JP5494898B1 - Lining structure of molten metal container - Google Patents

Lining structure of molten metal container Download PDF

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JP5494898B1
JP5494898B1 JP2013549446A JP2013549446A JP5494898B1 JP 5494898 B1 JP5494898 B1 JP 5494898B1 JP 2013549446 A JP2013549446 A JP 2013549446A JP 2013549446 A JP2013549446 A JP 2013549446A JP 5494898 B1 JP5494898 B1 JP 5494898B1
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heat insulating
gap
insulating material
molten metal
refractory
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JPWO2013180219A1 (en
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明彦 井上
禎公 清田
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JFE Steel Corp
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JFE Steel Corp
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B22CASTING; POWDER METALLURGY
    • B22DCASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
    • B22D41/00Casting melt-holding vessels, e.g. ladles, tundishes, cups or the like
    • B22D41/02Linings
    • CCHEMISTRY; METALLURGY
    • C21METALLURGY OF IRON
    • C21CPROCESSING OF PIG-IRON, e.g. REFINING, MANUFACTURE OF WROUGHT-IRON OR STEEL; TREATMENT IN MOLTEN STATE OF FERROUS ALLOYS
    • C21C7/00Treating molten ferrous alloys, e.g. steel, not covered by groups C21C1/00 - C21C5/00
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27DDETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
    • F27D1/00Casings; Linings; Walls; Roofs
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27DDETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
    • F27D1/00Casings; Linings; Walls; Roofs
    • F27D1/0003Linings or walls
    • F27D1/0006Linings or walls formed from bricks or layers with a particular composition or specific characteristics
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27DDETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
    • F27D3/00Charging; Discharging; Manipulation of charge
    • F27D3/12Travelling or movable supports or containers for the charge
    • F27D3/123Furnace cars
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27DDETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
    • F27D3/00Charging; Discharging; Manipulation of charge
    • F27D3/14Charging or discharging liquid or molten material
    • CCHEMISTRY; METALLURGY
    • C21METALLURGY OF IRON
    • C21CPROCESSING OF PIG-IRON, e.g. REFINING, MANUFACTURE OF WROUGHT-IRON OR STEEL; TREATMENT IN MOLTEN STATE OF FERROUS ALLOYS
    • C21C5/00Manufacture of carbon-steel, e.g. plain mild steel, medium carbon steel or cast steel or stainless steel
    • C21C5/28Manufacture of steel in the converter
    • C21C5/42Constructional features of converters
    • C21C5/44Refractory linings
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02WCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO WASTEWATER TREATMENT OR WASTE MANAGEMENT
    • Y02W30/00Technologies for solid waste management
    • Y02W30/50Reuse, recycling or recovery technologies
    • Y02W30/91Use of waste materials as fillers for mortars or concrete

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Materials Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
  • Furnace Housings, Linings, Walls, And Ceilings (AREA)
  • Casting Support Devices, Ladles, And Melt Control Thereby (AREA)
  • Treatment Of Steel In Its Molten State (AREA)

Abstract

溶融金属を収容する溶融金属容器のライニング構造であって、上記溶融金属容器の最外層を構成し、外側面と内側面とを貫通する複数個の貫通孔を有する鉄皮と、上記鉄皮の内側に設けられる、1層または2層の永久耐火物層と、上記永久耐火物層の内側に設けられ、上記溶融金属と接する稼働面を形成し、少なくとも一部が不定形耐火物で構成されるワーク耐火物層と、シート状の多角形部材であって、上記鉄皮と上記永久耐火物層との間、または、2層の上記永久耐火物層どうしの間に施工され、上記鉄皮の内側面に沿って隣接配置される複数枚の断熱材と、を備え、1つの上記断熱材と、当該断熱材に隣接配置される他の上記断熱材のうちの少なくとも1つとの間に、間隙が形成され、上記間隙が、上記貫通孔上に位置付けられ、かつ、上記断熱材の厚さ以上の幅を有する、溶融金属容器のライニング構造。   A lining structure of a molten metal container for containing a molten metal, comprising an outermost layer of the molten metal container and having a plurality of through holes penetrating an outer surface and an inner surface, One or two layers of permanent refractory layers provided on the inside, and provided on the inner side of the permanent refractory layer, forming an operating surface in contact with the molten metal, at least partly composed of an irregular refractory. A workpiece refractory layer and a sheet-like polygonal member, which is constructed between the iron skin and the permanent refractory layer, or between the two permanent refractory layers, A plurality of heat insulating materials arranged adjacent to each other along the inner surface, and between one of the heat insulating materials and at least one of the other heat insulating materials arranged adjacent to the heat insulating material, A gap is formed, the gap is positioned on the through hole, and Having a thickness of more than the width of the heat insulating material, the lining structure of the molten metal container.

Description

本発明は、溶融金属容器のライニング構造に関する。   The present invention relates to a lining structure for a molten metal container.

溶銑や溶鋼等の溶融金属を収容する溶融金属容器(以下、単に「容器」ともいう。)のライニング構造は、最外層である鉄皮が耐火物を支持する構造を有する。
溶融金属容器に使用される耐火物としては、定形耐火物と不定形耐火物とがある。とりわけ、不定形耐火物は、キャスタブルとも呼ばれ、その施工の容易さから、溶融金属に接するワーク耐火物層を構成する耐火物として、多く使用されている。
不定形耐火物は、一般に、アルミナ等の高融点物質の粉や粒の混合物に、水を加えて流動化させて容器に流し込み、内張り形状とされる。
The lining structure of a molten metal container (hereinafter also simply referred to as “container”) that contains molten metal such as hot metal or molten steel has a structure in which an iron skin as an outermost layer supports a refractory.
Refractories used for molten metal containers include regular refractories and irregular refractories. In particular, the amorphous refractory is also called a castable and is often used as a refractory constituting a work refractory layer in contact with molten metal because of its ease of construction.
The amorphous refractory is generally formed into a lining shape by adding water to a mixture of powder and particles of a high melting point material such as alumina and fluidizing the mixture into a container.

ところで、鉄などの金属は、その融点が数百〜千数百℃と高いものが多いため、溶融金属容器には、耐火性とともに断熱性が求められる。
従来、溶融金属容器に断熱性を付与する方法としては、ワーク耐火物層の背面側に断熱材を挿入する方法が提案されており、例えば、特許文献1には、シリカ微粒子を主材とした微孔性成形体である断熱材が開示されている。
By the way, many metals such as iron have a high melting point of several hundred to several hundreds of degrees Celsius, so that molten metal containers are required to have heat resistance as well as fire resistance.
Conventionally, as a method of imparting heat insulation to a molten metal container, a method of inserting a heat insulating material on the back side of the workpiece refractory layer has been proposed. For example, Patent Document 1 uses silica fine particles as a main material. A heat insulating material which is a microporous molded body is disclosed.

特開2008−249317号公報JP 2008-249317 A

溶融金属容器に溶鋼等が装入された場合、ワーク耐火物層を構成する不定形耐火物に水分が残存していると、その内部で水蒸気圧が例えば200℃で10気圧以上に上昇し、不定形耐火物が爆裂して破損するおそれがある。
そのため、溶融金属容器が使用されるにあたっては、不定形耐火物に対して、事前に加熱による乾燥(以下、「事前乾燥」ともいう。)が施される。事前乾燥は、水蒸気圧による不定形耐火物の破損を防ぐために、比較的低温で長時間をかけて行なわれる。
When molten steel or the like is charged in the molten metal container, if moisture remains in the amorphous refractory constituting the workpiece refractory layer, the water vapor pressure rises to, for example, 10 atm or more at 200 ° C., The amorphous refractory may explode and be damaged.
Therefore, when the molten metal container is used, the amorphous refractory is previously dried by heating (hereinafter also referred to as “pre-drying”). The pre-drying is performed over a long period of time at a relatively low temperature in order to prevent the irregular refractory from being damaged by water vapor pressure.

事前乾燥は、バーナ等を用いて容器の内側から行なわれるため、不定形耐火物の外面側の部位では、事前乾燥の序盤は温度が100℃以下と低く、不定形耐火物の内部から出る蒸気の一部が凝縮して液体の水となる。その後、次第に、不定形耐火物の外面側の部位も100℃以上となって、水分が蒸気となる。
容器の最外層である鉄皮には貫通孔が形成されており、事前乾燥によって不定形耐火物から出る蒸気は、この貫通孔から外部に排気される。
Since pre-drying is performed from the inside of the container using a burner or the like, the temperature at the beginning of pre-drying is as low as 100 ° C. or less at the outer surface side of the irregular refractory, and steam is emitted from the inside of the irregular refractory. Part of the water condenses into liquid water. Then, gradually, the site | part of the outer surface side of an amorphous refractory also becomes 100 degreeC or more, and a water | moisture content turns into a vapor | steam.
A through-hole is formed in the iron skin, which is the outermost layer of the container, and the vapor emitted from the amorphous refractory by pre-drying is exhausted to the outside through this through-hole.

しかしながら、ワーク耐火物層の背面側に断熱材が挿入されている場合、貫通孔からの排気が妨害される。しかも、不定形耐火物の内面側は事前乾燥によって既に固化し、一部焼結しているため、貫通孔から排気されなかった蒸気は、内面側からも排気されにくく、内部に留まる。
そのため、不定形耐火物の内部に水分が残存しているにもかかわらず、事前乾燥が終了したと誤認して、容器に溶融金属を装入してしまい、不定形耐火物の爆裂破損を招くおそれがある。
However, when a heat insulating material is inserted on the back side of the workpiece refractory layer, exhaust from the through hole is obstructed. Moreover, since the inner surface side of the amorphous refractory is already solidified and partially sintered by pre-drying, the steam that has not been exhausted from the through-hole is not easily exhausted from the inner surface side, and remains inside.
Therefore, even though moisture remains inside the amorphous refractory, it is misunderstood that the pre-drying has been completed, and the molten metal is charged into the container, resulting in explosion breakage of the amorphous refractory. There is a fear.

本発明は、以上の点を鑑みてなされたものであり、断熱材を施工した溶融金属容器のライニング構造において、不定形耐火物の事前乾燥中の通気性を良好にすることを目的とする。   This invention is made | formed in view of the above point, and aims at making air permeability during the pre-drying of an amorphous refractory in the lining structure of the molten metal container which constructed the heat insulating material.

本発明者らは、上記目的を達成するために鋭意検討を行なった。その結果、シート状の多角形部材である断熱材を特定の配置とすることで、不定形耐火物の事前乾燥中において、蒸気の通気性を良好にできることを見出し、本発明を完成させた。
すなわち、本発明は、以下の(1)〜(3)を提供する。
The present inventors have intensively studied to achieve the above object. As a result, it has been found that by making the heat insulating material, which is a sheet-like polygonal member, a specific arrangement, the vapor permeability can be improved during the preliminary drying of the irregular refractory, and the present invention has been completed.
That is, the present invention provides the following (1) to (3).

(1)溶融金属を収容する溶融金属容器のライニング構造であって、上記溶融金属容器の最外層を構成し、外側面と内側面とを貫通する複数個の貫通孔を有する鉄皮と、上記鉄皮の内側に設けられる、1層または2層の永久耐火物層と、上記永久耐火物層の内側に設けられ、上記溶融金属と接する稼働面を形成し、少なくとも一部が不定形耐火物で構成されるワーク耐火物層と、シート状の多角形部材であって、上記鉄皮と上記永久耐火物層との間、または、2層の上記永久耐火物層どうしの間に施工され、上記鉄皮の内側面に沿って隣接配置される複数枚の断熱材と、を備え、1つの上記断熱材と、この断熱材に隣接配置される他の上記断熱材のうちの少なくとも1つとの間に、間隙が形成され、上記間隙が、上記貫通孔上に位置付けられ、かつ、上記断熱材の厚さ以上の幅を有する、溶融金属容器のライニング構造。   (1) A lining structure of a molten metal container for containing a molten metal, which constitutes the outermost layer of the molten metal container, and has an iron skin having a plurality of through holes penetrating an outer surface and an inner surface; One or two permanent refractory layers provided on the inner side of the iron skin, and provided on the inner side of the permanent refractory layer, forming an operating surface in contact with the molten metal, at least a part of which is an amorphous refractory A workpiece refractory layer composed of a sheet-like polygonal member, which is constructed between the iron skin and the permanent refractory layer, or between the two layers of the permanent refractory layer, A plurality of heat insulating materials arranged adjacent to each other along the inner surface of the iron skin, and one heat insulating material and at least one of the other heat insulating materials arranged adjacent to the heat insulating material. A gap is formed between them, and the gap is positioned on the through hole. And has a thickness or width of the heat insulating material, the lining structure of the molten metal container.

(2)上記間隙の幅が、上記鉄皮の厚さ以下である、上記(1)に記載の溶融金属容器のライニング構造。   (2) The lining structure of the molten metal container according to (1), wherein a width of the gap is equal to or less than a thickness of the iron skin.

(3)上記断熱材が、防水性の被覆材に収納されている、上記(1)または(2)に記載の溶融金属容器のライニング構造。   (3) The molten metal container lining structure according to (1) or (2), wherein the heat insulating material is housed in a waterproof covering material.

本発明によれば、断熱材を施工した溶融金属容器のライニング構造において、不定形耐火物の事前乾燥中の通気性を良好にすることができる。   ADVANTAGE OF THE INVENTION According to this invention, in the lining structure of the molten metal container which applied the heat insulating material, the air permeability during the prior drying of an amorphous refractory can be made favorable.

溶鋼鍋1を一部を切り欠いて示す側面図である。It is a side view which cuts and shows the molten steel pan 1 partially. 鉄皮2の内側面形状に沿って配置された複数の断熱材5を、溶鋼鍋1の内側から見た模式図である。It is the schematic diagram which looked at the several heat insulating material 5 arrange | positioned along the inner surface shape of the iron shell 2 from the inner side of the molten steel pan 1. FIG. 断熱材5の厚さに対する間隙Gの幅の比率と、間隙Gの鉄皮2側の温度との関係を示すグラフである。6 is a graph showing the relationship between the ratio of the width of the gap G to the thickness of the heat insulating material 5 and the temperature of the gap G on the iron skin 2 side. (a)は、鉄皮2の厚さを30mm、断熱材5の間隙Gの幅を40〜50mmにした溶鋼鍋1を示す赤外線熱画像であり、(b)は、(a)の赤外線熱画像中のラインAおよびBの温度分布を示すグラフである。(A) is the infrared thermal image which shows the molten steel pan 1 which made the thickness of the iron shell 2 30 mm, and the width | variety G of the heat insulating material 5 was 40-50 mm, (b) is the infrared thermal image of (a). It is a graph which shows the temperature distribution of the lines A and B in an image. 鉄皮2の厚さに対する間隙Gの幅の比率と、鉄皮間隙部2aの輻射放熱量との関係を示すグラフである。It is a graph which shows the relationship between the ratio of the width | variety of the gap | interval G with respect to the thickness of the iron skin 2, and the radiation heat dissipation amount of the iron skin gap | interval part 2a. (a)は、鉄皮2の厚さを30mm、断熱材5の間隙Gの幅を20〜30mmにした溶鋼鍋1を示す赤外線熱画像であり、(b)は、(a)の赤外線熱画像中のラインAおよびBの温度分布を示すグラフである。(A) is the infrared thermal image which shows the molten steel pan 1 which made the thickness of the iron shell 2 30 mm, and the width | variety G of the heat insulating material 5 was 20-30 mm, (b) is the infrared thermal image of (a). It is a graph which shows the temperature distribution of the lines A and B in an image.

以下、本発明の実施の一形態について説明する。以下に説明する実施形態は、溶融金属としての溶鋼61を収容する溶鋼鍋1への適用例である。   Hereinafter, an embodiment of the present invention will be described. Embodiment described below is an application example to the molten steel pan 1 which accommodates the molten steel 61 as a molten metal.

図1は、溶鋼鍋1を一部を切り欠いて示す側面図である。図1に示す溶鋼鍋1は、転炉にて溶銑から転換された溶鋼61を収容し保持している。溶鋼61の湯面上にはスラグ(図示せず)が浮いている。溶鋼鍋1では、溶鋼61から不純物を除いたり添加元素を添加したりする二次精錬の処理が行なわれる。二次精錬が終わった溶鋼61は、溶鋼鍋1により輸送されて、連続鋳造工程に供される。   FIG. 1 is a side view showing a molten steel pan 1 with a part cut away. The molten steel ladle 1 shown in FIG. 1 accommodates and holds a molten steel 61 converted from molten iron in a converter. A slag (not shown) floats on the surface of the molten steel 61. In the molten steel pan 1, a secondary refining process is performed in which impurities are removed from the molten steel 61 and additional elements are added. The molten steel 61 that has undergone secondary refining is transported by the molten steel pan 1 and subjected to a continuous casting process.

溶鋼鍋1のライニング構造は、基本的には、外側から順に、鉄皮2、永久耐火物層3およびワーク耐火物層4を有する。さらに、溶鋼鍋1の側面部分等には、断熱機能を発揮する断熱材5が施工される。
以下では、まず、図1に基づいて、永久耐火物層3およびワーク耐火物層4について説明する。
The lining structure of the molten steel pan 1 basically has an iron skin 2, a permanent refractory layer 3, and a workpiece refractory layer 4 in order from the outside. Furthermore, the heat insulating material 5 which exhibits a heat insulation function is constructed in the side surface part etc. of the molten steel pan 1.
Below, based on FIG. 1, the permanent refractory layer 3 and the workpiece | work refractory layer 4 are demonstrated first.

永久耐火物層3は、鉄皮2の内側に設けられている。永久耐火物層3は、後述するワーク耐火物層4(の一部)が損傷し抜け落ちたときでも溶鋼61が漏洩しないよう、安全を確保するために施工される煉瓦層である。永久耐火物層3は、1層でもよく、図1に示すように2層設けられていてもよい。
永久耐火物層3を構成する耐火物(「永久耐火物」ともいう。)31としては、例えば、ろう石煉瓦などの定形耐火物(成形煉瓦)が用いられる。耐火物31は、図1に示すように、モルタル32を目地材として用いて、煉瓦積み施工される。
The permanent refractory layer 3 is provided inside the iron skin 2. The permanent refractory layer 3 is a brick layer that is constructed in order to ensure safety so that the molten steel 61 does not leak even when (a part of) the workpiece refractory layer 4 described later is damaged and falls off. The permanent refractory layer 3 may be a single layer or two layers as shown in FIG.
As the refractory material (also referred to as “permanent refractory material”) 31 constituting the permanent refractory layer 3, for example, a fixed refractory material (formed brick) such as a wax brick is used. As shown in FIG. 1, the refractory 31 is constructed by brick using a mortar 32 as a joint material.

永久耐火物層3の厚さとしては、ワーク耐火物が何らかの原因で剥落しても直ちには溶鋼61を漏出させないという理由から、40mm以上が好ましく、目地を通しての溶鋼61の流出を防ぐという理由から、2層の施工がより好ましい。   The thickness of the permanent refractory layer 3 is preferably 40 mm or more from the reason that the molten steel 61 does not leak immediately even if the workpiece refractory peels off for some reason, and for the reason of preventing the molten steel 61 from flowing out through the joint. Two-layer construction is more preferable.

ワーク耐火物層4は、永久耐火物層3の内側に設けられている。ワーク耐火物層4は、溶鋼61と接触する稼働面を形成する層である。
図1では、ワーク耐火物層4を構成する耐火物(「ワーク耐火物」ともいう。)41としては、不定形耐火物を用いた例を示す。不定形耐火物41を用いる場合、アルミナ(Al)やマグネシア(MgO)等の高融点物質の粉や粒の混合物に水を加えて流動化させたものを、永久耐火物層3と型枠(図示せず)との間に流し込み、内張り形状とする。
The workpiece refractory layer 4 is provided inside the permanent refractory layer 3. The workpiece refractory layer 4 is a layer that forms an operating surface that contacts the molten steel 61.
FIG. 1 shows an example in which an amorphous refractory is used as the refractory (also referred to as “work refractory”) 41 constituting the work refractory layer 4. When the amorphous refractory 41 is used, a mixture of powder and particles of a high melting point material such as alumina (Al 2 O 3 ) or magnesia (MgO) added to fluidize the permanent refractory layer 3. Pour between molds (not shown) to form a lining.

ところで、溶鋼鍋1に溶鋼61が装入された際に不定形耐火物41に水分が残存していると、不定形耐火物41の内部で水蒸気圧が例えば200℃で10気圧以上に上昇し、不定形耐火物41が爆裂して破損するおそれがある。そこで、このような破損を防止するため、比較的低温で長時間をかけて、事前乾燥が行なわれる。
事前乾燥は、一般的に、バーナ等を用いて、溶鋼鍋1の内側(すなわち、ワーク耐火物層4の稼働面側)から行なわれる。そのため、不定形耐火物41の外面側(すなわち、ワーク耐火物層4の鉄皮2側)の部位は、事前乾燥の序盤では温度が100℃以下と低く、不定形耐火物41の内部から出る蒸気の一部が、凝縮して液体の水となる。その後、事前乾燥の中盤〜終盤では、不定形耐火物41の外面側の部位も100℃以上となり、水分が蒸気となって、鉄皮2に形成された後述する貫通孔Hから排気される。
By the way, if moisture remains in the irregular refractory 41 when the molten steel 61 is charged into the molten steel pan 1, the water vapor pressure inside the irregular refractory 41 rises to 10 atm or more at 200 ° C., for example. The unshaped refractory 41 may explode and be damaged. Therefore, in order to prevent such breakage, preliminary drying is performed at a relatively low temperature for a long time.
The pre-drying is generally performed from the inside of the molten steel pan 1 (that is, the working surface side of the workpiece refractory layer 4) using a burner or the like. Therefore, the temperature of the part on the outer surface side of the irregular refractory 41 (that is, the iron skin 2 side of the workpiece refractory layer 4) is as low as 100 ° C. or less in the early stage of pre-drying, and comes out of the irregular refractory 41. A part of the vapor condenses into liquid water. Thereafter, in the middle stage to the final stage of pre-drying, the portion on the outer surface side of the irregular refractory 41 is also 100 ° C. or higher, and the moisture becomes steam and is exhausted from a through hole H described later formed in the iron skin 2.

ワーク耐火物層4(不定形耐火物41)の厚さとしては、修理頻度を下げ稼働率を上げるためには厚いほうが有利である。しかし、使用初期と末期との厚さの差が大きく内容積変動が大きいと浴面高さや保持可能量が変動し操業性が低下したり、容器重量が増し設備規模が大きくなったりする。このような理由から、ワーク耐火物層4(不定形耐火物41)の厚さは、100〜250mmが好ましく、敷部(底面部)との境界付近は溶鋼流や残存スラグに晒されるため厚く、それ以外の部位は薄く、部位毎に厚さを変えることがより好ましい。   As the thickness of the workpiece refractory layer 4 (unshaped refractory 41), it is advantageous to increase the thickness in order to reduce the repair frequency and increase the operation rate. However, if the difference in thickness between the initial stage of use and the end stage is large and the internal volume fluctuation is large, the bath surface height and the holdable amount fluctuate and the operability decreases, and the container weight increases and the equipment scale increases. For this reason, the thickness of the workpiece refractory layer 4 (unshaped refractory 41) is preferably 100 to 250 mm, and the vicinity of the boundary with the laying portion (bottom surface portion) is exposed to a molten steel flow or residual slag, so that it is thick. The other parts are thin, and it is more preferable to change the thickness for each part.

次に、鉄皮2について説明する。鉄皮2は、溶鋼鍋1の最外層として耐火物(耐火物31、耐火物41)を支持する鋼鉄製の構造物である。
鉄皮2の厚さ(図1中、T2で示す長さ)としては、下限は強度計算から定められ、厚いほど変形し難く長寿命であるが、費用と重量制約とから30〜90mmを採用する例が多い。
Next, the iron skin 2 will be described. The iron skin 2 is a steel structure that supports a refractory (refractory 31, refractory 41) as the outermost layer of the molten steel pan 1.
As for the thickness of the iron skin 2 (the length indicated by T2 in FIG. 1), the lower limit is determined from the strength calculation. The thicker the film is, the harder it is to be deformed and the longer the life is. There are many examples to do.

鉄皮2には、鉄皮2の外側面と内側面とを貫通する複数個の貫通孔Hが形成されている。貫通孔Hは、上述した事前乾燥によって不定形耐火物41から出る蒸気を通過させる。
貫通孔Hの孔径は、特に限定されないが、耐火物片などによる詰まり防止の観点から6mm以上であるのが好ましい。一方、詰まりさえ防げれば通気性は十分確保できるので30mm以下とすることが多い。
A plurality of through holes H penetrating the outer surface and the inner surface of the iron skin 2 are formed in the iron skin 2. The through-hole H allows the vapor emitted from the amorphous refractory 41 to pass through the above-described preliminary drying.
Although the hole diameter of the through-hole H is not specifically limited, It is preferable that it is 6 mm or more from a viewpoint of prevention of clogging with a refractory piece. On the other hand, as long as it can prevent clogging, sufficient air permeability can be ensured, so it is often 30 mm or less.

次に、断熱材5について説明する。断熱材5は、少なくとも、溶鋼鍋1の側面部に施工されるが、敷部(底面部)にも施工されてもよい。
断熱材5の施工位置としては、永久耐火物層3が2層設けられる場合は、この2層の間でもよい。しかし、断熱材5の温度を低く運用でき、長期間(例えば2年以上)断熱性能を発揮できるという理由から、図1に示すように、鉄皮2と永久耐火物層3との間が好ましい。
以下では、鉄皮2と永久耐火物層3との間に断熱材5が施工される場合を例に説明するが、本発明はこれに限定されるものではない。
Next, the heat insulating material 5 will be described. Although the heat insulating material 5 is constructed at least on the side surface portion of the molten steel pan 1, it may also be constructed on the laying portion (bottom surface portion).
As a construction position of the heat insulating material 5, when two permanent refractory layers 3 are provided, it may be between these two layers. However, for the reason that the temperature of the heat insulating material 5 can be operated low and the heat insulating performance can be exhibited for a long time (for example, 2 years or more), the space between the iron skin 2 and the permanent refractory layer 3 is preferable as shown in FIG. .
Below, although the case where the heat insulating material 5 is constructed between the iron skin 2 and the permanent refractory layer 3 is demonstrated to an example, this invention is not limited to this.

断熱材5は、シート状の部材であり、例えば、シリカ(SiO)、アルミナ(Al)などの微粒子を主材とした微孔性成形体で構成されている。
ところで、シリカ等の微粒子を成形した微孔性材質は、液体の水分に接すると流動化して断熱性が失われる。そのため、水分を加えて施工される不定形耐火物41が用いられる場合には、断熱材5の断熱性が低下するおそれがある。
そこで、断熱材5は、防水性の被覆材51に収納され、水分による劣化が防止されるのが好ましい。被覆材51の材質としては、防水性であれば特に限定されないが、例えば、樹脂フィルム等が挙げられ、具体的には、例えば、ポリプロピレンやポリエチレンなどの樹脂が適する。また、遮湿性を高めるためにこれらの樹脂でアルミ箔をラミネートした材質も用いられる。
The heat insulating material 5 is a sheet-like member, and is composed of, for example, a microporous molded body mainly composed of fine particles such as silica (SiO 2 ) and alumina (Al 2 O 3 ).
By the way, the microporous material formed by molding fine particles such as silica is fluidized when it comes into contact with moisture of the liquid and loses heat insulation. Therefore, when the amorphous refractory 41 constructed by adding moisture is used, the heat insulating property of the heat insulating material 5 may be lowered.
Therefore, it is preferable that the heat insulating material 5 is housed in a waterproof covering material 51 to prevent deterioration due to moisture. The material of the covering material 51 is not particularly limited as long as it is waterproof, and examples thereof include a resin film. Specifically, for example, a resin such as polypropylene or polyethylene is suitable. In addition, a material obtained by laminating an aluminum foil with these resins in order to improve the moisture barrier property is also used.

断熱材5の厚さ(図1中、T5で示す長さ)は、特に限定されないが、何らかの原因で断熱材5に溶鋼61が接した場合でも、溶鋼61が断熱材5を溶損させつつ広範囲に伸展することを防ぐという目的から、15mm以下が好ましく、3〜10mmがより好ましい。なお、断熱材5の厚さは、被覆材51を含む厚さとする。   The thickness of the heat insulating material 5 (the length indicated by T5 in FIG. 1) is not particularly limited. However, even when the molten steel 61 contacts the heat insulating material 5 for some reason, the molten steel 61 causes the heat insulating material 5 to melt. From the purpose of preventing extension over a wide range, it is preferably 15 mm or less, more preferably 3 to 10 mm. Note that the thickness of the heat insulating material 5 includes the covering material 51.

図2は、鉄皮2の内側面に沿って配置された複数の断熱材5を、溶鋼鍋1の内側から見た模式図である。図2では、鉄皮2および断熱材5以外の構成を省略して示している。   FIG. 2 is a schematic view of a plurality of heat insulating materials 5 arranged along the inner surface of the iron skin 2 as viewed from the inside of the molten steel pan 1. In FIG. 2, configurations other than the iron skin 2 and the heat insulating material 5 are omitted.

図2では、シート状の断熱材5として、長方形状のものを示している。しかし、断熱材5の形状は、多角形形状であれば特に限定されず、長方形のほか、例えば、台形、三角形などの形状が挙げられる。具体的には、例えば、鉄皮2が円錐台状である場合には、断熱材5の形状を台形とすることができる。   In FIG. 2, a rectangular shape is shown as the sheet-like heat insulating material 5. However, the shape of the heat insulating material 5 is not particularly limited as long as it is a polygonal shape, and examples thereof include a shape such as a trapezoid and a triangle in addition to a rectangle. Specifically, for example, when the iron skin 2 has a truncated cone shape, the shape of the heat insulating material 5 can be a trapezoid.

図2に示すように、複数枚の断熱材5が、鉄皮2の内側面に沿って、互いに隣接して配置される。断熱材5は、例えば、被覆材51(図1参照)と同じ材質の粘着テープによって、鉄皮2の内側面に固定される。
このとき、1つの断熱材5と、これに隣接する他の断熱材5のうちの少なくとも1つの断熱材5との間に、間隙Gが形成される。
例えば、図2中、断熱材5aの周囲には、他の断熱材5b〜5eが隣接配置される。このうち、断熱材5aと断熱材5bとの間、および、断熱材5aと断熱材5dとの間の位置に、それぞれ、間隙Gが形成される。そのため、永久耐火物層3およびワーク耐火物層4を省略した図2においては、間隙Gから鉄皮2が露出している。
As shown in FIG. 2, a plurality of heat insulating materials 5 are arranged adjacent to each other along the inner surface of the iron skin 2. The heat insulating material 5 is fixed to the inner surface of the iron skin 2 with, for example, an adhesive tape made of the same material as the covering material 51 (see FIG. 1).
At this time, a gap G is formed between one heat insulating material 5 and at least one of the other heat insulating materials 5 adjacent thereto.
For example, in FIG. 2, other heat insulating materials 5b to 5e are adjacently arranged around the heat insulating material 5a. Among these, the gap | interval G is formed in the position between the heat insulating material 5a and the heat insulating material 5b, and between the heat insulating material 5a and the heat insulating material 5d, respectively. Therefore, in FIG. 2 in which the permanent refractory layer 3 and the workpiece refractory layer 4 are omitted, the iron skin 2 is exposed from the gap G.

このとき、断熱材5は、形成される間隙Gが貫通孔H上に位置付けられるように配置される。なお、「間隙Gが貫通孔H上に位置付けられる」とは、間隙Gを形成する断熱材5が貫通孔Hの一部分を遮蔽する場合、および、間隙Gを形成する断熱材5が貫通孔Hを遮蔽せずに露出させる場合を含む概念とする。   At this time, the heat insulating material 5 is disposed such that the gap G to be formed is positioned on the through hole H. “The gap G is positioned on the through hole H” means that the heat insulating material 5 that forms the gap G shields a part of the through hole H, and the heat insulating material 5 that forms the gap G is the through hole H. The concept includes the case of exposing without shielding.

なお、図2では、直線状に形成された間隙Gに沿って、直線状に配列された貫通孔Hを示しているが、貫通孔Hの配列はこれに限定されるものではない。   In FIG. 2, the through holes H arranged in a straight line along the gap G formed in a straight line are shown, but the arrangement of the through holes H is not limited to this.

そして、本発明においては、断熱材5の間隙Gの幅(図2中、Wで示す長さ)を、上述した断熱材5の厚さ(図1中、T5で示す長さ)以上とする。このような間隙Gの幅の下限値は、通気性確保の観点から設定するものである。   And in this invention, the width | variety (length shown by W in FIG. 2) of the clearance gap G of the heat insulating material 5 shall be more than the thickness (length shown by T5 in FIG. 1) mentioned above. . Such a lower limit value of the width of the gap G is set from the viewpoint of ensuring air permeability.

本発明者らが、当初、厚さ6mmの断熱材5を、間隙Gの幅が1〜3mmとなるように配置したところ、事前乾燥の所要時間が大幅に延長した。使用後の解体調査の結果、これは、断熱材5の間隙Gに、永久耐火物層3を施工する際に用いたモルタル32が侵入し、間隙Gの通気性が損なわれたためであることが判明した。
そこで、本発明者らは、断熱材5を、間隙Gの幅が様々な寸法となるように配置し、事前乾燥中における貫通孔Hからの蒸気発生と鉄皮2の温度上昇とを観察した。その結果、断熱材5の厚さが6mmであると、間隙Gの幅が6mm未満の場合に事前乾燥の所要時間が延長し、断熱材5の厚さが3mmであると、間隙Gの幅が3mm未満の場合に事前乾燥の所要時間が延長した。
この現象を検証すべく、断熱材5の間隙Gに侵入したモルタル32の事前乾燥中の温度を伝熱計算により推定した。
When the present inventors initially arranged the heat insulating material 5 having a thickness of 6 mm so that the width of the gap G was 1 to 3 mm, the time required for the pre-drying was greatly extended. As a result of the dismantling investigation after use, this is because the mortar 32 used when constructing the permanent refractory layer 3 entered the gap G of the heat insulating material 5 and the air permeability of the gap G was impaired. found.
Therefore, the present inventors arranged the heat insulating material 5 so that the width of the gap G has various dimensions, and observed the generation of steam from the through hole H and the temperature increase of the iron skin 2 during the pre-drying. . As a result, if the thickness of the heat insulating material 5 is 6 mm, the time required for pre-drying is extended when the width of the gap G is less than 6 mm, and if the thickness of the heat insulating material 5 is 3 mm, the width of the gap G The time required for pre-drying was extended when the thickness was less than 3 mm.
In order to verify this phenomenon, the temperature during pre-drying of the mortar 32 that entered the gap G of the heat insulating material 5 was estimated by heat transfer calculation.

図3は、断熱材5の厚さに対する間隙Gの幅の比率と、間隙Gの鉄皮2側の温度との関係を示すグラフである。図3のグラフにおいて、横軸は、断熱材5の厚さに対する間隙Gの幅の比率(単位:%)を示す。一方、縦軸は、ワーク耐火物層4を構成する不定形耐火物41の外面側温度が120℃、蒸気圧が2気圧となる事前乾燥の中盤において、モルタル32が侵入した間隙Gの鉄皮2側の温度を計算した値(単位:℃)である。   FIG. 3 is a graph showing the relationship between the ratio of the width of the gap G to the thickness of the heat insulating material 5 and the temperature of the gap G on the iron skin 2 side. In the graph of FIG. 3, the horizontal axis indicates the ratio (unit:%) of the width of the gap G to the thickness of the heat insulating material 5. On the other hand, the vertical axis represents the iron skin of the gap G into which the mortar 32 has entered in the pre-drying middle plate where the outer surface temperature of the amorphous refractory 41 constituting the workpiece refractory layer 4 is 120 ° C. and the vapor pressure is 2 atm. This is a value (unit: ° C) calculated from the temperature on the second side.

図3のグラフから、横軸の値が100%未満の場合(すなわち、間隙Gの幅が断熱材5の厚さよりも小さい場合)、縦軸の値(すなわち、モルタル32が侵入した間隙Gの鉄皮2側の温度)が100℃を下回り、間隙Gに侵入したモルタル32の付着水の蒸発が緩慢となるのみならず、不定形耐火物41から発生した蒸気が通過する際に凝縮し、通気性が著しく損なわれることが裏付けられた。   From the graph of FIG. 3, when the value on the horizontal axis is less than 100% (that is, when the width of the gap G is smaller than the thickness of the heat insulating material 5), the value on the vertical axis (that is, the gap G in which the mortar 32 has entered). The temperature of the iron skin 2 side) is less than 100 ° C., and not only the evaporation of the adhering water of the mortar 32 that has entered the gap G becomes slow, but also condenses when the vapor generated from the amorphous refractory 41 passes, It was confirmed that the air permeability was significantly impaired.

以上のことから、本発明においては、断熱材5の間隙Gの幅を、断熱材5の厚さ以上とする。これにより、断熱材5を施工した溶鋼鍋1においても、不定形耐火物41の事前乾燥中の通気性を良好にすることができる。   From the above, in the present invention, the width of the gap G of the heat insulating material 5 is set to be equal to or larger than the thickness of the heat insulating material 5. Thereby, also in the molten steel pan 1 which constructed the heat insulating material 5, the air permeability during the preliminary drying of the amorphous refractory 41 can be made favorable.

また、断熱材5の間隙Gの幅は、間隙Gを形成したことによる断熱効果の低下を最小限に抑える観点から、鉄皮2の厚さ(図1中、T2で示す長さ)以下であるのが好ましい。次に、このような間隙Gの幅の上限値について説明する。   In addition, the width of the gap G of the heat insulating material 5 is less than the thickness of the iron skin 2 (the length indicated by T2 in FIG. 1) from the viewpoint of minimizing the decrease in the heat insulating effect due to the formation of the gap G. Preferably there is. Next, the upper limit value of the width of the gap G will be described.

図4(a)は、鉄皮2の厚さを30mm、断熱材5の間隙Gの幅を40〜50mmにした溶鋼鍋1(直径:4.0m、高さ:4.5m)を示す赤外線熱画像であり、図4(b)は、図4(a)の赤外線熱画像中のラインAおよびBの温度分布を示すグラフである。
より詳細には、図4(a)の赤外線熱画像は、クレーンで吊り上げた溶鋼61が収容された状態の溶鋼鍋1を側面のやや下側から見た図であり、明るい(色が薄い)部位ほど高温であることを示す。
また、図4(b)のグラフは、図4(a)の赤外線熱画像中の×点で始まり他端で終わる範囲(ラインAおよびB)の温度分布である。ラインAおよびBの長さは、それぞれ1.05mおよび1.08mである。図4(b)のグラフにおいて、横軸は×点を左端としたラインAおよびBのピクセル数を示し、縦軸は温度(単位:℃)を示す。
FIG. 4A is an infrared ray showing a molten steel pan 1 (diameter: 4.0 m, height: 4.5 m) in which the thickness of the iron skin 2 is 30 mm and the width of the gap G of the heat insulating material 5 is 40 to 50 mm. FIG. 4B is a graph showing the temperature distribution of lines A and B in the infrared thermal image of FIG. 4A.
More specifically, the infrared thermal image of FIG. 4A is a view of the molten steel pan 1 in a state in which the molten steel 61 lifted by a crane is accommodated from a slightly lower side, and is bright (color is light). It shows that the part is hotter.
Also, the graph of FIG. 4B is a temperature distribution in a range (lines A and B) that starts at the point x and ends at the other end in the infrared thermal image of FIG. The lengths of lines A and B are 1.05 m and 1.08 m, respectively. In the graph of FIG. 4B, the horizontal axis indicates the number of pixels in lines A and B with the x point as the left end, and the vertical axis indicates temperature (unit: ° C.).

ここで、例えば、ラインAに着目する。ラインAは、×点の温度が約240℃である。ラインAにおいて、鉄皮2のうち間隙Gに位置する部位(以下、「鉄皮間隙部2a」ともいう。)は、図4(a)中ではやや明るく、図4(b)のグラフでは山になっており、×点以外に2箇所ある。鉄皮間隙部2aは、他の部位よりも20〜30℃程度高く、温度上昇が認められる。   Here, for example, attention is paid to the line A. In line A, the temperature at the point x is about 240 ° C. In the line A, the part located in the gap G (hereinafter, also referred to as “iron gap part 2a”) of the iron skin 2 is slightly brighter in FIG. 4A, and is a mountain in the graph of FIG. There are two places other than the x point. The iron crevice gap 2a is about 20-30 ° C. higher than other parts, and an increase in temperature is observed.

シュテファン=ボルツマンの法則から、外部への輻射放熱は鉄皮2の外面温度の4乗に比例し、鉄皮間隙部2aでは、外部への輻射放熱が20%増加している。断熱効果の低下を抑制する観点から、断熱材5の間隙Gの幅はできるだけ小さい方が好ましい。
しかし、上述した間隙Gの幅の下限値、すなわち、断熱材5の厚さは、一般的に1〜20mm程度であるため、間隙Gの幅を下限値に合わせて正確に施工することは困難である。
From the Stefan-Boltzmann law, the radiation heat radiation to the outside is proportional to the fourth power of the outer surface temperature of the iron skin 2, and the radiation heat radiation to the outside is increased by 20% in the iron skin gap 2a. From the viewpoint of suppressing a decrease in the heat insulating effect, the width of the gap G of the heat insulating material 5 is preferably as small as possible.
However, since the lower limit of the width of the gap G described above, that is, the thickness of the heat insulating material 5 is generally about 1 to 20 mm, it is difficult to accurately construct the gap G in accordance with the lower limit. It is.

そこで、間隙Gの幅が大きくなると鉄皮2の外面温度が上昇し、シュテファン=ボルツマンの法則から、外部への輻射放熱は鉄皮2の外面温度の4乗に比例することに着目し、外部への輻射放熱を大幅に増加させない条件を伝熱計算により推定した。   Therefore, when the width of the gap G is increased, the outer surface temperature of the iron skin 2 is increased, and from the Stefan-Boltzmann law, it is noted that the radiation heat radiation to the outside is proportional to the fourth power of the outer surface temperature of the iron skin 2, Conditions that do not significantly increase the radiation heat dissipation to are estimated by heat transfer calculation.

図5は、鉄皮2の厚さに対する間隙Gの幅の比率と、鉄皮間隙部2aの輻射放熱量との関係を示すグラフである。
図5のグラフにおいて、横軸は、鉄皮2の厚さに対する間隙Gの幅の比率(単位:%)を示す。一方、縦軸は、溶鋼鍋1に溶鋼61が収容された状態における、鉄皮間隙部2aの外部への輻射放熱を計算した値であり、横軸が80%の計算結果を100とした指数である。
図5のグラフから、間隙Gの幅が鉄皮2の厚さよりも大きい場合は、輻射放熱が急激に増加することが示唆される。
FIG. 5 is a graph showing the relationship between the ratio of the width of the gap G to the thickness of the iron skin 2 and the amount of radiant heat released from the iron skin gap 2a.
In the graph of FIG. 5, the horizontal axis indicates the ratio (unit:%) of the width of the gap G to the thickness of the iron skin 2. On the other hand, the vertical axis is a value obtained by calculating the radiation heat radiation to the outside of the core gap 2a in a state where the molten steel 61 is accommodated in the molten steel pan 1, and the horizontal axis is an index with the calculation result of 100% being 100%. It is.
From the graph of FIG. 5, it is suggested that when the width of the gap G is larger than the thickness of the iron shell 2, the radiation heat dissipation increases rapidly.

図6(a)は、鉄皮2の厚さを30mm、断熱材5の間隙Gの幅を20〜30mmにした溶鋼鍋1を示す赤外線熱画像であり、図6(b)は、図6(a)の赤外線熱画像中のラインAおよびBの温度分布を示すグラフである。図6(a)および(b)の基本的な見方は、それぞれ、図4(a)および(b)と同じであるため、説明を省略するが、ラインAおよびBの長さは、それぞれ0.58mおよび1.10mである。
図6(a)および(b)からは、図4(a)および(b)では認められていた鉄皮間隙部2aでの温度上昇が、解消されていることが分かる。
したがって、断熱効果の大幅な低下が抑制できるという理由から、断熱材5の間隙Gの幅は、鉄皮2の厚さ以下とするのが好ましい。
FIG. 6A is an infrared thermal image showing the molten steel pan 1 in which the thickness of the iron skin 2 is 30 mm and the width of the gap G of the heat insulating material 5 is 20 to 30 mm, and FIG. It is a graph which shows the temperature distribution of the lines A and B in the infrared thermal image of (a). 6 (a) and 6 (b) are the same as FIGS. 4 (a) and 4 (b), respectively, and the description thereof is omitted. However, the lengths of the lines A and B are each 0. .58 m and 1.10 m.
6 (a) and 6 (b), it can be seen that the temperature increase in the iron-skin gap 2a, which was recognized in FIGS. 4 (a) and 4 (b), has been eliminated.
Therefore, it is preferable that the width of the gap G of the heat insulating material 5 is equal to or less than the thickness of the iron shell 2 because a significant decrease in the heat insulating effect can be suppressed.

以下に、実施例を挙げて本発明を具体的に説明する。ただし、本発明はこれらに限定されるものではない。   Hereinafter, the present invention will be specifically described with reference to examples. However, the present invention is not limited to these.

<発明例1>
図1の溶鋼鍋1(直径:4.0m、高さ:4.5m)において、鉄皮2(厚さ:30mm)の内側に、ろう石煉瓦を耐火物31として使用し、モルタル32を目地材として永久耐火物層3(厚さ:50mm)を形成した。さらに、アルミナ−マグネシア質の不定形耐火物41を、6質量%の混練水分として、永久耐火物層3と型枠(図示せず)との間に流し込み、ワーク耐火物層4(厚さ:120mm)を形成した。
<Invention Example 1>
In the molten steel ladle 1 (diameter: 4.0 m, height: 4.5 m) in FIG. 1, a wax stone brick is used as the refractory 31 inside the iron skin 2 (thickness: 30 mm), and the mortar 32 is a joint. A permanent refractory layer 3 (thickness: 50 mm) was formed as a material. Further, the alumina-magnesia amorphous refractory 41 is poured as a 6% by mass kneaded moisture between the permanent refractory layer 3 and a mold (not shown), and the workpiece refractory layer 4 (thickness: 120 mm).

また、敷部を除いて、鉄皮2と永久耐火物層3との間には、ポリエチレン樹脂フィルム(遮湿性を高めるためにアルミ箔をラミネートしたもの)製の被覆材51に収納されたシート状の断熱材5(厚さ:5mm)を施工した。断熱材5は、シリカおよびアルミナの微粒子を主材とした微孔性成形体で構成され、その形状は長方形であった(500〜1000mm×350〜500mm)。   Moreover, the sheet | seat accommodated in the coating | covering material 51 made from a polyethylene resin film (thin which laminated | stacked aluminum foil in order to improve moisture-proof property) is provided between the iron skin 2 and the permanent refractory layer 3 except a floor part. A heat insulating material 5 (thickness: 5 mm) was applied. The heat insulating material 5 was composed of a microporous molded body mainly composed of silica and alumina fine particles, and the shape thereof was rectangular (500 to 1000 mm × 350 to 500 mm).

このとき、複数枚の断熱材5を、被覆材51と同じ材質の粘着テープによって、鉄皮2の内側面に固定し、互いに隣接配置した。鉄皮2には、貫通孔H(孔径:12mm)がライン状に形成されていたが、図2に示すようにして、断熱材5の上下辺に、貫通孔H上に位置付けられる間隙Gを形成した。   At this time, the plurality of heat insulating materials 5 were fixed to the inner surface of the iron shell 2 with an adhesive tape made of the same material as the covering material 51 and arranged adjacent to each other. Although the through-hole H (hole diameter: 12 mm) was formed in the iron skin 2 in the shape of a line, the gap G positioned on the through-hole H is formed on the upper and lower sides of the heat insulating material 5 as shown in FIG. Formed.

断熱材5の施工は手作業で行なった。施工に際しては、直径8mmの鉛筆を携帯し、間隙Gの幅が、この鉛筆の直径から直径の2倍までの寸法となるように留意した。すなわち、間隙Gの幅を8〜16mmとした。このような施工により、間隙Gが位置付けられた貫通孔Hは、その四分の一程度が断熱材5によって遮蔽されるものもあった。   The construction of the heat insulating material 5 was performed manually. At the time of construction, a pencil with a diameter of 8 mm was carried, and attention was paid so that the width of the gap G would be a dimension from the diameter of this pencil to twice the diameter. That is, the width of the gap G was 8 to 16 mm. As a result of such construction, some of the through holes H in which the gap G is positioned are shielded by the heat insulating material 5 in about a quarter.

<発明例2>
間隙Gの幅を、20〜40mmとした以外は、発明例1と同様にして、断熱材5を施工した。施工に際しては、直径20mmの丸棒を携帯し、間隙Gの幅が、この丸棒の直径から直径の2倍までの寸法となるように留意した。間隔の許容範囲を大きくしたことにより、より大型の断熱材を用いることができ、施工性は向上した。
<Invention Example 2>
The heat insulating material 5 was constructed in the same manner as in Invention Example 1 except that the width of the gap G was set to 20 to 40 mm. At the time of construction, a round bar having a diameter of 20 mm was carried, and attention was paid so that the width of the gap G would be a dimension from the diameter of this round bar to twice the diameter. By increasing the allowable range of the interval, a larger heat insulating material can be used, and the workability is improved.

<比較例1>
間隙Gの幅を、2〜4mmとした以外は、発明例1と同様にして、断熱材5を施工した。施工に際しては、直径2mmの丸棒を携帯し、間隙Gの幅が、この丸棒の直径から直径の2倍までの寸法となるように留意した。
<Comparative Example 1>
The heat insulating material 5 was constructed in the same manner as in Invention Example 1 except that the width of the gap G was set to 2 to 4 mm. At the time of construction, a round bar having a diameter of 2 mm was carried and attention was paid so that the width of the gap G would be a dimension from the diameter of this round bar to twice the diameter.

<評価>
各例において、不定形耐火物41を流し込みワーク耐火物層4を形成した後、バーナを用いて、ワーク耐火物層4の稼働面側から事前乾燥を、加熱温度等の各条件を同じにして行ない、事前乾燥の開始から所要時間を測定した。なお、事前乾燥は、鉄皮外面温度がアルミナセメントの脱水温度である150℃に到達することにより、終了したものと判断した。
各例の所要時間を、発明例1の所要時間を100とした指数で評価した。結果を下記第1表に示す。指数が小さいほど、事前乾燥が終了するまでの時間が短く、事前乾燥中の通気性が良好であるものとして評価できる。
<Evaluation>
In each example, after pouring the amorphous refractory 41 and forming the workpiece refractory layer 4, using a burner, pre-drying from the working surface side of the workpiece refractory layer 4, with the same conditions such as the heating temperature, etc. The time required from the start of pre-drying was measured. In addition, it was judged that pre-drying was complete | finished when the iron-skin outer surface temperature reached 150 degreeC which is the dehydration temperature of an alumina cement.
The time required for each example was evaluated by an index with the time required for Example 1 as 100. The results are shown in Table 1 below. It can be evaluated that the smaller the index is, the shorter the time until the predrying is completed and the better the air permeability during the predrying.

また、各例において、事前乾燥終了後の溶鋼鍋1に溶鋼61を収容する使用を開始し、3日経過後の赤外線熱画像から、鉄皮間隙部2aの温度上昇を評価した。鉄皮2における鉄皮間隙部2aの、他の部位からの温度差の最大値(単位:℃)を、下記第1表に示す。温度差が小さいほど、鉄皮間隙部2aの温度上昇が抑制され、断熱性に優れるものとして評価できる。   Moreover, in each example, the use which accommodates the molten steel 61 in the molten steel pan 1 after completion | finish of prior drying was started, and the temperature rise of the iron-skin gap | interval part 2a was evaluated from the infrared thermal image after 3 day progress. The maximum value (unit: ° C.) of the temperature difference from other parts of the core gap 2a in the core 2 is shown in Table 1 below. As the temperature difference is smaller, the temperature rise of the iron gap portion 2a is suppressed, and it can be evaluated that the heat insulation is excellent.

また、各例において、事前乾燥終了後の溶鋼鍋1に溶鋼61を収容する使用を開始し、14日経過後の耐火物状況を点検観察し、剥離損耗の有無を評価した。剥離損耗とは、正常な溶損とは異なり、耐火物の内部の異常により10mm以上の厚さで剥落することであり、事前乾燥が十分でないことが原因の1つとして挙げられる。   Moreover, in each example, the use which accommodates the molten steel 61 in the molten steel pan 1 after completion | finish of prior drying was started, the refractory situation after 14-day progress was inspected and observed, and the presence or absence of peeling abrasion was evaluated. Peeling wear is different from normal melting loss and is peeling off at a thickness of 10 mm or more due to an abnormality inside the refractory, and one reason is that pre-drying is not sufficient.

上記第1表に示す結果から、発明例1,2は、比較例1よりも事前乾燥の所要時間が短く、事前乾燥中の通気性が良好であることが分かった。また、比較例1は使用中の剥離損耗が認められ、事前乾燥時間が長いにもかかわらず乾燥が不十分であった可能性がある。
また、発明例1は、発明例2よりも、鉄皮2における鉄皮間隙部2aと他部位との温度差が小さく、鉄皮間隙部2aの温度上昇が抑制されたことが分かった。なお、発明例1では、鉄皮間隙部2aの温度上昇が10℃以下であり、輻射放熱の増加は無視できる範囲であった。
From the results shown in Table 1, it was found that Invention Examples 1 and 2 required a shorter time for pre-drying than Comparative Example 1, and had good air permeability during pre-drying. Further, in Comparative Example 1, peeling wear during use was observed, and there was a possibility that the drying was insufficient despite the long pre-drying time.
In addition, it was found that Invention Example 1 had a smaller temperature difference between the iron skin gap 2a and the other part of the iron skin 2 than the Invention Example 2, and the temperature increase of the iron skin gap 2a was suppressed. In Invention Example 1, the temperature rise of the iron gap portion 2a was 10 ° C. or less, and the increase in radiation heat dissipation was in a negligible range.

1 溶鋼鍋(溶融金属容器)
2 鉄皮
2a 鉄皮間隙部
3 永久耐火物層
31 耐火物(定形耐火物)
32 モルタル
4 ワーク耐火物層
41 耐火物(不定形耐火物)
5 断熱材
51 被覆材
61 溶鋼(溶融金属)
G 間隙
H 貫通孔
T2 鉄皮の厚さ
T5 断熱材の厚さ
W 間隙の幅
1 Molten steel pan (molten metal container)
2 Iron skin 2a Iron skin gap 3 Permanent refractory layer 31 Refractory (standard refractory)
32 mortar 4 work refractory layer 41 refractory (indefinite refractory)
5 Thermal insulation material 51 Coating material 61 Molten steel (molten metal)
G Gap H Through-hole T2 Iron skin thickness T5 Heat insulation thickness W Gap width

Claims (3)

溶融金属を収容する溶融金属容器のライニング構造であって、
前記溶融金属容器の最外層を構成し、外側面と内側面とを貫通する複数個の貫通孔を有する鉄皮と、
前記鉄皮の内側に設けられる、1層または2層の永久耐火物層と、
前記永久耐火物層の内側に設けられ、前記溶融金属と接する稼働面を形成し、少なくとも一部が不定形耐火物で構成されるワーク耐火物層と、
シート状の多角形部材であって、前記鉄皮と前記永久耐火物層との間、または、2層の前記永久耐火物層どうしの間に施工され、前記鉄皮の内側面に沿って隣接配置される複数枚の断熱材と、
を備え、
1つの前記断熱材と、当該断熱材に隣接配置される他の前記断熱材のうちの少なくとも1つとの間に、間隙が形成され、
前記間隙が、前記貫通孔上に位置付けられ、かつ、前記断熱材の厚さ以上の幅を有する、溶融金属容器のライニング構造。
A molten metal lining structure for containing molten metal,
The outermost layer of the molten metal container, the iron skin having a plurality of through holes penetrating the outer surface and the inner surface,
One or two permanent refractory layers provided inside the iron skin;
A workpiece refractory layer provided on the inside of the permanent refractory layer, forming a working surface in contact with the molten metal, at least a part of which is formed of an amorphous refractory;
A sheet-like polygonal member, which is constructed between the iron skin and the permanent refractory layer, or between the two layers of the permanent refractory layer, and is adjacent along the inner surface of the iron skin A plurality of thermal insulators arranged;
With
A gap is formed between one of the heat insulating materials and at least one of the other heat insulating materials arranged adjacent to the heat insulating material,
The molten metal container lining structure, wherein the gap is positioned on the through hole and has a width equal to or greater than a thickness of the heat insulating material.
前記間隙の幅が、前記鉄皮の厚さ以下である、請求項1に記載の溶融金属容器のライニング構造。   The lining structure of the molten metal container according to claim 1, wherein a width of the gap is equal to or less than a thickness of the iron skin. 前記断熱材が、防水性の被覆材に収納されている、請求項1または2に記載の溶融金属容器のライニング構造。   The lining structure of the molten metal container according to claim 1 or 2, wherein the heat insulating material is accommodated in a waterproof covering material.
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