KR0169337B1 - Fixing structure for metal frame of sliding nozzle plate - Google Patents

Abstract

The present invention relates to a structure for fixing a plate having a metal case such as a plate refractory used in a sliding nozzle device for a molten metal container to a metal frame.

A fixed structure to a metal frame of a plate in a sliding nozzle device attached to a metal melt container, wherein the plate has at least one molten metal through hole and a metal case surrounding the side and non-sliding surface of the plate refractory. A projection formed of a metal case is provided on the opposite side of the sliding surface, and a recess corresponding to the projection is provided on the metal frame side so that the fitting gap is 0.1-1.0 mm with respect to the sliding direction.

In this way, the fixed plate or the sliding plate for the sliding nozzle device can be easily attached or detached from the fixed metal frame or the sliding metal frame in cold and hot periods. Is simplified.

Description

Metal frame fixing structure of sliding nozzle plate

1 is a plan view of a plate for a sliding nozzle which is an embodiment of the present invention.

2 is a longitudinal cross-sectional view of a plate for a slinging nozzle as seen from line A-A of FIG. 1, which is an embodiment of the present invention.

3 is an enlarged view of the main portion of the cross-sectional view shown in FIG.

4 is a view of FIG. 3 viewed at right angles.

5 is a perspective view showing a second embodiment of the present invention.

6 is a longitudinal sectional view showing a third embodiment of the present invention.

7 is a cross-sectional view of the liner of FIG.

* Explanation of symbols for main parts of the drawings

1: Plate Refractory 2: Metal Case

3: mortar for joint 4: melt-through hole

5: sliding surface 6: protrusion

7 burr height 7 ': joint protrusion

8 cylindrical part 9 air type

10 concave portion of the metal frame 11 metal frame

12 liner 13: hole or recess

14: nozzle coupling hole

The present invention relates to a structure for fixing a plate having a metal case of plate refractory material used in a sliding nozzle device for a molten metal container to a metal frame. The plate as used in the present invention means a top plate and a bottom plate of a two-plate type, a top plate and a bottom plate of a three-plate type.

The plate refractory material used in the sliding nozzle apparatus is known from the metal case as disclosed in Japanese Patent Application Laid-Open No. 48-6932. Further, as a method of fixing the plate to the metal frame, Japanese Patent Application Nos. 49-119422 and 52-115607 Many have been proposed, as disclosed in WO 60-234765.

In Japanese Patent Laid-Open No. 1-218761, a sliding plate positioning method using a nozzle hole and a concentric metal case shape is proposed. This simplifies the attachment of the sliding plate to the sliding metal frame. However, in this proposal, since the metal case for positioning is formed around the molten metal through hole, the outer diameter is increased and the temperature difference between the metal case and the sliding metal frame is increased, so that the metal case and the sliding metal during cold operation are increased. The gap between the frames tended to be small. In some cases, the metal case is inserted into the metal frame and the sliding plate is not pulled out, which may cause trouble in operation.

SUMMARY OF THE INVENTION An object of the present invention is to provide a fixing structure capable of easily detaching or mounting a fixed plate or a sliding plate having a non-sliding surface from a metal frame, and also providing a stable exchange operation even when the temperature after casting is high. In addition, finishing such a plate by a simple manufacturing process is one of the problems.

As a means for solving the above problems, the present invention provides a projection formed on the metal case on the opposite side of the sliding surface for positioning with almost no flow in the sliding direction with the metal frame, and the projection is provided with the metal frame. It has an outer shape in which the fitting gap in the sliding direction is 0.1-1.0 mm, and a cylindrical shape with a diameter having a projection part of one third or less of the width of the plate has a height of 1-5 mm, and has a pneumatic shape curbed in the cylindrical portion. have.

The plate synchronizes the movement of the metal frame with respect to the sliding direction, and also has projections formed in the metal case on the opposite side of the sliding surface in order to simplify the replacement of the plate, and the projections fit in the sliding direction with the frame. It was made to have an external shape which becomes this 0.1-1.0mm. Moreover, in order to prevent the rotational movement of the plate at the time of sliding, it is preferable to make a plurality of protrusions.

The outer diameter of the protrusion was restrained to less than one third of the width of the plate so that the sliding direction gap with the metal frame of the protrusion of the plate at the time of cold did not vary as much as possible depending on the temperature load at the time of casting. In addition, an error occurs between the temperature of the projection of the plate and the temperature of the plate insertion portion of the metal frame, depending on the temperature load during normal casting. That is, the plate side temperature becomes higher than the temperature on the 20-100K metal frame side, and acts in the direction of reducing the gap in the sliding direction. By reducing the outer diameter to one third or less of the plate width, the gap difference in the sliding direction between cold and hot can be reduced. As the gap difference between cold and hot becomes small, the gap becomes too large to prevent the plate from being synchronized with the movement of the metal frame and also becomes so small that the projection does not fall out of the sliding metal frame.

In order to facilitate the coupling and detachment of the metal frame of the plate, the projection has a cylindrical shape of 1-5 mm in height and a continuous air shape in the cylindrical portion thereof. The cylindrical shape of the projection, that is, the height of the coupling part is 1 mm or less. If the back is poor fitting, when the cylindrical height is 5mm or more, the coupling and separation of the plate becomes a movement as if opening the drawer is difficult. In addition, the bending force acts on the protrusions as well as the shear force at the time of sliding, resulting in insufficient strength of the protrusions. In the case where the plate is to be inserted into the metal frame, a continuous air-shaped projection in a cylindrical shape serves as a guide. In addition, by making the air shape, the strength of the protrusion becomes larger than the simple cylindrical shape, and the movement of the metal frame can be reliably transmitted to the plate.

Designed to simplify the coupling and separation between the plate and the metal frame, high precision coupling is employed only in the sliding direction in the critical positioning direction during casting, so that the clearance has a considerable margin in the direction perpendicular to the sliding direction. This clearance makes the separation of the plate simple.

In order to simplify the manufacturing process of the plate of the present invention, the metal case protrusions were provided on the opposite side of the sliding surface, and the cylindrical shape of the protrusions was 5 mm or less in height, and the shape of the air was continuous to the cylindrical portion. The projection of the metal case is combined with the recess on the side of the metal frame. Naturally, the metal case side can be formed into the recess by turning the metal frame side, but a problem arises in the structure of attaching the plate refractory to the metal case. In other words, when the recess is formed on the metal case side, the thickness of the joint of the metal case and the refractory is inevitably added to the height of the recess. Moreover, although the method of providing a recessed part in a refractory body is easy, the crack of a refractory material tends to generate | occur | produce, and it is not preferable.

The method of manufacturing a metal case may be a welding process, a forging process, a press process, a cutting process, or a combination thereof. The single process of the press process is the simplest and most efficient. In the case of press working, it is necessary to press mold to reduce the cost, and it is important to extend the life of the mold by avoiding unreasonable shapes in press processing. That is, by attaching the projection shape of the metal case in the press direction, the cylinder height is 5 mm or less. In addition, an air shape having a continuous curvature in the cylindrical portion was obtained.

1 and 2 are examples of the operation of the two-plate sliding nozzle device on the upper (fixed) plate as the first embodiment of the present invention. (1) is a plate refractory, (2) is a metal case enclosing the sliding surface, and the fire-resistant mortar (3) is filled between (1) and (2). (4) is a molten metal through-hole, and the flow volume of a molten metal is adjusted by mutual sliding movement of two sliding plates with the sliding surface 5. (6) is a projection for positioning the metal frame and the plate, the projection is formed in the cylindrical portion in a continuous smooth surface in the sliding surface direction, the shape is connected as sliding on the horizontal surface of the bottom of the metal case (with knots) Trumpet shape), and the height 7 of the knot becomes the thickness of the joint material filled between the lead and the metal case. 7 'is a joint projection for keeping the thickness of the mortar joint constant like 7'.

The plate refractory material 1 is usually made of alumina, zirconia, zircon, alumina carbon, magnesia or the like. The metal case 2 has a thickness of 1 to 6 mm and is practically produced by press molding using carbon steel having a plate thickness of 3.2 mm. The radius of curvature of the bent portion is to suppress the consumption of the press die during press molding. In order to ensure at least 3-8mm. The mortar was put into this metal case, the plate refractory was pressed in, and it dried then to obtain a plate. Ten small holes (not shown) were drilled into the metal case to depressurize the air during press-fit and promote drying during drying.

3 is a cross-sectional view in the sliding direction in which the engaging portion between the protrusion of the plate and the recess of the metal frame of the present invention is enlarged.

4 is a cross-sectional view of the portion of FIG. 3 viewed at right angles to the sliding direction. The shape of the projection part 6 is a simple circular shape, and the outer shape of the cylindrical part 8 is particularly high, ie, ± 0.2 mm, and the diameter of the circle is 36 mm, which is 1/3 or less of the plate width 200 mm. The protrusions are provided on the opposite side of the sliding surface, and the number of the protrusions is two to prevent the movement of the plate to rotate in the horizontal plane while receiving the sliding force of the metal frame. In the mounting operation of the plate, the pneumatic portion 9 continuous to the cylindrical portion of the projection is first touched by the edge of the recess 10 of the metal frame by the coarse pressing operation of the operator or the automatic mounting device. It slides into the recess 10 along the air shape. The slipped protrusion is almost fixed to the metal frame by the high precision coupling of the cylindrical portion 8 and the metal frame recess. In order to ensure proper positioning, the projections should have a height of 5-15 mm. When the plate comes off when the press-in is released only by fitting, temporary fixation is performed by a compression spring (not shown) or a magnet attached to the metal frame side. In this way, the mounting work can be carried out very simply.

In the following separation operation, if the combination of the cylindrical portion 8 and the concave portion 10 of the metal frame is performed in all directions, only a movement such as opening the drawer can be allowed, so that a clearance of 1-10 mm is allowed in the sliding direction and the right direction. It is considered to have the plate open by twisting the plate in a direction perpendicular to the sliding direction.

5 shows a second embodiment in which the projections are provided at the corners. The fitting gap in the sliding direction with respect to the recess (not shown) of the metal frame with respect to the box-shaped protrusion 6 is 0.3 mm. The clearance gap in the direction perpendicular to the sliding direction is 4 mm.

The length of the projection part in the sliding direction was 60 mm which is 1/3 or less of the plate width 210 mm, and the width of the projection part was 20 mm. The projection has a planar portion 8A having a height of 3 mm on a surface intersecting the sliding direction, and this planar portion 8A receives a sliding force from the metal frame, similar to the outer shape of the cylindrical portion of the first embodiment. The curved surface portion 9, which is continuous in the "

In this way, the shape of the projections in the present invention can be applied to other than the circular shape.

FIG. 6 and FIG. 7 are views of the invention in which the protrusions 6 are coupled to the holes or recesses 13 provided in the liner using the liner 12 without providing the recesses in the metal frame 11. Three examples are shown. Reference numeral 14 denotes a joining hole of the lower nozzle or the upper nozzle, so that the present invention can be applied to an existing apparatus. Of course, since the thickness in the surface pressure direction varies, it is necessary to adjust the tension of the spring or the thickness of the plate refractory. Regarding the numbers, the same numbers as the previous numbers indicate the same parts.

To form the part cut out in the length side portion or the nozzle coupling hole of the liner 12 to facilitate the coupling and detachment of the liner 12 to the metal frame 11, or to be coupled to the hanging jig through the inclined hole And separate. Alternatively, magnets can be combined and separated.

According to this invention, the following effects can be exhibited.

(1) The fixing plate or the sliding plate for the sliding nozzle device can be easily coupled or fixed to the fixed metal frame or the sliding metal frame in cold and hot.

(2) The manufacturing process is simplified in manufacturing the plate by mounting the metal case on the plate refractory.

Claims (3)

A fixed structure to a metal frame of a plate in a sliding nozzle device attached to a metal melting container, wherein the plate is provided with at least one molten metal through-hole and a metal case surrounding the side and non-sliding surface of the plate refractory. The projection part formed by the metal case is provided on the opposite side of the sliding surface, and on the metal frame side, a recess corresponding to the projection part is provided so that the fitting gap is 0.1-1.0 mm with respect to the sliding direction. Metal frame fixing structure. The plate for sliding nozzles formed by a metal case according to claim 1, wherein the protrusion has a cylindrical shape having a diameter equal to or less than one third of the plate width, has a height of 1-5 mm, and has a continuous air shape in the cylindrical portion. Metal frame fixing structure. According to claim 1 or 2, wherein the projections of the metal case has a shape (snapping trumpet shape) that is connected to the horizontal surface of the bottom of the metal case in a smooth curve in the direction of the sliding surface to the cylindrical portion in a sliding manner The plate metal frame fixing structure for sliding nozzles, characterized in that the knot height is matched with the thickness of the joint material filled between the edge and the metal case.