TWI230738B - Refractory lining inside the cone of metal refining converter and magnesia carbon fire brick - Google Patents

Abstract

The purpose of the present invention is to provide a lining at the restriction part of a converter capable of more suppressing the falling of bricks than before even if the bricks at the restriction part are stack aslant and increasing a workability at the time of installation, in which the shell of the converter at the restriction part is lined with firebricks by tilt stacking to protect the restriction part against melting by hot molten steel and slag, a projectedly bent locking part is provided on the upper and lower surfaces of the firebricks, and the locking part on the lower surface of the firebrick stacked on an upper side is overlapped with the locking part on the upper surface of the firebrick stacked on a lower side.

Description

1230738 发明 Description of the invention [Technical field to which the invention belongs] The present invention relates to the lining of a converter ', in particular, to a brick lining of a converter used for melting steel, especially a brickwork structure of a cone mouth portion of a furnace mouth. [Prior art] Converter is a kind of metallurgical vessel used for melting steel. As shown in Fig. 6, the entire structure is composed of the furnace mouth 1 used for input of raw materials and discharge of the melted furnace 1 resulting from refining; the furnace belly 2 and furnace bottom 3 that hold molten steel and slag and perform refining And a cone portion 4 formed by gradually narrowing the diameter from the furnace belly 2 to the furnace mouth 1 with a large diameter. Moreover, the outer side of the converter 5 is formed by the iron sheet 6, and the inner part which is in contact with high-temperature molten steel and slag is protected by a refractory lined with refractory bricks 7 (referred to as lining). However, the lining of the "tapered surface" 4 is generally a "horizontal brick" in which refractory bricks 7 (hereinafter referred to as bricks) are laid horizontally, as shown in Fig. 4, or As shown in Fig. 5, a "tilt bricklaying" construction method in which a brick surface is bricked from a horizontal slope. In addition, as another method, the following special kung fu techniques are condensed when laying bricks. For example, a proposal has been made to build a brick surface perpendicularly to the iron surface of the tapered surface (see Japanese Patent Document 1). In addition, a technology is disclosed in which a brick having a tapered surface is equipped with a full-scale device, and padlocks are used to prevent the tapered brick from falling down (see Japanese Patent Documents 2 and 3). In addition, a technique is disclosed in which grooves are pre-carved on a brick during construction, and adjacent bricks are integrated with each other to achieve a fall prevention effect (see Japanese Patent Documents 4 and 5). 1230738 According to the experience so far, for obtaining the longevity of the tapered surface portion 4, the construction method of the "tilted brickwork" is better than the construction method of the "horizontal brickwork". This is because the erosion of molten steel and slag generally starts from the furnace belly 2 and expands to the tapered surface portion 4. When it is a "horizontal bricklaying" construction method, it is applied to the bricks located above the melted part. The cause of the downward force 'tends to cause the underlying brick to break. In other words, if the brick is broken and partly falls off, the bearing capacity of the bricks on the entire circumference of the tapered surface disappears, causing an accident that the entire bricks fall off, which prevents the operation from continuing. On the other hand, in the construction method of the "tilted brickwork", the downward force is dispersed and reduced, so the construction method of the "horizontal brickwork" has the effect of reducing the breakage of the bricks. In order to maximize the effect, as disclosed in the above-mentioned Japanese Patent Document 1, it is preferable to lay bricks at a right angle to the wall surface of the furnace. However, "In the technique of Japanese Patent Document 1, if the inclination of the furnace wall is too outdated", there is a problem that the furnace building operation cannot be performed smoothly because the bricks slip during the furnace building. In particular, when the converter is first used (built), coke is added to the furnace for heating, and after the construction lining is dried, the coke is discharged on the contrary. However, at this time, the bricks of the tapered face of the inclined brickwork are peeled off. Case. In addition, as a countermeasure for preventing the drop of the tapered face brick, as described in the above-mentioned Japanese Patent Documents 2 and 3, there is a technique for equipping the brick with a hook, but this causes an increase in material cost. In addition, as described in the above-mentioned Japanese Patent Documents 4 and 5, the technology of integrating the grooves in the tapered surface bricks with preset grooves requires the operation of separately providing grooves, which increases the number of working hours and increases the cost. The problem. The die set used in the stamping and forming of the brick should be 7 1230738. The groove should be concave and convex to produce grooves as disclosed in the aforementioned Japanese Patent Documents 4 and 5. 'In the subsequent heat treatment of the bricks, the Corners are prone to cracks. Accordingly, it is necessary to perform another grooving process after the brick is manufactured. The present invention has been made in view of the above circumstances, and an object thereof is to provide a converter lining which can suppress the shedding of the bricks in comparison with conventional methods even if the bricks of the tapered surface portion are "inclined bricklaying" and have excellent workability during construction. [Japanese Patent Document 1] Shikaihei 3-6 7 0 5 0 [Japanese Patent Document 2] Japanese Patent Laid-open Hei 1 -3 099 1 5 [Japanese Patent Document 3] Shi Kaihei 5-3 7 9 5 Publication 0 [Japanese Patent Document 4] Japanese Patent Publication No. 5 8-3 2 3 1 Publication [Japanese Patent Document 5] Japanese Patent Application Laid-Open No. 5 -2 7 97 1 9 [Summary of the Invention] In order to achieve the above, The purpose has been deliberately studied, and this result is embodied in the present invention. That is to say, the lining of the converter cone surface of the present invention is based on the refractory bricks of the converter cone surface on which the refractory bricks are laid by oblique bricklaying to protect the converter cone surface caused by high-temperature molten steel and molten slag. In the lining, it is characterized in that: convex bending stoppers are provided on the upper and lower sides of the refractory brick, and the stopper under the refractory brick on the upper side and the refractory brick on the lower side are 1230738 The captive portions of the surfaces overlap each other. In addition, in the present invention, it is preferable that the upper and lower surfaces of the refractory brick are perpendicular to the surface of the iron sheet, or the height of the convex bending stopper portion is 5 to 20 mm, or The position of the convex bending stop is set at a position from the end of the side of the iron sheet of the refractory brick and is 1/1 5 to 1/3 of the total length of the brick. According to the present invention, the bricks adjacent to each other up and down are tied to each other by the upwardly-curved bending and restraining portion of the innovative design, so that the bricks are not easy to peel off even if the melting of the furnace belly occurs. In addition, it is possible to prevent the bricks from falling off when laying bricks or vice versa. In short, according to the present invention, even if the brick of the tapered surface portion is a "tilted brick", it is possible to provide the lining of the converter which can suppress the falling of the brick more than conventional methods and has excellent workability during construction. [Embodiment] Hereinafter, an embodiment of the present invention will be described with reference to the drawings. Figure 1 shows the overall impression of the lining of the converter cone face of the present invention. As shown in Fig. 1, the brick 7 used for the lining is a furnace belly brick 8 which is horizontally laid on the furnace belly 2 and is inclined to be laid. Moreover, the main point is that, instead of a brick having only a flat surface like a general brick, as shown in the cross-section of FIG. 2, a brick is used in which the convex surface is provided with a convex bending stop portion 9 on a part of the brick surface. In short, the anchoring portion 9a laid on the lower side of the brick and the anchoring portion 9b on the lower side of the brick overlap each other. According to this, because the bricks adjacent to each other are tied to each other, even if the furnace belly brick 8 and the brick 7 of the tapered surface portion 4 are melted to a certain extent, the bricks under the support are lost, and the bricks above are not easy to fall off. . The reason why the locking portion 9 is made convex is that if it is made concave, it will easily slip off when the bricks are stacked up and down, and when the external force of 1230738 is applied, the bricks may fall off together. In addition, if lined in this way, when bricks are laid, an operator entering the furnace can press the bricks 7 from the front toward the iron sheet side, and only the anchoring portions 9 a of the bricks laid on the upper side fall into the bricks. Since the lower blocking portion 9b is constructed, the load on the furnace building operation is not increased. In addition, as for the manufacture of the brick, it is only necessary to produce a mold frame that can be shaped as described above, and no special cost is required. In addition, since the brick lining for a brick furnace is constructed on a ring-shaped iron sheet, two opposing sides of adjacent bricks that are not rectangular parallelepiped are generally not parallel. In the present invention, the brick is provided with a convex bend to be a polyhedron, so there is no problem in the construction. However, in a technical field different from converters, for example, on the inner wall of a hot blast stove or the like, especially the ceiling, refractory bricks with a stopper have been used to prevent the bricks from falling. As a representative of refractory bricks used in hot blast stoves, etc., the above-mentioned fastening portion (corresponding to 9a in FIG. 1) is provided near the center of the lining thickness direction, and the height of the step difference of the fastening portion is about 25 mm. , And the inclined portion (corresponding to 9 c in FIG. 1) that reaches the step is configured to form an angle of about 30 ° with the horizontal plane of the brick (corresponding to β; [). However, it is difficult to apply such a shape to the lining of a converter due to the following cases. The refractory bricks such as the first hot-air stove have less damage, and generally have a life span of more than ten years before the exchange. On the other hand, since the inner wall of the converter is often corroded by molten steel, its life is at most about i years. Furthermore, when the lining erosion reaches the above-mentioned anchoring portion, the anchoring effect naturally disappears, and therefore, the risk of the brick falling sharply increases. According to this, if, as in the case of a hot blast stove, the anchoring portion is near the center of the lining thickness direction, and when the brick is eroded halfway, the risk of falling of the brick 10 1230738 increases sharply, so there is a problem that the brick exchange frequency increases. Second, the furnace temperature in the hot-blast furnace is 120 ° C. However, the maximum furnace temperature in the converter exceeds 170 ° C. Therefore, the converter environment has a higher heat load than a hot-blast furnace. In addition, in terms of thermal conductivity, MgO-C bricks (magnesia and carbon bricks) used in converters are also larger than silicon bricks used in hot blast furnaces. Therefore, there are cases where the converter is lined, focusing on this system. The force of a deformed part such as a part is larger than that of a hot blast stove. In order to solve the above-mentioned first problem, it is required to set the fastening portion as close as possible to the side of the iron sheet in the thickness direction of the lining. However, the second problem is to place the fastening portion near the edge of the brick or increase the fastening. It is difficult to protrude the part to increase the stopping force. In order to satisfy these opposite conditions, the present inventors tried various shapes and sizes, and found that the problems described above can be solved by the following shapes. First of all, according to the present invention, the shape of the upwardly-curved bent stop is a so-called "hook" shape, a step-like right-angle step or an inclined step, hiragana "~" The shape such as the "S" shape of the Chinese character or the Roman character can be used as long as it has the effect of preventing each other from joining. However, from the viewpoint of the combined effect of the stopping force and the strength of the stopping portion, the slow S-shape shown in FIG. 2 is the best. The convex portion 9a is preferably a curved surface instead of an angle, and is preferably larger in angle than a right angle. This is because the structure can suppress the cracking that starts from the bent corner (corner corner) due to stress concentration. In addition, the inclination angle ((9 1) between the inclined portion 9 c and the horizontal plane of the brick is less than 30 ° ~ 90 °, and more preferably, it is 45 ° ~ 75 °. In other words, if the angle is too small Then the stopping force is insufficient, especially in inclined piles 11 1230738 stacked perpendicular to the furnace wall surface. This tendency increases. On the other hand, if the angle is too large, the stopping portion is easily damaged. In addition, in the present invention, the above The height of the convex bending anchoring portion 9 is preferably 5 to 20 mm. The reason is that if the height is less than 5 mm, the anchoring of the bricks to each other may cause the brick to fall off due to unstable small external forces. If the height is more than 20 mm, In addition, there are reasons for the saturation of the anchoring effect and the suspense of the anchoring part. In addition, in the present invention, it is best to set the position of the convex bending anchoring part 9 away from the iron sheet of the refractory brick. The side end is 1/15 ~ 1/3 of the total length of the lining in the thickness direction. This is because the position of the tie is less than 1/1/1 5 of the full length of the side of the iron sheet of the refractory brick. When the brick is broken, the remaining bricks cannot completely protect the iron sheet, and if it exceeds 1/3, in the depth of erosion or When a downward force is applied, it is easy to cause a fall. In addition, it is more preferable that the full length of the brick is about 1/1 5 to 1 Π 0. In addition, as the above-mentioned bending stop is simple in shape, it is used The mold frame during the manufacture of the brick can be easily formed by providing the unevenness corresponding to the bending stopper in advance. Although there is no requirement for the type of the brick, the aforementioned application of magnesium oxide and carbon brick is still preferred. Regarding the inclination angle of the bricklaying 7 (0 2 in FIG. 1), it is only necessary to have a certain degree of inclination with respect to the level (for example, about 10 degrees), but it is preferably 15 degrees or more. The situation where the surface is perpendicular is the best. This is because the effect of the downward force on the brick 7 is large. (Example) As a cone part of the converter, a brick as shown in FIG. 2 is made to be perpendicular to the iron sheet. In the state, brick 7 is applied to the conical surface part 4 of the converter 5 (Example 12 of the implementation of the present invention 1230738), and the operation of melting the molten steel is performed in the converter. In addition, it is also performed in a converter constructed from bricks having a generally flat surface. Work (comparative example). The material of these bricks 7 is MgO-C series (magnesium oxide and carbon brick) is a so-called "non-burnable" brick made by mixing the mixed powder of Mg0 and C into each mold frame and drying it. The brick of the present invention The dimensions, as shown in Figure 7, are 150mm in height x length (in the direction of the thickness of the padded) 810mmx width 75mm, and the upper convex bending stop 9 is located at the top and bottom. The upward convex bending stop 9 is located away from The end of the iron sheet is located at a position of 75 mm, and an inclined step as shown in FIG. 2 is provided, and the height of the step is i 5 mm. In addition, each part of the brick furnace 5 other than the brick surface part 4 is made of ordinary bricks. The inclination angle (0 1: see FIG. 2) of the inclination 9 c of the inclined portion reaching the step is 60 degrees. In addition, as the construction method of the above-mentioned tapered face brick, Comparative Example 1 is a conventional "horizontal brickwork" ((9 2 = 0 degrees), and Comparative Example 2 is a "tilted brickwork with an inclination angle (0 2) of 12 degrees" "Brick" is an "inclined bricklaying" in which the brick surface is perpendicular to the iron sheet surface in the embodiment of the present invention. Moreover, in conventional flat bricks, it is difficult to exceed the above-mentioned tilt. In addition, it is difficult to change Furnace wall surface), and the tilt of the horizontal brick (0 2: see FIG. 1) in the case of oblique stacking is about 30 degrees. In addition, in the present invention, an iron sheet (0 3 = 90 degrees) perpendicular to the face of the brick furnace cone is used. (Refer to Figure 1)) The best effect can be obtained by laying bricks. However, it is also confirmed that the effect is also 95 to 105 degrees at 0 (Refer to Figure 1) (Refer to Figure 3). In addition, the operation starts from ordinary carbon steel. Most types of steel are melted in various steel types. However, in the comparative example and the present invention, the average and approximately the same steel type (composition) are shown. Figure 3 shows the life index of the cone surface of the converter (the life of the horizontal brickwork 13 1230738 is Benchmark) to evaluate the results of operations performed by such converters. Known g According to the present invention, the life of the converter cone face can be twice as early as the conventional one. This is because in the conventional horizontal brick and inclined brick, the consumption of the brick is a combination of cracks and melting loss. However, by laying bricks perpendicular to the iron sheet, it is possible to disperse the external force applied to the tapered face bricks, thereby suppressing the cause of the cracking of the bricks. In addition, during the lining construction of the brick furnace of the present invention, It is known that the construction will not increase the man-hours of the furnace building operation. In addition, the cost of the brick is only to make a new mold frame, so the manufacturing cost of the brick will not increase. [Simplified illustration of the drawing] Figure 1 shows the invention A cross-sectional view of the overall impression of the cone face of the converter. Fig. 2 is a detailed cross-sectional view showing the cone face of the converter of the present invention. Fig. 3 is a graph showing the life of the cone face of a converter having the cone face of the present invention and a conventional cone face. Fig. 4 is a cross-sectional view of a converter cone face showing the conventional "tiling brick" method. 0 Fig. 5 is a cross-sectional view of a converter cone face showing the conventional "tiling brick" method. turn A cross-sectional view of the structure of a furnace. Fig. 7 shows an example of the size and shape of the brick of the present invention, Fig. 7 (a) is a side view, and Fig. 7 (b) is a top view. (Element symbol description), 1 Furnace mouth 2 Hearth belly 14 1230738

3 Furnace bottom 4 Conical surface part 5 Converter 6 Iron sheet 7 Refractory brick 8 Furnace belly brick 9 Convex and bent retaining part 9 a Anchor part 9b Anchor part 9c Inclined part θ 1 Inclined angle formed by the inclined part 9c and the horizontal plane of the brick Θ 2 tilt angle Θ 3 tilt angle

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Claims (1)

1230738 Scope of application and patent application 1 · A lining of a converter cone face is made of refractory bricks inclined on the iron sheet of the converter cone face to protect the molten steel caused by high temperature molten steel and slag. It is characterized in that: the upper and lower refractory bricks are provided with upper convex bending anchoring portions, and the anchoring portions under the refractory bricks on the upper side and the anchoring portions on the upper refractory bricks are overlapped with each other. 2. The lining of the cone face of the converter according to item 1 of the scope of the patent application, wherein the upper and lower faces of the refractory brick are formed to be perpendicular to the surface of the iron sheet. 3. The lining of the converter cone surface according to item 1 of the scope of patent application, wherein the height of the above-mentioned convex bending stop is 5 to 20 mm. 4 · If the lining of the converter cone surface of item 2 of the patent application is lined, wherein the height of the above-mentioned convex bending stop is 5 to 20 mm. 5. The lining of the converter cone surface according to any one of claims 1 to 4, wherein the position of the above-mentioned convex bending stop is located at the end of the side of the iron sheet of the refractory brick and the total length of the brick 1/1/1 5 ~ 1/3 position. 6. A kind of magnesia and carbon refractory brick, which is a substantially rectangular brick with MgO and C as the main components, which includes: at the end in the length direction of the brick and 1/1 5 to 1 of the total length of the brick The top and bottom of the brick at the / 3 position are provided with upward convex bending restraint portions. 16