing base 140 and spaced apart from the supporting plate 130 in the width direction of the nozzle housing 12 so as to restrict movement of the supporting plate 130;
Further comprising: a nozzle support member for supporting the nozzle.
delete

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