JP2563190Y2 - Mold for continuous casting - Google Patents

Description

[Detailed description of the invention]

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mold for cooling and solidifying a supplied molten metal to form a slab in order to continuously cast a metal such as steel, and particularly to uniformly cool the slab. In addition, the present invention relates to a continuous casting mold that does not allow molten metal to flow out.

[0002]

2. Description of the Related Art In continuous casting, molten metal stored in a tundish is supplied to a mold, where it is cooled to form a solidified slab at least at the outer periphery. This is performed by continuously drawing the slab with a drawing device provided on the downstream side of the mold. In general, a mold used for the continuous casting is such that a molten metal supplied to a hollow portion is solidified into a slab by forming a mold into a cylindrical body and cooling the outer peripheral wall (often with water cooling). The mold is made of a material with excellent thermal conductivity having a hollow part corresponding to the shape and dimensions of the desired slab cross section, and a cooling water jacket is installed outside the mold to cool along the outer peripheral wall of the mold. It is configured to allow water to circulate. Accordingly, the molten metal is deprived of the heat by the cooling water and cooled and solidified to form a slab. The casting direction (axial direction of the mold) of the continuous casting performed in this manner is not limited to vertical, but may be set in a horizontal or inclined direction, and the cross section of the hollow portion may be various such as rectangular, polygonal, and circular. When this mold is classified according to its form, it is divided into the following two types.

(1) A cylindrical fixed mold integrally formed with a cylindrical body In order to obtain a small-section cast piece (a billet), a so-called tubular mold in which a mold is an integral cylinder or square cylinder, There is a so-called assembling mold in which a plurality of mold elements divided in the circumferential direction are brought into close contact with each other to obtain a rectangular slab (slab or bloom) with a cross section, and this is called an assembling mold. The inner peripheral wall of the portion has a continuous, closed cross section, and is used as a fixed mold in which the cross-sectional dimension of the hollow portion does not change during casting.

[0004] By the way, since the slab solidifies and shrinks as it cools, the cross-sectional dimension becomes smaller. Therefore, in a mold in which such a tubular body is integrally formed, the contact between the mold and the slab is maintained. Therefore, an appropriate taper is formed on the inner peripheral wall of the mold so that the downstream side has a small size. However, since the shrinkage of the slab varies depending on many factors such as the type of metal to be cast, the casting temperature, the casting pulling speed, etc., simply forming a taper on the inner peripheral wall of the mold will make the inner peripheral wall of the mold and the surface of the slab uniform. It is difficult to maintain a proper contact, so as a solution to this drawback, shorten this cylindrical fixed mold,
A movable mold (adjustable mold) described below is often installed on the downstream side.

(2) A movable mold (adjustable mold) in which a cylindrical body is formed by a plurality of movable elements that are separated from each other and independent of each other. This is used as a movable mold in which the cross-sectional dimension of the hollow portion changes during casting. The components of the movable mold are spaced apart from each other without being closely attached in the circumferential direction, and are pressed against the slab surface by a biasing means such as a spring or a fluid pressure cylinder. And, in order to make such movement possible, there is a gap between each element of the movable mold, so at the position after an appropriate solidified layer is formed on the surface of the molten metal, that is, at the downstream side of the fixed mold Provided.

As described above, the slab shrinks as it cools and solidifies. However, according to this movable mold, each mold element is pressed against the slab surface, so that good contact with the slab surface is achieved. The slab can be cooled more uniformly than the fixed mold.

As a combination of the cylindrical fixed mold and the movable mold, a horizontal continuous casting facility having a configuration as shown in FIG. 9 is known (for example, Japanese Patent Laid-Open No. 1-2187).
No. 41). Therefore, in order to facilitate understanding of the present invention, the configuration of FIG. 9 which is a background art thereof will be described.

In the figure, reference numeral 1 denotes a tundish for storing molten steel M, and a cylindrical fixed mold 2 is hermetically connected to the tundish 1 via connection refractories 3 and 4. And movable molds 5 and 6 are installed,
On this downstream side, a pulling roll 7 is provided. First, the outline of continuous casting by the horizontal continuous casting facility having the above configuration will be described. Molten steel M is supplied to a tundish 1, temporarily stored therein, and then connected to a refractory 3, 4 and then into a cylindrical fixed mold 2. It flows into, but at the same time in contact with the inner peripheral wall of the cylindrical fixing mold 2, to produce a solidified layer S _C on the contact surface or the molten steel outer periphery. However, since the thickness of the solidified layer S _C is smaller than the diameter of the molten steel, the strength of the slab at this portion is not sufficient. Then, the slab S is the thickness of the solidified layer S _C increases as it is cooled by the movable mold 5 and 6, the thickness of the solidified layer S _C of the vicinity of the outlet of the movable mold 6 10
It has reached 50mm and has sufficient strength. Then, the slab S is pulled out by the drawing roll 7 on the downstream side, and then cut into appropriate dimensions by a cutting device.

As described above, since the molten steel M is finally formed into a slab having a predetermined shape while being cooled by the fixed or movable mold, the slab is uniformly cooled in the cooling process, and the slab is cooled. Various structures have been devised to prevent deformation and cracking. Therefore, FIG.
The equipment configuration will be described. Since the thing shown in FIG. 9 is a facility for obtaining a cast piece having a circular cross section, the cylindrical fixed mold 2 has a hollow section having a tapered shape reduced in the casting direction in consideration of shrinkage of the cast piece due to cooling. And is formed in a cylindrical shape. A cooling water jacket 8 is provided outside the cylindrical fixed mold 2, and cooling water supplied from the cooling water jacket 8 flows along the outer peripheral wall of the cylindrical fixed mold 2. As shown in FIG. 10, the movable mold 5 installed following the cylindrical fixed mold 2 has a total of four elements 9a, 9 surrounding a circular hollow portion.
b, 9c and 9d. Each element 9a, 9b, 9c, 9
“d” indicates that the carbon liner 11 is mounted on the inner surface of the cooling plate 10 made of a copper alloy. In the cooling plate 10, a plurality of pipes 12 through which cooling water flows are arranged.

In FIG. 9, 13 is a cooling water inlet and 14 is a cooling water outlet. Longitudinal direction of movable mold 5 (casting direction)
An end of a rod 18 of an air cylinder 17 is engaged with an engaging member 16 fixed to a plate 15 outside the cooling plate 10 at a substantially intermediate position, and a base end of the air cylinder 17 is screwed to a mold frame 19. Have been. In addition, the movable mold 5
A connecting member 21 is connected to an engaging member 20 fixed to the movable mold 5 near the inlet / outlet side in the casting direction.
A spring 24 is interposed between the pressing member 22 and the insert plate 23 at the other end, and is fastened with bolts 25.

The movable mold 6 is also composed of four elements 9a, 9b, 9c and 9d similarly to the one shown in FIG. The base member is screwed to the mold frame 19 at its base end. An engaging member 20, a connecting member 21, a pressing member 22, a spring 24, and a bolt 25 having the same configuration as described above are also provided near each of the movable mold 6 in the casting direction.

FIG. 11 shows the movable mold elements 9a, 9b, 9
The case where the inner hollow portions c and 9d are rectangular is shown. In this case, the hollow cross section of the cylindrical fixed mold 2 is also rectangular.

The case where a billet having a circular cross section is manufactured by using the continuous casting facility configured as described above will be described below.

(Behavior of cast slab in cylindrical fixed mold) Molten steel M flowing into the cylindrical fixed mold 2 from the tundish 1 is cooled by contacting the inner peripheral wall of the cylindrical fixed mold 2 and solidified on the outer periphery. to generate the S _C. The thickness of the solidified layer S _C gradually increases in accordance with the drawing of the slab S by the drawing roll 7, while the cross-sectional dimension of the slab gradually decreases due to the increased thickness of the solidified layer S _C. I do.
The cylindrical fixed mold 2 is a fixed mold, and does not follow a change in the shape of the slab, but its inner surface extends from the upstream side to the downstream side in consideration of the decrease in the cross-sectional dimension of the slab. It is formed in a tapered shape so that the inner peripheral cross-sectional dimension is reduced. However, since the shrinkage of the slab varies depending on many factors, it is impossible to maintain uniform contact between the inner peripheral wall of the cylindrical fixed mold 2 and the slab in all cases, and the inner peripheral wall of the cylindrical fixed mold 2 is not possible. A gap is formed in a part of the contact portion with the contact member, and a slightly non-uniform contact state occurs, and uneven cooling proceeds to some extent. As a result, the slab shape on the exit side of the cylindrical fixed mold 2 is slightly deformed.

(Behavior of Slab in Movable Mold 5) The role of the movable mold is to perform uniform cooling in the circumferential direction of the slab section in order to prevent the progress of deformation of the slab shape. Elements 9a, 9b, 9c and 9d are connected to air cylinder 17
Each element 9a, 9b, 9 is pressed against the spring force of the spring 24 in the diameter reducing direction against the spring force of the spring 24 so as to conform to the slab shape.
By causing c and 9d to follow, it is possible to secure contact between the movable mold 5 and the slab S over a wide range of the slab S. Then, the slab S is almost uniformly cooled by the cooling plate 10 while being drawn by the drawing roll 7 on the downstream side, and the thickness of the solidified layer S _C gradually increases toward the downstream side. The cross-sectional dimension of the piece S gradually decreases.

The applicant of the present application has filed Japanese Patent Application No. 2-338555 for improving the function of the movable mold. This application is "the inlet of a movable mold, in which the inner diameter of the movable mold is fixed so as to be adjustable". By adjusting the inner diameter of the inlet, the slab is smoothly pulled out, and each moving element is supported by the inlet as a fulcrum. As it can be pressed in the diameter reducing direction, the followability of each moving element to the slab shape is further improved, and the slab and the movable mold come into substantially full contact with each other. It is uniformly cooled without generating.

(Behavior of Slab in Movable Mold 6) The thickness of the solidified layer S _C of the slab S cooled in the movable mold 5 is equal to the thickness of the solidified layer of the entire mold at the entrance side of the movable mold 6. It is about half and has sufficient strength. Therefore, the spring 24 is controlled by the air cylinder 17.
When the respective elements of the movable mold 6 are pressed in the diameter-reducing direction against the spring force of the above, the respective elements 9a, 9b, 9c and 9d almost entirely contact the surface of the slab S, and the slab S and the movable mold 6 does not come into contact with each other, and is uniformly cooled in the longitudinal direction in accordance with the drawing by the drawing roll 7 on the downstream side. It is possible to obtain a billet having a shape almost similar to that of a contracted shape.

As is apparent from the above detailed description, in order to improve the contact between the slab and the mold, each of the components constituting the mold is moved in the radial direction (V direction in FIG. 9). As a fulcrum, the exit side is shown in FIG.
Movable molds are also known in which a movable mold is provided which swings in a direction, or whose components are rotatable in the T direction in FIGS. However, in such a movable mold,
Since each component moves, the gap C ₁ between the cylindrical fixed mold 2 and the movable mold at the joint in the casting direction is set.
(See FIG. 9) or a gap C ₂ between the moving elements in the circumferential direction (see FIGS. 10 and 11) inevitably exists. By the way, the continuous casting mold having such a movable mold has an operational problem that the molten metal inside the slab flows out unless a solidified layer is sufficiently formed on the entire circumference of the slab surface. I have. That is, while the casting is performed smoothly, the solidified layer generated in the upstream cylindrical fixed mold serves as an outer shell to protect the molten metal, so that the gaps C ₁ and C ₂ as described above are formed. It doesn't matter if it exists,
When casting a metal with insufficient formation of a solidified layer or a metal with extremely low hot strength near the freezing point temperature, when the element of the movable mold hits the slab near the movable mold entrance where the solidified layer thickness is thin, There is a possibility that the solidified layer is destroyed and the molten metal inside flows out (breakout). If this breakout occurs in the cylindrical fixed mold or near the entrance of the movable mold, molten metal flows into the gaps C ₁ and C _2, and after the solidified layer is restored, the metal is inserted into the gap and the casting metal is cast. Since the strip cannot be pulled out, the casting cannot be continued thereafter.

The present invention has been made in view of the above-mentioned problems of the prior art, and has as its object to prevent the outflow of molten metal and the insertion of ingots into gaps even when the solidified layer is broken. It is another object of the present invention to provide a continuous casting mold that can resume casting immediately after the solidified layer is restored.

[0020]

In order to achieve the above object, the gist of the present invention is to provide a cylindrical fixed mold hermetically connected to a tundish, and a plurality of cylindrical fixed molds following the cylindrical fixed mold in the circumferential direction of the casting section. In a continuous casting mold in which a movable mold which is divided into elements and is configured to be movable in the casting cross-section radial direction is coaxially connected, a part of the movable mold on the cylindrical fixed mold side or the entire movable mold is removed. The movable mold and the fixed mold were made to have a common frame so that they could be replaced with the fixed mold, and were extended from the fixed mold so that there was no gap at the joint in the casting direction between the fixed mold and the cylindrical fixed mold. A member or a part of the fixed mold and a fixed mold are screwed together with a screwing member, and the fixed mold is formed by utilizing the elasticity of an elastic member interposed in order to adjust the tightening force of the screwing member. In continuous casting mold, characterized in that the Jo stationary mold side is a structure that elastically presses.

[0021]

[Function] Since there is no gap between the cylindrical fixed mold and the fixed mold, even if the solidified layer is broken in the cylindrical fixed mold or near the entrance of the movable mold, the molten metal flows out and the ingot flows into the gap. Insertion can be prevented. In addition, by making the frame of the fixed mold and the frame of the movable mold common, both molds can be appropriately exchanged and used depending on the type of the cast metal, so that a good cast piece can always be obtained.
In addition, since the fixed mold is elastically pressed toward the cylindrical fixed mold using the elasticity of the elastic member, no strong pressing force is generated between the fixed mold and the cylindrical fixed mold, and the fixed mold is fixed. Damage to the mold is suppressed.

[0022]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below with reference to the drawings.

(Embodiment 1) FIG. 1 shows a movable mold 5 shown in FIG. 9 as a fixed mold 26. As shown in FIG. 2 or 3, a carbon liner 27 surrounding a hollow portion and a cooling plate 28 are integrated. The peripheral wall is continuous, so there is no circumferential gap C ₂ ,
In addition, as shown in FIG.
9 and the rear end flange 30 of the cylindrical fixed mold are screwed together with bolts 32 with springs 31 interposed therebetween.
Since the cylindrical fixed mold 2 and the fixed mold 26 adhered closely,
Gap casting direction seam portion C ₁ does not exist. Thus, solidified layer S _C is not the molten metal flows out be destroyed by the tubular within the fixed mold 2. In this case, since the front surface of the carbon liner 27 of the fixed mold 26 is directly pressed against the cylindrical fixed mold 2, the carbon liner may be damaged unless the pressing force is adjusted. However, since the spring 31 is interposed, the fastening force of the bolt 32 is moderately reduced, and the carbon liner 27 is not damaged.
In addition, since the spring 31 is interposed, expansion and contraction of the cylindrical fixed mold 2 due to heat during casting (casting direction).
It follows, it becomes possible to eliminate the clearance C ₁ in the casting direction seam portion.

[0024] (Example 2) This example is, of course is that there is no circumferential clearance C _2, a clearance C in the casting direction seam portion of the cylindrical fixed mold and the fixed mold
₁ (see section A in FIG. 4) and a structure in which the inlet end of the carbon liner does not move due to heat shrinkage (see section B in FIG. 4 and section C in FIG. 5). is there. FIG. 5 is an enlarged view of a portion A of FIG. 4. The structure of the portion A will be described with reference to FIGS. 5 and 4. The carbon liner 27 and the cooling plate 28 are tightly fixed by screws 33 to form a cylindrical fixed mold. The rear end flange 30 and the member 34 are screwed, and the member 35 and the member 34 are further screwed.
A bolt 38 is screwed into a concave portion 36 formed in 5 through a disc spring 37, and an end face of the bolt 38 is pressed against the cooling plate 28. Therefore, the fixed mold 26 is pressed against the tubular fixed mold 2 side while being moderately relaxed by the spring force of the disc spring 37, and follows the expansion and contraction (casting direction) of the tubular fixed mold 2 due to heat during casting. It was not a gap C ₁ is generated in the casting direction seam portion of the cylindrical fixed mold 2 and the fixed mold 26, yet carbon liner 2
7 is not damaged.

The carbon liner 27 is usually fixed to the cooling plate 28 by shrink fitting or screwing. However, due to the difference between the thermal expansion coefficient and the substantial temperature difference between the carbon liner and the copper cooling plate, the carbon liner 27 is cast during casting. Since the liner expands in the casting direction and cools and contracts after casting, the carbon liner may not be present at the specified position. In this case, a gap is formed between the end face of the cooling plate and the end face of the carbon liner, and when the solidified layer is broken, the molten metal enters the gap, and when a bullion occurs, the slab cannot be pulled out. It may be. Therefore, if the carbon liner inlet tip is configured not to move due to heat shrinkage, the situation where the slab cannot be pulled out does not occur. The structure for that is shown in the C section of FIG. 5 and the B section of FIG. 4 in which the A section of FIG. 4 is enlarged. As shown in part C of FIG. 5, the carbon liner 27 and the cooling plate 28 are screwed together with screws 33, and as shown in part B of FIG. Is screwed to the cooling plate 28, and a part of the end face of the member 39 is pressed against the carbon liner 27, so that the inlet end of the carbon liner 27 does not move due to heat shrinkage.

(Embodiment 3) Embodiment 3 is composed of FIG. 6 to FIG. The structure of the portion D in FIG. 6 will be described with reference to FIG. 7 which is an enlarged view thereof. The lateral groove 42 and the vertical groove 43 are formed substantially in a cross shape on the side of the cylindrical fixed mold 2 of the cooling plate 28. A female screw portion 44 is formed in the cylindrical fixed mold 2. The cylindrical fixed mold 2 and the cooling plate 28 are connected by connecting bolts 45 that are inserted into the groove portions 42 and screwed into the female screw portions 44. A spring 46 is interposed between the connection bolt 45 and the bottom of the groove 42. A tapered hole 47 is formed in the connection bolt 45, and the tapered screw 5 having a tapered surface 49 that matches the tapered surface 48 of the hole 47.
0 is inserted in the groove 43.

Further, as shown in FIG. 6, a plate 52 is erected on a slide plate 51 in contact with the cooling plate 28, and the plate 52 is fixed to one member 53a of a two-part guide plate 53, The other member 53b of 53 is fixed to the rear end flange 30 of the cylindrical fixed mold, and the protruding piece 54 is fitted into the member 53a. Further, the guide plate 53 is fixed to the cylindrical fixed mold rear end flange 30 by bolts 55 penetrating the members 53a and 53b (see FIG. 8, which is a cross section taken along the line VIII-VIII in FIG. 6). The structure of the portion E in FIG. 6 is the same as the structure of the portion B in FIG.

Therefore, when the taper screw 50 is screwed and the tapered surface 49 is brought into contact with the tapered surface 48 of the connecting bolt 45 in this configuration, there is no gap C _{2 in the} circumferential direction. 7, the cooling plate 28 moves to the left with the slide plate 51 as a guide surface, and the end face of the cylindrical fixed mold 2 and the end face of the carbon liner 27 come into close contact with each other. As a result, not a gap C ₁ is present in the casting direction seam portion. Also, the spring 4
6 and the spring 40 moderately reduce the pressing force of the carbon liner 27, so that the carbon liner is not damaged.

In the present application, the case where the present invention is applied to the two-stage movable molds 5 and 6 has been described.
It goes without saying that the present invention can be applied to a movable mold having more than two steps.

[0030]

[Effects of the Invention] The present invention is configured as described above, and has the following effects.

(1) Since there is no gap between the cylindrical fixed mold and the fixed mold, even if the solidified layer is broken, there is no outflow of molten metal and no metal ingot, and casting is performed immediately after the solidified layer is restored. Can be resumed.

(2) By using a common mold frame for the fixed mold and the movable mold, the fixed mold and the movable mold can be appropriately exchanged and used depending on the type of metal to be cast. Can be obtained.

(3) Since the fixed mold is elastically pressed toward the cylindrical fixed mold by using the elastic force of the elastic member, a strong pressing force is generated between the fixed mold and the cylindrical fixed mold. However, damage to the fixed mold is suppressed.

[Brief description of the drawings]

FIG. 1 is a side sectional view of a main part of a horizontal continuous casting facility using a continuous casting mold of the present invention.

FIG. 2 is a sectional view taken along the line II-II in FIG.

FIG. 3 is a diagram showing a case where the hollow portion of the mold of FIG. 2 is rectangular.

FIG. 4 is a side sectional view of a main part of a horizontal continuous casting facility using another embodiment of the continuous casting mold of the present invention.

FIG. 5 is an enlarged view of a portion A in FIG. 4;

FIG. 6 is a side sectional view of a main part of a horizontal continuous casting facility using still another embodiment of the continuous casting mold of the present invention.

FIG. 7 is an enlarged view of a portion D in FIG. 6;

8 is a sectional view taken along the line VIII-VIII in FIG.

FIG. 9 is a side sectional view of a main part of a conventional horizontal continuous casting facility using a movable mold.

FIG. 10 is a sectional view taken along the line XX of FIG. 9;

11 is a diagram showing a case where the hollow portion of the movable mold in FIG. 10 is rectangular.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Tundish 2 ... Cylindrical fixed mold 6 ... Movable mold 19 ... Mold frame 26 ... Fixed mold

Claims (1)

(57) [Scope of request for utility model registration] 1. A cylindrical fixed mold hermetically connected to a tundish, and is divided into a plurality of elements in a circumferential direction of the casting section following the cylindrical fixed mold and is configured to be movable in a radial direction of the casting section. In a continuous casting mold in which a movable mold and a movable mold are coaxially connected, a cylindrical fixed model of the movable mold is provided.
Part of the mold side or the entire movable mold can be replaced with a fixed mold
The frame of these movable mold and fixed mold is common
The member extending from the fixed mold or a part of the fixed mold and the fixed mold are screwed by a screw member so that no gap is present at the joint in the casting direction between the fixed mold and the cylindrical fixed mold. A continuous mold having a structure in which the fixed mold is elastically pressed toward the cylindrical fixed mold by utilizing the elasticity of an elastic member interposed to adjust the tightening force of the screw member. Mold for casting.