JPH0726056U - Heat retaining lid for molten metal container - Google Patents

Abstract

(57) [Abstract] [Purpose] In the heat insulation lid of the molten metal container, the material cost and the drying cost are low, and the sufficient heat insulation performance suppresses the temperature drop of the molten metal and the container temperature to the minimum, and the comparatively lightweight molten metal of the container The production efficiency is good in terms of storage capacity, and the total cost can be significantly reduced. [Structure] A refractory castable (alumina, etc.) 2 that is inexpensive and durable is provided on the operating surface side of the refractory material arranged in the outer frame 1, and heat insulation is good and lightweight on the back side. The ceramic fiber (alumina fiber, etc.) 3 is arranged to form a two-layer structure. The outer frame 1 releases moisture when dried,
A plurality of pores 7 are formed to allow air in and out of the ceramic fiber to flow in and out during operation. The anchor metal member 4 is composed of a Y-shaped metal fitting 8 for refractory castable and a flat metal fitting 9 for ceramic fiber to improve the fixing force of the refractory material.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a heat retaining lid for a molten metal container such as a ladle or a tundish that contains molten metal such as molten steel.

[0002]

[Prior art]

 In order to store molten metal such as molten steel (referred to as molten metal in this specification) in a ladle in a steelmaking process and convey it, and to store molten metal in a ladle that has become empty after the casting is finished. In the returning process, it is a known technique to cover the opening of the ladle with a heat retaining lid to suppress the temperature drop of the molten metal or the refractory lining the ladle (for example, Japanese Utility Model Laid-Open No. 57-97673, JP-A-5-97673). -5742 publication).

Regarding the structure of the heat-retaining lid, etc., Japanese Utility Model Laid-Open No. 1-177066 (conventional example 1), Japanese Utility Model Laid-Open No. 58-189072 (conventional example 2), Japanese Utility Model Laid-Open No. 57-86061 are used. (Prior art example 3).

Such a heat retaining lid is constructed by providing a refractory material inside an outer frame (iron skin), and as the refractory material, a refractory castable is used as shown in Conventional Example 1. It is common. In rare cases, a ceramic fiber molded body (a molded body formed by adding a binder to alumina fiber) as shown in Conventional Examples 2 and 3 is used.

[0005]

[Problems to be solved by the device]

 However, the conventional technique using the refractory material as described above has the following problems. In other words, the heat insulation lid using the conventional refractory castables such as the conventional example 1 has insufficient heat insulation performance or the weight of the lid is heavy (for example, a lid having a diameter of 4.5 m is used). (10 to 12 tons), there was a problem that the capacity of molten metal in the ladle was limited, the production efficiency was restricted, and the fuel cost for drying the refractory castables was high.

Further, with the heat retaining lid using the ceramic fiber molded body as in the conventional examples 2 and 3, although the problem of the refractory castable can be solved, on the other hand, the life of the ceramic fiber is compared. Due to its relatively short length and the high price of the high heat-resistant ceramic fiber itself, there was a problem that the material cost was high.

The present invention has been made to solve the above-mentioned problems, and its purpose is to reduce the melt temperature and container temperature with low material cost and drying cost, and with sufficient heat insulation performance. In addition, the heat retention lid of the molten metal container, which is significantly lighter than the conventional one in terms of overall cost, is achieved because it has a comparatively light weight and a good result in terms of the amount of molten metal stored in the container. To provide.

[0008]

[Means for Solving the Problems]

 This invention relates to a heat-retaining lid for a molten metal container in which a refractory material is provided in an outer frame, the refractory castable having the structure of the refractory material disposed on the operating surface side, and the rear side of the refractory castable. It has a two-layer structure with the ceramic fiber arranged in the above, and a plurality of pores are formed in the outer frame located on the back surface of this ceramic fiber.

Refractory castable is an irregular shaped refractory that mixes hydraulic cement with refractory material and casts it into a mold to form it. High refractory material such as high alumina refractory material with high fire resistance and high mechanical strength is used. To use. Ceramic fibers are high-temperature fiber-based heat insulating materials, such as alumina fibers, silica fibers, and zirconia fibers. It is preferable that the pores have a diameter of 5 mm or less for the reason described later.

The anchor metal fixture for fixing the refractory material to the outer frame is composed of a Y-shaped metal fitting whose tip bifurcated portion engages with the refractory castable, and a flat metal fitting for locking the ceramic fiber.

The refractory castable may be made of a composite material containing hydraulic alumina as a main component and ceramic fibers as a reinforcing material to reduce weight and increase mechanical strength.

[0012]

[Action]

 In the above-mentioned structure, ceramic fibers are attached to the outer frame having pores and to which the anchor metal fittings are attached, and then refractory castables are filled and dried to manufacture a heat retaining lid. Here, the pores formed in the outer frame work as follows. The first is to accelerate the release of evaporated water when the refractory castable is dried, and the second is the amount of abrupt expansion of the air held by the ceramic fiber when the heat-retaining lid is placed on the hot metal container. It is a function to prevent the deformation of refractory castables or the outer frame by absorbing the shrinkage of air when it is removed from the molten metal container.

The reason for limiting the diameter of the pores to 5 mm or less is that if the diameter is larger than 5 mm, convection occurs between the air held by the ceramic fibers and the atmosphere through the pores, and the heat insulation performance of the ceramic fibers is reduced. This is because it decreases.

In the anchor hardware, the Y-shaped metal fitting has a function of mainly fixing the castable refractory material, and the flat-shaped metal fitting has a function of fixing the ceramic fiber, so that the fixing force of the refractory material is increased as compared with the conventional Y-shaped metal fitting alone. In addition, it has the effect of increasing the durability against mechanical vibration and extending the life of refractory materials.

Since the refractory castable layer is located on the working surface side and the ceramic fiber layer is located on the back surface of the refractory castable layer in the manufactured heat retaining lid, heat resistance is higher than that of the conventional ceramic fiber single layer. Inexpensive ceramic fibers, which are relatively inferior in performance, can be used, and the amount thereof can be small. Therefore, the material cost for construction is relatively low.

[0016] Furthermore, the operating surface is a castable refractory material with durability, and as described above, the outer frame is provided with pores, and the anchor metal fittings in which Y-shaped fittings and flat-shaped fittings are combined are used. Therefore, the life of the refractory material can be made relatively long.

The refractory castable portion that needs to be dried is relatively thin, and as described above, since the evaporated water during drying is released from both the operating surface and the pores, it is a relatively short time and a small amount. Can be dried with fuel.

The presence of the ceramic fiber layer improves the heat insulating property and has the effect of suppressing the temperature drop of the molten metal as compared with the case of the refractory castable single layer, and since the weight can be reduced, more molten metal can be produced. Can be stored in a ladle, improving production efficiency.

[0019]

【Example】

 Hereinafter, the present invention will be described in detail with reference to an illustrated embodiment. This is an example applied to a ladle used in the steelmaking process from the converter for steelmaking to continuous casting. Fig. 1 is an overall sectional view of the heat retaining lid of the present invention, Fig. 2 is its top plan view, 3 is an enlarged sectional view of FIG.

As shown in FIGS. 1 to 3, the heat-retaining lid of the present invention includes a container-shaped outer frame (iron skin) 1 in which a side plate 1b is integrally erected downward around a disk 1a. , A refractory castable 2 containing Al ₂ O ₃ · Si O ₂ as a main component, a ceramic fiber 3 made of Al ₂ O ₃ fibers, and a plurality of anchor metal pieces 4 planted in the outer frame 1. The refractory castables 2 are arranged on the lower working surface side in the outer frame 1, and the ceramic fibers 3 are arranged on the upper rear surface side in the outer frame 1 to form a two-layer structure.

In the outer frame 1, a reinforcing member 5 such as an H-shaped steel is arranged vertically and horizontally on the upper surface of the disc 1a to reinforce, and the suspension ring 6 is fixed to the reinforcing member 5 at the center of the disc. Further, a large number of pores 7 having a diameter of 5 mm or less are formed in the disc 1a at predetermined intervals.

From the viewpoint of preventing blockage due to dust or the like, a pipe 10 having a downward end may be attached to the pore 7, as shown in FIG. In this case, the inner diameter of the tube 10 is about 5 mm or less, and the centers of the tube 10 and the hole 7 are attached so that the hole 7 communicates with the outside.

The anchor metal piece 4 is composed of a Y-shaped metal fitting 8 whose base is fixed to the lower surface of the disc 1 a by welding or the like, and a flat metal fitting 9 that fits into the linear base of the Y-shaped metal fitting 8. The lower surface of the ceramic fiber 3 is locked by the metal fitting 9, and the lower end bifurcated portion of the Y-shaped metal fitting 8 is engaged and fixedly held in the refractory castable 2.

In the above-mentioned structure, the outer frame 1 is laid with a predetermined thickness without forming the alumina ceramic fibers 3 in the outer frame 1 with the opening facing upward, and is locked by the flat metal fitting 9. . Then, the hydraulic alumina of the refractory castable 2 is poured over this, ceramic fibers are mixed if necessary, and curing and drying are performed.

At the time of drying, the pores 7 of the outer frame 1 promote the release of evaporated water.

Next, a specific example in which the heat-retaining lid having the above-mentioned configuration was used on a trial basis in a steelmaking process (using 9 heat-retaining lids) with a monthly production of 200,000 tons was compared with the conventional technique. Along with this, I will explain the annual merit per lid. Table 1 shows the configuration of the lid used in the test.

[0027]

[Table 1]

The test results are shown in Table 2.

(1) The cost of the refractory material was about twice that of the refractory castable ceramic fiber, and could be significantly reduced as compared with the case of the single ceramic fiber layer. If the refractory castable layer is 70% and the ceramic fiber layer is 30% and the same alumina fiber as in the prior art A is used, the amount is 1.3 times that of the refractory castable single layer.

(2) The service life is that the operating surface is a refractory castable 2, the anchor metal 4 combining the Y type and the flat type increases durability against mechanical vibration, and the pores of the outer frame 1 Since the refractory castable 2 or the outer frame 1 is prevented from being deformed by the inflow and outflow of air by 7, the same as the case of the refractory castable single layer.

(3) The material cost / lifetime can be greatly reduced as compared with the case of the ceramic fiber single layer due to the above (1) and (2).

(4) As for the drying cost, in the case of the refractory castable single layer, heating per fuel (COG: coke oven gas) of 200 Nm ³ / hr for 30 hours was required for the refractory castable single layer, but in the present invention, the COG of 100 Nm is required. It could be dried by heating at ³ / hr for 30 hours, and it could be reduced to half of the case of refractory castable single layer.

(5) The molten metal temperature drop suppression is 5 ° C for the refractory castable single layer and 7.5 ° C for the ceramic fiber single layer, whereas it is 6.5 ° C in the present invention. Met. The suppression of molten metal temperature drop has the effect of reducing refractory costs and energy costs in the steelmaking process. That is, if the ladle has poor heat retention, unless the tapping temperature is raised, the molten metal temperature will drop before pouring, and if the melting temperature falls below the melting point, casting may not be possible. It is necessary to raise the temperature of the molten metal. When the temperature of the molten metal rises, extra energy is required, and the melting rate of the refractory lining the ladle and the frequency of replacement increase, but if the heat retention is improved, the temperature of the molten metal can be lowered by that amount, and the energy can be reduced. The cost can be reduced, and the melting loss of the refractory and the replacement frequency can be suppressed.

(6) If the capacity of the crane associated with the movement of the ladle is constant, the weight of the ladle with a lid itself can be reduced and the weight of the molten metal itself can be increased by that amount in order to improve the production efficiency. This is because it is possible to increase the amount of molten metal by 6.5 tons per charge in the case of the ceramic fiber single layer, and in the present invention by 3 tons, compared with the case of the refractory castable single layer. This improvement in production efficiency has the effect of reducing refractory costs, energy costs, and consumables costs in the steelmaking process.

(7) Combining the above items, the ceramic fiber single layer is superior to the present invention in terms of drying cost, suppression of melt temperature drop, and improvement of production efficiency, but the material cost is high. Due to its short life, a single refractory castable layer can only benefit a few hundreds of thousands of yen per lid per year, but the present invention is superior to the conventional technologies A and B in all respects. , You can get the benefit of millions of yen.

[0036]

[Table 2]

It is needless to say that the present invention can be applied to a molten metal container such as a continuously cast tundish other than a ladle, and a molten metal other than molten steel.

[0038]

[Effect of device]

 As mentioned above, the heat-retaining lid according to the present invention has the structure of the refractory material, in which the inexpensive and durable refractory castables are arranged on the operating surface side, and the rear side has good heat insulation and lightweight ceramic fiber. To form a two-layer structure.The outer frame has a plurality of pores that release water during drying and let air in and out of the ceramic fiber flow in and out during operation. It consists of Y-shaped metal fittings for castables and flat metal fittings for ceramic fibers to improve the fixing force of the refractory material, so the material cost and drying cost are low, and sufficient heat insulation performance is provided. The temperature drop of the molten metal and the temperature of the container can be suppressed to a minimum, the production efficiency can be improved in terms of the amount of molten metal stored in the container, which is relatively lightweight, and the heat insulation lid is superior in all respects. Can be obtained. As a result, the overall cost can be reduced significantly compared to the past, and the economic effect is great.

[Brief description of drawings]

FIG. 1 is an overall sectional view showing a heat retaining lid of a molten metal container according to the present invention.

FIG. 2 is a top plan view of the heat retaining lid of FIG.

3 is a partially enlarged cross-sectional view of the heat retaining cover of FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Outer frame 1a ... Disc 1b ... Side plate 2 ... Refractory castable 3 ... Ceramic fiber 4 ... Anchor metal 5 ... Reinforcing member 6 ... Suspension ring 7 ... Pore 8 ... Y type metal fitting 9 ... Flat metal fitting 10 ... Pipe

Claims (3)

[Scope of utility model registration request] 1. A heat-retaining lid for a molten metal container, wherein a refractory material is provided in an outer frame, wherein the refractory material comprises a refractory castable disposed on an operating surface side and a rear side of the refractory castable. A heat-retaining lid for a molten metal container, which has a two-layer structure with the disposed ceramic fibers, and a plurality of pores are formed in an outer frame located on the back surface of the ceramic fibers. 2. The heat-retaining lid according to claim 1, wherein an anchor metal for fixing the refractory material to the outer frame is engaged with a Y-shaped metal fitting having a bifurcated tip engaging with the refractory castable, and a ceramic fiber. A heat-retaining lid for a molten metal container, which is composed of a flat metal fitting for stopping. 3. The heat-retaining lid according to claim 1, wherein the refractory castable comprises hydraulic alumina as a main component, and ceramic fibers are mixed as a reinforcing material. Heat retention lid.