JP2018020331A - Method for mounting ladle packing - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent deviation and tearing of a ladle packing in a slide valve provided on a ladle, and to prevent entry of molten steel between plates constituting a lower nozzle and a slide valve and leakage of the molten steel to the outside.SOLUTION: In a method for inserting a ladle packing 18 containing 65 mass% or more and 70 mass% or less of AlO, 20 mass% or more and 25 mass% or less of SiO, 3 mass% or more and 5 mass% or less of C, and 10 mass% or more and 20 mass% or less of a phenolic resin of a binder between a lower plate 14 and a lower nozzle 16, and then using the ladle packing, a thickness of the ladle packing 18 before insertion is 7.5 mm or more and 8.5 mm or less, a surface temperature of the ladle packing 18 at the time of insertion is 30°C or higher and 40°C or lower, a nozzle case 20 is fastened so that a fastening ratio of the ladle packing 18 is 0.24 or less, the ladle packing 18 between the lower plate 14 and the lower nozzle 16 is compressed, and a temperature of the ladle packing 18 after compression is heated to 350°C or higher.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a method of using a ladle packing attached to a slide valve (injection hole) provided at the bottom of the ladle.

2. Description of the Related Art Conventionally, a slide valve (injection hole) that discharges molten steel in a ladle by sliding and opening and closing is provided at the bottom of the ladle that houses the molten steel.
This slide valve is fixed to the bottom of the ladle, and is provided at the bottom of the ladle, the upper nozzle that guides molten steel to the outside, the slide valve plate that slides in the horizontal direction, and the lower part of the slide valve plate, It has a lower nozzle for pouring molten steel flowing out from the upper nozzle to the outside (tundish).

When pouring the molten steel in the ladle to the tundish, slide the slide valve plate horizontally to bring the upper nozzle, slide valve plate, and lower nozzle into communication, and open the slide valve. Thus, molten steel can be discharged.
As a technique regarding such a slide valve, for example, there are those disclosed in Patent Documents 1 to 3.

Patent Document 1 is a method of attaching a lower nozzle to a pan, and is intended to prevent intrusion of a bullion.
Specifically, it is a technology that reliably hardens the packing without excess and deficiency and reliably prevents the metal from being inserted. The lower plate is attached to the ladle where the lower nozzle is attached to the lower plate provided in the ladle. A packing containing phenol resin is interposed between the lower nozzle and the lower nozzle, and then the packing is heated so as to satisfy the following conditions. The surface temperature of the packing after heating is 350 ° C. or more, the heating time is within 10 minutes, and the value obtained by converting the total heat of heating to the weight unit of the packing is 40 MJ / kg or more.

Patent Document 2 is a technique of a composite seal member at a nozzle joint, and aims to improve quality, productivity, and yield.
Specifically, it is a technology that enables stable continuous casting operation, and aims to contribute to high quality casting with stability by improving quality, productivity and yield, and reducing costs. It is made of refractory material such as zirconia ceramics such as zirconia and zirconia-alumina, siliceous ceramics, alumina, magnesia and spinel ceramics, and has a softening temperature of 1400 ° C. or higher. A molded body containing a resinous binder or the like is pressure-molded into an annular molded body having an inner diameter of 40 to 70 mm, an outer diameter of 80 to 150 mm, and a thickness of 2 to 6 mm, thereby producing a sheet-like annular molded body.

Patent Document 3 is a technique of a refractory structure that sandwiches a refractory property packing, and aims to facilitate assembly.
Specifically, it is a product with joints attached in advance, there is no need for mortar kneading work at the work site, skill level is not required for installation work, and there is no damage to the joint material during packing and transportation by providing a dowel part The present invention provides a molten metal flow rate control device that can reduce the management items at the work site, can be used stably, and can be mechanized for the mounting work of the slide valve device.

  That is, in a molten metal flow rate control device comprising an assembly of a bottom plate, a slide plate, a seal plate, a chute nozzle and an immersion nozzle, a molten steel flow hole is formed in one or more upper end surfaces of the bottom plate, chute nozzle and immersion nozzle. Is a molten metal flow rate control device in which a ring-shaped dowel portion is provided and a joint material made of preform mortar and / or sheet-like packing is attached in advance to the upper end surface inside the dowel portion.

JP 2008-207195 A Japanese Patent Laid-Open No. 2003-25060 JP 55-109550 A

By the way, the lower nozzle (change nozzle) is attached to the lower plate of the slide valve that pours molten steel, and if a few charges are used to stably pour molten steel in the ladle, it is replaced when the ladle is maintained. ing. That is, the lower nozzle is replaced relatively frequently.
The attachment method of the lower nozzle is generally a screw-in type, and the lower nozzle is attached to the slide valve plate so as to be tightened with a ladle packing interposed therebetween.

The ladle packing is replaced every time the lower nozzle is replaced. When the lower nozzle is replaced, it is inserted between the lower plate of the slide valve and the lower nozzle and compressed between them. . At the time of replacement, in order to prevent the molten steel from leaking to the outside, a predetermined pressure needs to be evenly applied to the entire surface of the ladle packing.
However, since the operator performs manual replacement of the lower nozzle, it is difficult to uniformly apply a predetermined pressure to the entire surface of the ladle packing. That is, when manually attaching the lower nozzle, it is difficult to strictly apply tightening torque or the like so that a predetermined pressure is uniformly applied to the entire surface of the ladle packing. Therefore, in the ladle packing compressed non-uniformly, there is a possibility that problems such as undulating bias, peeling, and tearing occur between the lower plate and the lower nozzle of the slide valve.

  For example, Patent Document 1 is a technique suitable for attaching a lower nozzle to a ladle. However, if the temperature and compression rate of the ladle packing are not appropriately set when the lower nozzle is attached, the possibility of being very low However, it is conceivable that the ladle packing is peeled off or torn, and a molten steel feeder is generated. In order to perform the installation work better, various regulations are considered necessary.

In Patent Documents 2 and 3, it is considered that when the temperature of the ladle packing and the compression rate are inappropriate when the lower nozzle is attached, the ladle packing may be peeled off or torn. Moreover, since the said literature does not implement heating of the ladle packing at the time of attachment, there exists a possibility that hardening may become inadequate and molten steel insertion may generate | occur | produce.
Therefore, in view of the above problems, the present invention prevents the ladle packing from being biased or broken in the slide valve provided in the ladle, and the molten steel between the lower nozzle and the plate constituting the slide valve. It aims at providing the usage method of the ladle packing which can prevent a penetration | invasion and the leakage to the exterior.

In order to achieve the above object, the present invention takes the following technical means.
The method of using the ladle packing according to the present invention is that the bottom of the ladle that conveys the molten steel discharged from the converter in the steel making process is attached to the bottom of the ladle and is inserted into the ladle. A cylindrical upper nozzle for discharging the molten steel, and a plate-like slide valve composed of two pieces of an upper plate and a lower plate, which is arranged below the upper nozzle, and which is arranged below the slide valve, A molten steel discharge part composed of a cylindrical lower nozzle capable of communicating with the upper nozzle via the slide valve is provided, and the lower nozzle constituting the molten steel discharge part has a male screw on the outer peripheral wall. The nozzle case is formed so as to avoid a hole through which the molten steel passes during exhaust steel, and the male screw provided on the bottom side of the ladle is male to the nozzle case. By screwing in and tightening the screw The lower nozzle is attached to the bottom of the ladle, and regarding the ingredients, Al ₂ O ₃ is 65 mass% to 70 mass%, SiO ₂ is 20 mass% to 25 mass%, C is 3 mass% to 5 mass In a method of using a ladle packing containing 10 mass% or more and 20 mass% or less of a phenolic resin used as a binder, between the lower plate and the lower nozzle, The thickness of the ladle packing is 7.5 mm or more and 8.5 mm or less, the surface temperature of the ladle packing at the time of insertion is 30 ° C. or more and 40 ° C. or less, and the tightening ratio of the ladle packing is 0.24 or less. And tightening the nozzle case to compress the ladle packing inserted between the lower plate and the lower nozzle, and heating the ladle packing temperature to 350 ° C. or higher after compression. Features.

  According to the present invention, in the slide valve provided in the ladle, the ladle packing is prevented from being biased or broken, and the molten steel enters between the lower nozzle and the plate constituting the slide valve, and to the outside. Leakage can be prevented.

It is the figure which showed the outline of the use use of a ladle, ie, the steelmaking process. It is the side sectional view showing typically the composition of a ladle. It is sectional drawing which expanded and showed each structure of the upper nozzle, a slide valve (injection hole), and a lower nozzle. It is the figure which showed the outline of the attachment part of a lower nozzle typically. It is the figure which showed typically the outline of the nozzle case in which the member which supports a lower nozzle, and a lower nozzle is inserted. It is the figure which showed the attachment method of the lower nozzle typically. It is the figure which showed typically the moment and stress concerning a ladle packing. It is the graph which showed about the stress which has arisen in the ladle packing inside with respect to the time passage at the time of tightening the ladle packing in the state where holding temperature was less than 30 ° C. It is the graph which showed about the stress which has arisen in the ladle packing inside with respect to the time passage at the time of tightening the ladle packing in the state where holding temperature exceeded 40 ° C. It is the graph which showed about the stress which has arisen inside the ladle packing with respect to the time passage at the time of tightening the ladle packing with the tightening ratio of 0.24 or less. It is the graph which showed about the stress which has arisen inside the ladle packing with respect to the time passage at the time of exceeding the fastening ratio 0.24 and tightening the ladle packing. It is the figure which showed the outline of the ladle typically. It is the figure which showed the outline of the upper nozzle typically. It is the figure which showed typically the outline of the plate (upper and lower) which comprises a slide valve. It is the figure which showed the outline of the lower nozzle typically. It is the figure which showed the outline of the ladle packing of this invention typically. It is the figure which showed typically the outline of the heating method of the ladle packing of this invention. It is the figure which showed the outline of the use cycle of a ladle typically. It is the figure which showed typically the metal (molten steel) penetration | invasion state between a ladle packing and a lower nozzle (refractory material). It is the figure which showed typically the biased state of the ladle packing. It is the figure which showed typically the torn state of the ladle packing.

Hereinafter, an embodiment of a method for using a ladle packing according to the present invention will be described with reference to the drawings.
In addition, embodiment described below is an example which actualized this invention, Comprising: The structure of this invention is not limited with the specific example. Therefore, the technical scope of the present invention is not limited only to the contents disclosed in the present embodiment.
The method of using the ladle packing according to the present invention is as follows. When the lower nozzle of the slide valve 11 is attached to the ladle 1 that is a container for housing the molten steel 33 used in the steelmaking field of the steel industry, the ladle 1 is used. This is a technology related to the annular ladle packing 18 used for the joint of the lower nozzle and the holding temperature of the ladle packing 18 before use is set to 30 ° C. to 40 ° C., and the compression ratio of the ladle packing 18 is 0.24 or less. The ladle packing 18 is heated to 350 ° C. or higher after the attachment.

First, the ladle 1 to which the present invention is applied will be described.
FIG. 1 is a schematic diagram schematically showing the use application of the ladle 1. FIG. 2 is a cross-sectional view schematically showing the outline of the shape of the ladle 1. FIG. 3 is a cross-sectional view schematically showing an outline of the slide valve 11 (injection hole) provided on the bottom 2 of the ladle 1.
As shown in FIG. 1, when the molten steel 33 is discharged from the converter 30 into the ladle 1, the molten steel 33 is conveyed to the continuous casting facility 31 by the ladle 1. In the continuous casting process, the molten steel 33 in the ladle 1 is discharged into an intermediate container of a continuous casting facility 31 called a tundish 32 in which the inside is constructed with the refractory 6. The molten steel 33 is cast into the mold of the continuous casting equipment 31 via the tundish 32.

  As shown in FIG. 2, the ladle 1 is an iron container for receiving the high-temperature molten steel 33 discharged from the converter 30 and then transporting it to the next step, the molten steel processing and continuous casting equipment 31. . A refractory 6 is installed in the ladle 1. Regarding the refractory 6, a castable 6 c made of alumina / magnesia is applied to the bottom 2 and the side wall 3 in the ladle 1, and a magnesia / carbon brick 6 d is applied to the slag line 4. Yes.

The discharge of the molten steel 33 from the ladle 1 to the tundish 32 is performed by a molten steel discharge unit including the upper nozzle 7, the slide valve 11, and the lower nozzle.
As shown in FIGS. 2 and 3, the upper nozzle 7 (insert nozzle) is for removing the molten steel 33 charged in the ladle 1 and is a cylindrical member formed of a refractory material. It is. At least one or more of the upper nozzles 7 is attached by being inserted into a through hole opened in the bottom portion 2 of the ladle 1 in which the refractory 6 is constructed on the inner surface of the iron shell 5. That is, the ladle 1 is brought into communication with the outside by the upper nozzle 7 that is attached to the bottom portion 2 so as to penetrate therethrough.

A recess 8 is formed on the lower surface of the upper nozzle 7, and a protrusion 13 formed on the upper plate 12 of the slide valve 11 that controls the discharge of the molten steel 33 is fitted into the recess 8. That is, a slide valve 11 is disposed below the upper nozzle 7.
As shown in FIG. 3, the slide valve 11 is disposed between the upper nozzle 7 and a cylindrical lower nozzle disposed below the upper nozzle 7 with a space therebetween, and the cylindrical upper nozzle 7. And the lower nozzle can communicate with each other.

The slide valve 11 is a plate-like refractory composed of two upper and lower sets, and is housed in a hollow housing 9 attached to the bottom 2 of the ladle 1.
The upper plate 12 is the bottom 2 of the ladle 1 and is attached to the upper portion of the housing 9, and the lower plate is disposed so as to contact the lower portion of the upper plate 12.
A hole penetrating in the vertical direction is formed in the upper plate 12, and the periphery of the penetrating hole is formed in a convex shape upward. The convex portion 13 facing upward is fitted into a recess 8 formed on the lower surface of the upper nozzle 7 so that the upper plate 12 is fixed so as not to move.

That is, the upper plate 12 is attached to the bottom portion 2 of the ladle 1 so that the penetrating hole is substantially aligned with the hole of the upper nozzle 7 and is in a communicating state.
On the other hand, the lower plate is disposed on the lower surface side of the upper plate 12 and has a hole penetrating in the vertical direction. The periphery of the through hole is formed in a convex shape downward. The convex portion 15 facing downward is fitted into a recess 17 formed on the upper surface of the lower nozzle, so that the lower plate and the lower nozzle are integrally fixed. That is, a lower nozzle is disposed below the lower plate.

The lower plate is supported by a slide member, and a hydraulic cylinder 10 is provided at one end of the slide member. The lower plate is slid in the horizontal direction on the lower surface of the upper plate 12 by driving the hydraulic cylinder 10.
That is, the lower plate slides in the horizontal direction while sliding on the lower surface of the upper plate 12 as the slide member slides by expanding and contracting the hydraulic cylinder 10 provided at one end of the slide member.

Now, a lower nozzle (change nozzle) is for guiding the molten steel 33 discharged | emitted from the inside of the ladle 1 below, and is a cylindrical member formed with the refractory material. The lower nozzle is disposed below the upper nozzle 7 and the slide valve 11. The lower nozzle can communicate with the upper nozzle 7 via the slide valve 11.
The lower nozzle 16 is attached to the slide member via a cylindrical nozzle case 20 (holder). That is, the lower nozzle 16 is covered with the nozzle case 20 so as to avoid a hole portion (a tapping hole 19) through which the molten steel 33 passes during exhaust steel.

A circular recess 17 is formed on the upper surface of the lower nozzle 16, and a ladle packing 18 (details will be described later) is inserted into the recess 17.
The nozzle case 20 is a cylindrical member having an inner peripheral diameter that is substantially the same as or slightly larger than the outer peripheral diameter of the lower nozzle 16, and is formed so that the lower nozzle 16 is fitted therein. That is, the nozzle case 20 is for holding the lower nozzle 16 by external fitting.

As shown in FIGS. 3 to 6, a plurality of protrusions 21 (locking portions) that are convex in the horizontal direction are formed on the outer peripheral wall at the top of the nozzle case 20. The plurality of protrusions 21 are inclined in one direction and are provided at a predetermined interval and are male threads.
On the other hand, the slide member provided on the bottom 2 side of the ladle 1 is provided with a lower nozzle support member 22 that supports the lower nozzle 16. The lower nozzle support member 22 is an annular ring member whose inner peripheral diameter is substantially the same as or slightly larger than the outer peripheral diameter of the nozzle case 20.

A plurality of grooves 23 (locked portions) that are horizontally concave are formed on the inner peripheral wall of the lower nozzle support member 22. The plurality of grooves 23 are inclined in one direction and are provided at a predetermined interval and are female threads.
That is, a plurality of grooves 23 of the lower nozzle support member 22 are provided so as to be paired with the protrusions 21 of the nozzle case 20.

  As shown in FIGS. 5 (a) and 5 (b), in the lower nozzle support member 22 of the present embodiment, a groove 23 is inclined on the inner peripheral wall in one direction and at a certain interval. Three are provided. Further, as shown in FIGS. 5C and 5D, in the nozzle case 20 of the present embodiment, the protrusion 21 is inclined on the outer peripheral wall in one direction and is spaced at a certain interval. Provided.

On the other hand, as shown in FIGS. 4 and 6, as a method of attaching the lower nozzle 16 to the bottom 2 of the pan 1, first, a ladle packing 18 is placed in the recess 17 on the upper surface of the lower nozzle 16, The lower nozzle 16 on which the ladle packing 18 is placed is inserted into the nozzle case 20.
Then, the nozzle case 20 is attached to the lower nozzle support member 22, and the protrusion 21 of the nozzle case 20 is fitted into the groove 23 of the lower nozzle support member 22. Then, the nozzle case 20 is rotated in one direction, and the inserted protrusion 21 is moved upward along the groove 23. That is, the nozzle case 20 is inserted into the lower nozzle support member 22, and the protrusion 21 (male screw) of the nozzle case 20 is screwed into the groove 23 (female screw) of the lower nozzle support member 22 and tightened. For example, it is moved from the protrusion 21 indicated by the broken line in the left diagram of FIG. 6 to the protrusion 21 indicated by the alternate long and short dash line.

Then, the protrusion 21 (locking portion) is locked in the groove 23 (locked portion), and the lower nozzle 16 supports the lower plate 14 via the nozzle case 20 and the lower nozzle support member 22. It will be detachably attached to the slide member.
At this time, the thickness of the ladle packing 18 inserted between the lower nozzle 16 and the lower plate 14 is compressed by the lower nozzle 16 and thinned by screwing of the nozzle case 20.

For example, as shown in FIG. 6, when the thickness of the ladle packing 18 before insertion is 7.5 mm or more and 8.5 mm or less, the thickness is compressed to about 1 mm to 2 mm when pressed by the lower nozzle 16.
The lower nozzle 16 is attached to a slide member that supports the lower plate 14, and the hole of the upper plate, the hole of the lower plate 14, the hole of the upper nozzle 7 and the hole of the lower nozzle 16 are made to substantially coincide with each other, By opening the slide valve 11, a tapping hole 19 through which the molten steel 33 flows is formed, and the molten steel 33 in the ladle 1 can be tapped into the tundish 32 from the tapping hole 19.

After the molten steel 33 is discharged, the lower plate 14 is slid in the horizontal direction, the holes of the lower plate 14 and the lower nozzle 16 are shifted in the horizontal direction to cut off the communication state, and the slide valve 11 is closed. For example, the following molten steel 33 can be received.
As described above, specific configurations of the upper nozzle 7, the slide valve 11, and the lower nozzle 16 are, for example, as described in Japanese Patent No. 4836828.

The ladle packing 18 of the present embodiment includes a component in which Al ₂ O ₃ is 65 mass% or more and 70 mass% or less, SiO ₂ is 20 mass% or more and 25 mass% or less, and C is 3 mass% or more and 5 mass% or less. Is adopted.
Now, when the molten steel 33 is poured into the tundish 32 from the ladle 1, the molten steel 33 passes through the hot water outlet hole 19 formed by opening the slide valve 11 for a long time.

Therefore, the ladle packing 18 and the molten steel discharge portion including the upper nozzle 7, the slide valve 11, and the lower nozzle 16 are resistant to thermal shock against thermal shock in the initial passage of the molten steel 33, and wear of the molten steel 33 that passes through the tapping hole 19. Corrosion resistance against chemical erosion caused by is required.
In order to satisfy the above required characteristics, the ladle packing 18 contains 65 mass% or more and 70 mass% or less of alumina, and by adding 3 mass% or more and 5 mass% or less of carbon, the slag 34 or While reducing the wettability with the molten steel 33 and improving the corrosion resistance, and improving the thermal conductivity, it is possible to improve the resistance to thermal shock generated from the expansion difference due to the temperature gradient.

Moreover, the thermal shock resistance can be further improved by adding silica having a thermal expansion coefficient lower than that of alumina to 20 mass% or more and 25 mass% or less to the ladle packing 18.
Moreover, in the ladle packing 18 of this embodiment, the thing containing 10 mass% or more and 20 mass% or less of phenol resin used as a binder is employ | adopted.
The ladle packing 18 containing the above components (Al ₂ O ₃ , SiO ₂ , C) contains 10 mass% or more and 20 mass% or less of a thermosetting resin using phenol and formaldehyde as raw materials. And the whole molten steel discharge | emission part is hold | maintained at a softness, and when the lower nozzle 16 is attached, it can be made to contact | adhere uniformly with the contact surface of the ladle packing 18 and the lower plate 14 uniformly.

The ladle packing 18 is a donut-shaped plate material having a predetermined thickness, and is inserted between the lower plate 14 and the lower nozzle 16 so that the inner hole is aligned with the hole of the lower plate 14 and the hole of the lower nozzle 16. The
Here, the thickness of the ladle packing 18 before being inserted between the lower plate 14 and the lower nozzle 16 will be described.

FIG. 7 is a diagram schematically showing the occurrence of bias due to moment that occurs when the ladle packing 18 is thick.
The nozzle case 20 that holds the lower nozzle 16 is manually tightened by an operator, so that the lower nozzle 16 is inserted in a state that is not parallel to the lower plate 14 at the initial stage of tightening.

  As shown in FIG. 7, the ladle packing 18 at the time of tightening is compressed non-uniformly while twisting in the horizontal direction due to the friction generated on the upper and lower surfaces. At this time, among the pressures applied to the ladle packing 18, a pressure higher than the average is P, and a pressure lower than the average is p (P> p). The average pressure is “a value obtained by dividing the force applied to the ladle packing by the area of the ladle packing”. Regarding the parameters, the friction coefficient is μ, the thickness of the ladle packing 18 is H, and the width of the ladle packing 18 ([outer diameter−inner diameter] / 2) is I.

When the ladle packing 18 is twisted in the horizontal direction, a shear stress of Pμ / IH is generated in the ladle packing 18, causing displacement and elastic deformation.
When the ladle packing 18 is thinner than 7.5 mm, since the cross-sectional area (area in the cross section along the radial direction of the ladle packing) is small, the stress is increased and the ladle is broken.

  On the other hand, when the thickness of the ladle packing 18 is thicker than 8.5 mm, the bending moment due to the friction generated on the upper surface and the lower surface is increased. For example, if the moment of the part where the pressure of p is applied is m and the part where the pressure of P is applied is M, m = H / 2 × p × μ × 2 = Hpμ, M = H / 2 × P Since x μ × 2 = HPμ and P> p, M> m and uneven compression occurs, and a wavy bias occurs in a portion where the applied force is weak.

As mentioned above, in this embodiment, the thickness of the ladle packing 18 before insertion is prescribed | regulated as 7.5 mm or more and 8.5 mm or less. The ladle packing 18 preferably has a friction coefficient μ ≧ 0.75 and a surface roughness Ra ≦ 50 μm.
Then, the surface temperature of the ladle packing 18 when inserting between the lower plate 14 and the lower nozzle 16 is demonstrated.

Since the ladle packing 18 contains a liquid thermosetting resin (phenolic resin), after inserting and tightening between the lower plate 14 and the lower nozzle 16, stress relaxation and stress due to shrinkage due to heating. A decrease occurs. That is, the stress generated in the ladle packing 18 is reduced.
However, the stress generated in the final ladle packing 18 after being inserted and tightened between the lower plate 14 and the lower nozzle 16 and heated is the minimum that does not cause problems such as leakage of hot water (molten steel 33). Must have more than stress.

Now, the ladle packing 18 changes in Young's modulus depending on the applied temperature. For example, when the temperature rises, the Young's modulus of the ladle packing 18 decreases. On the other hand, when the temperature decreases, the Young's modulus of the ladle packing 18 increases.
FIG. 8 is a view showing the stress generated in the ladle packing 18 with respect to time when the ladle packing 18 is tightened in a state where the holding temperature is lower than 30 ° C.

As shown in the left figure of FIG. 8, in this embodiment, the stress which has arisen inside the ladle packing 18 is measured at three locations, and the measurement points are indicated by points A, B and C.
Regarding the ladle packing 18 according pressure P, and pressure measurement point A P _1, the pressure measuring point B and P _2, the pressure P ₃ of the measurement point C, as _{(P 1> P 2> P} 3) Yes.
Further, the minimum necessary tightening force of the ladle packing 18 that does not cause problems such as hot water leakage is F _C, and the stress generated in the ladle packing 18 that changes over time is F _f . Regarding the stress F _f after heat shrinkage, the stress at the measurement point A is F _f -A, the stress at the measurement point B is F _f -B, and the stress at the measurement point C is F _f -C.

As shown in the right figure (graph) of FIG. 8, when the ladle packing 18 is tightened at a holding temperature lower than 30 ° C. and a tightening ratio of 0.24 or less, the stress (F _f -A, F _f -B, F _f -C) exceeds the necessary minimum tightening force F _C and F _C <F _F. However, as mentioned above, if the holding temperature is low, the ladle Since the Young's modulus of the packing 18 is increased, the ladle packing 18 is biased in the process of compressing the ladle packing 18. That is, the stress (F _f -A, F _f -B, F _f -C) generated at each measurement point is different.

On the other hand, FIG. 9 is a graph showing the stress generated in the ladle packing 18 with respect to the passage of time when the ladle packing 18 is tightened in a state where the holding temperature exceeds 40 ° C.
As shown in FIG. 9, when the ladle packing 18 is tightened in a state where the holding temperature is higher than 40 ° C., the elastic modulus is very low and the stress relaxation allowance increases due to the expansion of the plastic region. F _f falls below the minimum required tightening force F _C , resulting in F _c > F _f .

As mentioned above, in this embodiment, the surface temperature of the ladle packing 18 at the time of insertion is prescribed | regulated as 30 to 40 degreeC.
Next, the tightening ratio of the ladle packing 18 will be described.
The tightening ratio of the ladle packing 18 is defined as (thickness of the ladle packing 18 after tightening / thickness of the ladle packing 18 at the beginning of tightening (before insertion)).

FIG. 10 is a graph showing the stress generated in the ladle packing 18 with respect to time when the ladle packing 18 is tightened at a tightening ratio of 0.24 or less.
As shown in FIG. 10, when the ladle packing 18 is tightened at a holding temperature of 30 ° C. or higher and 40 ° C. or lower and a tightening ratio of 0.24 or lower, F _f > F _c always occurs, and hot water leaks occur. Not good.

On the other hand, FIG. 11 is a graph showing the stress generated in the ladle packing 18 with respect to time when the ladle packing 18 is tightened, exceeding the tightening ratio 0.24.
As shown in FIG. 11, when the holding temperature is 30 ° C. or more and 40 ° C. or less and the tightening ratio is 0.24 and the ladle packing 18 is tightened, F _f <F _c after heat shrinkage, There is a very high possibility of problems such as hot water leaks.

Returning to FIG. 10, when the tightening ratio when the ladle packing 18 is tightened is low (0.24 or less), that is, when the volume change rate is high, the stress F _f increases. Further, when the ladle packing 18 contracts with the heating after tightening, the reduction width of the stress reduction becomes small, so that the final stress F _f is improved.
As described above, in the present embodiment, the nozzle case 20 is tightened so that the tightening ratio of the ladle packing 18 is 0.24 or less, and the ladle packing 18 is inserted between the lower plate 14 and the lower nozzle 16 of the slide valve 11. The ladle packing 18 is compressed.

Now, when heating the ladle packing 18 after being tightened, it is desirable to do the following.
When used in tapping steel, the binder (phenolic resin) contained in the ladle packing 18 is volatilized, and the contained raw materials (Al ₂ O ₃ , SiO ₂ , C) are sintered to ensure solidity. It is desirable that

For example, when the heating temperature of the ladle packing 18 is not 350 ° C. or higher, the contained binder does not volatilize and remains, and the sintering of the contained raw material does not proceed.
Therefore, when heating the ladle packing 18 after tightening, it is necessary to heat it to 350 ° C. or higher before using it in the steel output.
From the above, in this embodiment, the ladle packing 18 is heated to 350 ° C. or higher after compression.

As described above, by using the present invention, it is possible to prevent the ladle packing 18 from being biased or torn when tightened, so that the slide valve 11 is opened to form the hot water hole 19, and the hot water hole 19 (nozzle) When passing the steel, it is possible to prevent the molten steel 33 from entering between the lower nozzle 16 and the lower plate 14, and to prevent troubles during the steel output such as leakage of the molten steel 33.
[Experimental example]
Below, this experiment example performed based on the usage method of the ladle packing 18 in this invention is described.

First, the implementation conditions of this experimental example will be described.
As shown in FIG. 12, the ladle 1 used in this experimental example is a molten steel container for holding a molten steel 33 having a carbon content of 2% by mass or less. It has a refractory lining structure having an iron skin 5, a permanent refractory 6a layer, and a workpiece refractory 6b layer.

The iron shell 5 of the ladle 1 is a bottomed cylindrical container, and has an elliptical shape when viewed from above. The iron shell 5 is formed with a height of about 4.3 m (4270 mm), a short diameter of about 4.3 m (4330 mm), a long diameter of about 4.5 m (4510 mm), and a thickness of 20 mm or more. The bottom 2 of the iron shell 5 is curved and its diameter R is 12000 mm. The depth of the ladle 1 is about 3.7 m (3693 mm).
As for the permanent refractory 6a, a high-alumina material is applied on the iron skin 5 side, and a waxy stone material is applied on the workpiece refractory 6b side to form a two-layer structure. As for the workpiece refractory 6b, a regular MgO-C brick 6d is applied to the part that comes into contact with the molten metal surface (slag line part 4), and alumina or magnesia material is used to the part that does not come into contact with the molten metal surface (metal line part). An irregular refractory (castable) 6c is constructed.

As shown in FIG. 13, the upper nozzle 7 is attached to the bottom 2 of the ladle 1 and has a total length of 325 mm, an outer peripheral diameter of the upper surface of 166 mm, an outer peripheral diameter of the bottom surface of 210 mm, and a hole diameter (inner peripheral diameter). A cylindrical member having a diameter of 85 mm or 80 mm.
As the material of the upper nozzle 7, an alumina-carbon refractory is adopted, heated at about 800 ° C. during production, and the contained binder is volatilized.

  As shown in FIG. 14, the upper plate and the lower plate 14 are long plates made of a plate-like refractory having a total length of 510 mm, a width of 240 mm, and a thickness of 40 mm. One hole is opened in each of the lower upper plate and the plate. The center of the hole is a position 180 mm away from one end side of the short sides and a position 120 mm away from the long side (equal intervals). Moreover, the hole diameter of the upper plate and the lower plate 14 is the same diameter (85 mm or 80 mm) as the hole diameter of the upper nozzle 7 described above.

On the other hand, as the material of the upper plate and the lower plate 14, a material obtained by adding zirconia to an alumina-carbon refractory is employed.
The upper plate and the lower plate 14 are overlapped so that the holes of the upper plate and the lower plate 14 are opposite to each other in the longitudinal direction, that is, do not communicate with each other. This state is the closed state of the slide valve 11.

And the molten steel 33 can be discharged | emitted by making the position of a hole the parallel movement of the lower plate 14 with a hydraulic cylinder 10, and making it a communication state, and making the slide valve 11 an open state.
As shown in FIG. 15, the lower nozzle 16 is a cylindrical refractory having a length of 277 mm (276 mm to 278 mm), an upper surface having an outer diameter of 182 mm, and a lower surface having an outer diameter of 148 mm. As the material of the lower nozzle 16, an alumina refractory is used. The hole diameter of the lower nozzle 16 is the same diameter (85 mm or 80 mm) as the hole diameters of the upper nozzle 7, the upper plate, and the lower plate 14.

As shown in FIG. 16, the ladle packing 18 has the components as described in detail above, the outer diameter is 170 mm (range: 165 mm to 175 mm), and the inner diameter is 80 mm (range: 79.5 mm or more). 80.5 mm or less) and a ring-shaped member formed with a thickness of 8 mm (range: 7.5 mm or more and 8.5 mm or less).
As a heat retaining method for the ladle packing 18, the heat is kept for a certain time in the heat retaining chamber.

The heat insulating chamber has a structure in which the inside is hermetically sealed, a thermometer and a heater are attached therein, and the heater operates so as to maintain a set temperature.
As a heat insulation time, at least 1 hour before using the ladle packing 18 is kept warm. Moreover, it is desirable to use the ladle packing 18 within 24 hours after being put in the heat insulation at the longest. The ladle packing 18 that has been kept warm for more than 24 hours is discarded.

As shown in FIG. 17, the heating method of the ladle packing 18 is from a state where the ladle 1 is erected (as shown on the right), and the ladle 1 is tilted sideways so that the slide valve 11 is fully opened (as shown on the left). Figure). In this state, the charcoal 35 (combustion object) is placed in the hot water outlet 19. At this time, it is preferable to place the charcoal 35 so that the charcoal 35 comes near the ladle packing 18.
Next, in addition to the charcoal 35, combustible material such as paper is put into the tap hole 19 and ignited to form a seed fire, and the charcoal 35 is burned. When burning the charcoal 35, a pipe 36 is inserted into the hot water outlet 19 from the lower nozzle 16 side, and oxygen is blown from the pipe 36. By doing in this way, by the combustion of the charcoal 35, heat is transmitted to the ladle packing 18 side, and the ladle packing 18 is heated. Further, the upper plate and the lower plate 14 may be heated by preheating.

In this experimental example, molten steel 33 having a steel output temperature of 1510 ° C. or higher and lower than 1700 ° C. was used. In measuring the molten steel temperature in the ladle 1, a thermometer was inserted into the molten steel 33 at the end of blowing in the converter 30 and measured.
As shown in FIG. 18, the ladle 1 is conveyed to the converter 30 and receives the molten steel 33. The ladle 1 in which the molten steel 33 is charged is conveyed to a molten steel processing step, and component adjustment and inclusion removal in the molten steel 33 are performed. After the molten steel treatment, the ladle 1 is conveyed to the continuous casting facility 31 and injects (discharges) the molten steel 33 into the tundish 32. The empty ladle 1 is also transported to the converter 30 to receive the molten steel 33. The ladle 1 is used in such an operation cycle.

The elapsed time from the time when the molten steel 33 is received by the converter 30 and received by the continuous casting equipment 31 until the molten steel 33 is started to be injected into the tundish 32 is determined as the elapsed time of the molten steel 33 in the ladle 1. The residence time.
In the operation cycle, the residence time of the molten steel 33 in the ladle 1 is set to 30 minutes or more and less than 300 minutes, and injection of the molten steel 33 into the tundish 32 is started after the molten steel residence time. Moreover, the time (injection implementation time) from the start to the end of injection of the molten steel 33 in the continuous casting facility 31 is set to 28 minutes or more and less than 120 minutes.

In addition, after the completion of the molten steel injection into the tundish 32, the time when the ladle 1 is empty until the next molten steel 33 is received in the converter 30 is the unreceived steel of the molten steel 33 in the ladle 1. Time. The unsteel time of the molten steel 33 in the ladle 1 is 50 minutes or more and less than 360 minutes.
Next, the experimental result of the usage method of the ladle packing 18 of this invention is demonstrated according to a figure and a table | surface.

  Tables 1 and 2 show the experimental results of the method of using the ladle packing 18 performed for comparison with the present invention (Comparative Examples 1 to 7). Tables 1 and 2 are a continuation, and are divided into two parts for ease of explanation.

As shown in Tables 1 and 2, the experiment number 1 of the comparative example is not satisfied because the tightening ratio of the ladle packing 18 is 0.51, which greatly exceeds 0.24. As a result, bullion has invaded and is not suitable. In the experiment number 2 of the comparative example, the tightening ratio of the ladle packing 18 is 0.31, which exceeds 0.24 and is not satisfied. As a result, bullion has invaded and is not suitable.
In the experiment number 3 of the comparative example, the heating temperature of the ladle packing 18 is 152 ° C., which is much lower than 350 ° C., and is not satisfied. As a result, the metal is inadequately cured and invaded, which is not suitable. In Experiment No. 4 of the comparative example, the holding temperature of the ladle packing 18 before insertion is 29 ° C., and does not satisfy 30 ° C. or more and 40 ° C. or less. That is, the heat insulation of the ladle packing 18 before tightening is insufficient. As a result, at the time of tightening, the ladle packing 18 is biased, and the bullion has infiltrated.

  In the experiment number 5 of the comparative example, the thickness of the ladle packing 18 before insertion is 7.4 mm and does not satisfy 7.5 mm or more and 8.5 mm or less. As a result, the ladle packing 18 has been broken at the time of tightening, which is not suitable. In Experiment No. 6 of the comparative example, the holding temperature of the ladle packing 18 before insertion is 41 ° C., and does not satisfy 30 ° C. or more and 40 ° C. or less. As a result, the ladle packing 18 has been cut off and is unsuitable. In the experiment number 7 of the comparative example, the thickness of the ladle packing 18 before insertion is 8.6 mm, and does not satisfy 7.5 mm or more and 8.5 mm or less. As a result, the ladle packing 18 is biased at the time of tightening, which is inappropriate.

In the experiment numbers 1 to 4 of the comparative examples, the following problems occurred.
Since the ladle packing 18 is damaged at the time of tightening, when the molten steel 33 is poured into the tundish 32 from the ladle 1, there is a problem that the molten steel 33 leaks from between the lower nozzle 16 and the lower plate 14 to the outside. .
Alternatively, as shown in FIG. 19, when the lower plate 14 and the lower nozzle 16 after replacement are repaired, when the dent 17 in which the ladle packing 18 is interposed is visually confirmed, one of the lower plate 14 and the lower nozzle 16, Or in both, there existed intrusion of the molten steel 33 between the ladle having a length exceeding 1 mm in the diameter outward direction from the hole (the tap hole 19), the ladle packing 18 and the lower nozzle 16 (refractory).

In the experiment numbers 4 and 7 of the comparative examples, the following problems occurred.
As shown in FIG. 20, when the lower nozzle 16 is removed from the slide valve 11 and the thickness of the ladle packing 18 is measured with calipers and visually confirmed, it is between the outer peripheral side and the inner peripheral side (inner hole). It was confirmed that a plurality of wrinkles connecting the outer periphery and the inner periphery occurred.
Referring to the cross section aa in FIG. 20, when the inner side surrounded by the two straight lines (within 5 mm or less) among the four straight lines in the figure is observed from the inner peripheral side (inner hole), it is compressed. It can be confirmed that the thickness is equal to or greater than the average thickness at the time. On the other hand, when both outer sides (with an interval of 5 mm or less) sandwiching the thick part are observed from the inner peripheral side, it can be confirmed that the thickness is equal to or less than the average thickness when compressed.

From the above, in the experiment numbers 4 and 7 of the comparative example, the ladle packing 18 is biased.
In the experiment numbers 5 and 6 of the comparative examples, the following problems occurred.
As shown in FIG. 21, when the ladle packing 18 is tightened and heated and then removed and observed, the original state was annular, but part of it was sheared (cut into pieces), and the surface was continuous. Sex was interrupted and it was no longer circular.

  On the other hand, Tables 3 and 4 show the results of experiments performed according to the method of using the ladle packing 18 of the present invention (Experiment Nos. 8 to 14 in Examples). Tables 3 and 4 are a continuation, and are divided into two for ease of explanation.

  As shown in Tables 3 and 4, in Experiment No. 8 of the example, the thickness of the ladle packing 18 before insertion is 8.3 mm and satisfies the rule of 7.5 mm to 8.5 mm. The surface temperature of the ladle packing 18 at the time of insertion is 35 ° C., and the regulation of 30 ° C. or more and 40 ° C. or less is satisfied. The tightening ratio of the ladle packing 18 is 0.23, which satisfies the rule of 0.24 or less. The heating temperature of the ladle packing 18 after compression is 466 ° C., which satisfies the requirement of 350 ° C. or higher.

From the above, the intrusion of the metal (molten steel 33) does not occur, the ladle packing 18 is not biased, and the ladle packing 18 is not broken, which is favorable.
As shown in Tables 3 and 4, in Experiment No. 12 of the example, the thickness of the ladle packing 18 before insertion is 7.7 mm and satisfies the rule of 7.5 mm to 8.5 mm. The surface temperature of the ladle packing 18 at the time of insertion is 31 degreeC, and satisfy | fills the regulations of 30 degreeC or more and 40 degrees C or less. The tightening ratio of the ladle packing 18 is 0.24 and satisfies the rule of 0.24 or less. The heating temperature of the ladle packing 18 after compression is 442 ° C, which satisfies the requirement of 350 ° C or higher.

From the above, the intrusion of the metal (molten steel 33) does not occur, the ladle packing 18 is not biased, and the ladle packing 18 is not broken, which is favorable.
As shown in Tables 3 and 4, in the experiment number 14 of the example, the thickness of the ladle packing 18 before insertion is 8.0 mm and satisfies the rule of 7.5 mm or more and 8.5 mm or less. The surface temperature of the ladle packing 18 at the time of insertion is 32 ° C., and the regulation of 30 ° C. or more and 40 ° C. or less is satisfied. The tightening ratio of the ladle packing 18 is 0.22, which satisfies the rule of 0.24 or less. The heating temperature of the ladle packing 18 after compression is 527 ° C, which satisfies the requirement of 350 ° C or higher.

From the above, the intrusion of the metal (molten steel 33) does not occur, the ladle packing 18 is not biased, and the ladle packing 18 is not broken, which is favorable.
That is, if the ladle packing 18 is attached between the slide valve 11 and the lower nozzle 16 according to the present invention, problems of the ladle packing 18 can be avoided as shown in the experiment numbers 8 to 14 of the examples shown in Tables 3 and 4. In addition, it is possible to prevent operational troubles such as intrusion of molten steel 33 and leakage of molten steel 33.

The embodiment disclosed this time should be considered as illustrative in all points and not restrictive.
In particular, in the embodiment disclosed this time, matters that are not explicitly disclosed, for example, operating conditions and operating conditions, various parameters, dimensions, weights, volumes, and the like of a component deviate from a range that a person skilled in the art normally performs. Instead, values that can be easily assumed by those skilled in the art are employed.

DESCRIPTION OF SYMBOLS 1 Ladle 2 Bottom part 3 Side wall part 4 Slag line part 5 Iron skin 6 Refractory 6a Permanent refractory 6b Work refractory 6c Alumina magnesia material castable (unshaped refractory)
6d Magnesia carbon brick (MgO-C brick)
7 Upper nozzle 8 Recess 9 Housing 10 Hydraulic cylinder 11 Slide valve 12 Upper plate 13 Convex part (upward)
14 Lower plate 15 Convex part (downward)
16 Lower nozzle 17 Recess 18 Ladle packing 19 Hot water outlet 20 Nozzle case 21 Protrusion (male screw / locking part)
22 Lower nozzle support member (cassette)
23 Groove (Female thread, locked part)
30 Converter 31 Continuous casting equipment 32 Tundish 33 Molten steel 34 Slag 35 Charcoal 36 Pipe

Claims (1)

In the bottom of the ladle that transports the molten steel discharged from the converter in the steelmaking process,
A cylindrical upper nozzle attached to the bottom of the ladle and for discharging the molten steel charged in the ladle;
A plate-like slide valve that is arranged below the upper nozzle and consists of two plates, an upper plate and a lower plate,
A molten steel discharge part is provided that is arranged below the slide valve and is configured by a cylindrical lower nozzle that can communicate with the upper nozzle via the slide valve,
The lower nozzle constituting the molten steel discharge part is covered with a nozzle case having a male screw formed on the outer peripheral wall so as to avoid a hole through which the molten steel passes during the discharge of the steel, and the bottom side of the ladle The lower nozzle is attached to the bottom of the ladle by screwing and tightening the male screw of the nozzle case with respect to the female screw provided in the
Regarding ingredients, Al ₂ O ₃ is 65 mass% or more and 70 mass% or less, SiO ₂ is 20 mass% or more and 25 mass% or less, C is 3 mass% or more and 5 mass% or less, and phenol resin used as a binder is 10 mass% or more In a method of using a ladle packing containing 20 mass% or less, inserted between the lower plate and the lower nozzle,
The thickness of the ladle packing before insertion is 7.5 mm or more and 8.5 mm or less,
The surface temperature of the ladle packing at the time of insertion is 30 ° C or more and 40 ° C or less,
Tighten the nozzle case to compress the ladle packing inserted between the lower plate and the lower nozzle so that the tightening ratio of the ladle packing is 0.24 or less,
A method of using a ladle packing, wherein the temperature of the ladle packing is heated to 350 ° C or higher after compression.