JP5216291B2 - Ceramic fiber block - Google Patents

Description

The present invention relates to a ceramic fiber block in which scattering of a furnace material shot (short fibers peeled off from a ceramic fiber refractory material) is prevented.

In recent years, ceramic fiber blocks have been used for heat insulation walls of heat treatment furnaces such as heating furnaces and annealing furnaces. For example, Patent Document 1 discloses a ceramic fiber block formed by continuously folding a ceramic fiber blanket, and a bolt attached to an inner surface of a heat treatment furnace is formed in a channel provided outside the ceramic fiber block. The method of fixing to the inner surface of the iron skin by passing through the bolt hole and tightening the nut with a box wrench is shown. However, since the surface of the ceramic fiber block is exposed in the heat treatment furnace, there arises a problem that the furnace material shot is wrinkled on the surface of the strip passing through the furnace. Therefore, in Patent Document 2, the surface of the furnace wall constituted by the ceramic fiber block is covered with a protective sheet such as a stainless steel protective plate or a ceramic fiber cloth to prevent the furnace material shot from being scattered, and the strip is made of the ceramic fiber block. To prevent contact.

JP 2003-55056 A JP-A-6-221770

However, in the invention described in Patent Document 2, since the protective plate or the protective sheet collectively covers a plurality of ceramic fiber blocks constituting the furnace wall of the heat treatment furnace, the arrangement of the ceramic fiber blocks for each heat treatment furnace. In addition to the design, there is a problem that the work of designing the arrangement of the protective plate or the protective sheet and creating the construction drawing is required, and the design work of the furnace wall becomes complicated. Furthermore, since the installation work of the protective plate or the protective sheet is performed after the installation work of the ceramic fiber block, there is a problem that the construction period is prolonged.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a ceramic fiber block capable of preventing the scattering of furnace material shots and improving the efficiency of the furnace wall design and shortening the furnace wall construction period. .

The ceramic fiber block according to the present invention in line with the above object is arranged side by side inside the furnace shell of the heat treatment furnace to form a heat insulation wall of the heat treatment furnace, and the inner wall surface forming the furnace inner surface of the heat insulation wall is a protective plate made of stainless steel Ceramic fiber blocks each coated with
A laminated body formed by continuously folding a ceramic fiber blanket, a channel provided outside the fold of the laminated body and disposed on the inside of the fold of the laminated body, to which a support member for supporting the laminated body is attached, and A box nut that penetrates through the laminated body and is fastened to the front side of the first stud bolt that is attached to the inside of the furnace shell and passes through the first bolt hole formed in the channel is provided on the base side. And a second stud bolt that passes through a second bolt hole formed in the protective plate and is tightened with a nut.

In the ceramic fiber block according to the present invention, the inner wall surface is rectangular when viewed from the front, and a corner portion of any one side of the inner wall surface or each corner portion of any two adjacent sides is the stainless steel protective plate It is preferable that it is covered with the end side bending part.

In the ceramic fiber block according to the present invention, it is preferable that an area of the stainless steel protection plate viewed from the front is larger than an area of the inner wall surface.

In the ceramic fiber block according to the present invention, a slit-like pair of openings is formed on the surface of the stainless steel protective plate, and a binding member for bundling the laminated body passes through the pair of openings. preferable.

In the ceramic fiber block according to claims 1 to 4, since the stainless steel protective plate that covers the inner wall surface forming the furnace inner surface of the heat insulation wall of the heat treatment furnace is provided, the installation of the ceramic fiber block and the stainless steel protection are provided. The plate can be installed at the same time, and the work of designing the installation of the stainless protection plate and drawing it becomes unnecessary. As a result, the furnace wall design can be performed efficiently, and the ceramic fiber block incorporating the stainless steel protective plate can be used for general purposes, thereby reducing the cost and the construction period.
Since the stainless steel protective plate is fixed by the second stud bolt provided on the base side with the box nut fixed to the first stud bolt penetrating the channel of the ceramic fiber block, the stainless steel protective plate is laminated. It is not necessary to perform a new treatment for fixing to the stainless steel, and the stainless protection plate can be installed very easily.

In particular, in the ceramic fiber block according to claim 2, when the ceramic fiber blocks are arranged side by side, the corners of the end side bent portions of the stainless steel protective plates respectively provided on the adjacent ceramic fiber blocks are not in contact with each other. It is possible to prevent competition between stainless protective plates. In addition, the corners of the end side bent portions of the stainless steel protective plates of adjacent ceramic fiber blocks do not contact each other, so that during the heat treatment furnace operation, the competition due to the thermal expansion of the stainless steel protective plates of the adjacent ceramic fiber blocks Can be prevented.

In the ceramic fiber block according to the third aspect, the stainless steel protective plates can be overlapped with each other between the adjacent ceramic fiber blocks, and it is possible to more reliably prevent the scattering of the furnace material shot into the heat treatment furnace.

In the ceramic fiber block according to claim 4 , since the bundling member for bundling the laminate passes through the slit-like opening formed on the surface of the stainless steel protective plate, the stainless steel protective plate and the laminate are It can be integrated and the handling of the ceramic fiber block becomes easy. Then, by cutting the portion of the binding member that passes through the pair of openings, the binding member can be pulled out from one of the openings, and the binding member can be easily detached from the ceramic fiber block.

Next, embodiments of the present invention will be described with reference to the accompanying drawings for understanding of the present invention.
Here, FIG. 1 is a perspective view of a ceramic fiber block according to an embodiment of the present invention, and FIGS. 2A and 2B are perspective views showing a state in which a channel is attached to the laminate of the ceramic fiber block. 3 is a perspective view showing a state before the ceramic fiber block is attached. FIG. 4 is a side sectional view showing a state in which the ceramic fiber block is attached to the inside of the furnace shell. FIG. FIG. 6 is a perspective view showing a state in which the blocks are arranged side by side, and FIG. 6 is a plan view showing a state according to a modified example in which the ceramic fiber block is attached to the inside of the furnace shell.

As shown in FIGS. 1 and 5, the ceramic fiber block 10 according to one embodiment of the present invention is arranged side by side inside the furnace shell 11 of the heat treatment furnace to form the heat insulation wall 12 of the heat treatment furnace. The inner wall surface 13 forming the furnace inner surface is covered with a stainless protection plate 14. This will be described in detail below.

As shown in FIGS. 2 (A) and 2 (B), the ceramic fiber block 10 is made of, for example, a ceramic fiber blanket 15 made of alumina or alumina-silica, and having a width W of 250 to 650 mm. When the laminated body 16 formed by continuously folding and the laminated body 16 provided outside the fold line of the laminated body 16 are arranged inside the furnace shell 11, the side plate tip is brought into contact with the inside of the furnace shell 11. Channel 17. Here, the first bolt hole 18 is provided in the groove bottom portion of the channel 17, for example, in the central portion in the longitudinal direction. Further, it is an example of a support member that supports the laminated body 16 by being disposed inside the fold line of the laminated body 16 outside the groove bottom portion in the longitudinal direction of the channel 17 while avoiding the position where the first bolt hole 18 is formed. A plurality of beams 19 are mounted side by side perpendicular to the longitudinal direction of the channel 17 via a fixing member 20. The length of the beam 19 is shorter than the width of the ceramic fiber blanket 15 (for example, 10 to 50 mm shorter than the width of the ceramic fiber blanket 15), and each beam 19 is accommodated in the fold. Thereby, the laminated body 16 and the channel 17 can be integrated through the beam 19 and the beam 19 can be prevented from being heated.

As shown in FIG. 1, the inner wall surface 13 formed on the front surface of the laminate 16 by connecting the folds when the ceramic fiber blanket 15 is continuously folded is rectangular in front view and has a vertical length. Is the same as the width W of the ceramic fiber blanket 15, and the lateral length L is 250 to 350 mm. It also includes the case of a square when viewed from the front. The corner portions of any two adjacent sides of the inner wall surface 13 are covered with end side bent portions 21 and 22 of the stainless steel protective plate 14, respectively. And since the area of the stainless steel protection plate 14 as viewed from the front is larger than the area of the inner wall surface 13, the protrusions 23, 24, and A connecting portion 25 that connects the protruding portions 23 and 24 is formed. The stainless steel protection plate 14 is hooked on the inner wall surface 13 side of the laminate 16 by covering the corners of two adjacent sides of the inner wall surface 13 with the end side bent portions 21 and 22 of the stainless steel protection plate 14. Thus, rotation and displacement of the stainless protection plate 14 can be prevented.

Further, as shown in FIG. 4, the ceramic fiber block 10 is provided through the laminated body 16, passes through a first bolt hole 18 formed in the channel 17, and is attached to the inside of the furnace shell 11. A box nut 27 to be tightened to the front side of the stud bolt 26 is provided on the base side, and the nut 30 is tightened through a washer 29 through the second bolt hole 28 formed in the stainless steel protective plate 14 on the front side. A second stud bolt 31 is provided. Thereby, the stainless steel protection plate 14 can be fixed to the laminated body 16 using the second stud bolt 31 that fixes the laminated body 16 to the inside of the furnace shell 11 via the first stud bolt 26. As a result, the ceramic fiber block 10 can be easily installed inside the furnace shell 11.

Further, as shown in FIG. 1, when the ceramic fiber block 10 is viewed from the front, a slit-like pair of openings 41 are provided above and below one side (right side in the drawing) of the surface of the stainless steel protection plate 14 in the left-right direction. , 42 are formed. For this reason, as shown in FIG. 3, the binding part 43 of the band 32 is formed between the openings 41 and 42 so that the band 32 which is an example of a binding member for bundling the laminate 16 penetrates between the pair of openings 41 and 42. Can be provided. Thereby, the stainless steel protection plate 14 and the laminated body 16 can be integrated, and handling of the ceramic fiber block 10 becomes easy. Then, after fixing the ceramic fiber block 10 inside the furnace shell 11, the band 32 can be easily detached from the ceramic fiber block 10 by cutting one side of the binding portion 43 and pulling out the binding portion 43.

Then, the method at the time of installing the ceramic fiber block 10 which concerns on one embodiment of this invention inside the furnace shell 11 of a heat treatment furnace is demonstrated.
First, as shown in FIG. 3, the first stud bolt 26 attached to the furnace shell 11 is a ceramic fiber block 10 in which the laminated body 16 and the stainless steel protection plate 14 are bound and integrated by a band 32. It positions so that the 1st bolt hole 18 formed in the channel 17 of the fiber block 10 may be penetrated. At this time, as shown in FIGS. 4 and 5, when the ceramic fiber block 10 is viewed from the front, the end side bent portions 21 and 22 of the stainless protection plate 14 covering the corners of the two adjacent sides of the inner wall surface 13 are provided. However, it arrange | positions so that it may become the one side (right side in a figure) of a left-right direction and the one side (lower side in a figure) of an up-down direction. Then, as shown in FIG. 4, the second stud bolt 31 is turned to fasten the base box nut 27 to the front side of the first stud bolt 26 penetrating the first bolt hole 18. Thereby, the ceramic fiber block 10 is fixed inside the furnace shell 11 of the heat treatment furnace.

Here, for example, the ceramic fiber blanket 33 made of alumina or alumina-silica ceramic fiber is attached to the furnace wall (inside the furnace shell 11), so the channel 17 of the ceramic fiber block 10 is provided. The surface on the side is in contact with the ceramic fiber blanket 33, and the first stud bolt 26 passes through the ceramic fiber blanket 33. For this reason, when the ceramic fiber block 10 is fixed inside the furnace shell 11 of the heat treatment furnace, a gap generated in the channel 17 can be closed. Then, a washer 29 is attached to the front side of the second stud bolt 31 and the nut 30 is tightened. Thereby, the protection plate 14 made of stainless steel is integrated with the laminate 16 and the fixing of the ceramic fiber block 10 is completed.

When the fixing of the ceramic fiber block 10 to the inside of the furnace shell 11 of the heat treatment furnace is completed, for example, the ceramic fiber block 34 similar to the ceramic fiber block 10 is positioned on the right side of the ceramic fiber block 10 and the furnace shell of the heat treatment furnace is placed. 11, the end side bent portions 21 and 22 of the stainless steel protection plate 14 provided on the ceramic fiber block 34 are arranged on the right side and the lower side, respectively, and provided on the ceramic fiber block 10. The corner portion covered with the end-side bent portion 21 of the stainless protective plate 14 and the right side of the protruding portion 24 are covered with the protruding portion 23 and the connecting portion 25 of the stainless protective plate 14 provided on the ceramic fiber block 34. To.

When the ceramic fiber block 35 similar to the ceramic fiber block 10 is positioned below the ceramic fiber block 10 and fixed inside the furnace shell 11 of the heat treatment furnace, a stainless steel protection provided on the ceramic fiber block 35 is provided. The end side bent portions 21 and 22 of the plate 14 are arranged so as to be on the right side and the lower side, respectively, and corner portions covered with the end side bent portions 22 of the stainless steel protection plate 14 provided on the ceramic fiber block 10 and The lower side of the protruding portion 23 is covered with the protruding portion 24 and the connecting portion 25 of the stainless steel protection plate 14 provided on the ceramic fiber block 35.

Further, when the ceramic fiber block 36 similar to the ceramic fiber block 10 is positioned below the ceramic fiber block 34 and on the right side of the ceramic fiber block 35 and fixed inside the furnace shell 11 of the heat treatment furnace, the ceramic fiber block The end side bent portions 21 and 22 of the stainless steel protection plate 14 provided on 36 are arranged on the right side and the lower side, respectively, and the end side bent portions of the stainless steel protection plate 14 provided on the ceramic fiber block 34 are arranged. The corners covered with 22 and the lower side of the protrusions 23 are covered with the protrusions 24 and the connecting parts 25 of the stainless steel protective plate 14 provided on the ceramic fiber block 36 and are made of stainless steel provided on the ceramic fiber block 35. End side bent portion of the protective plate 14 1-covered corners and right projecting portions 24 so as to be covered by the projection 23 and the connecting portion 25 of the stainless steel protective plate 14 provided on the ceramic fiber block 36. When the fixing of the ceramic fiber block 10 to the inside of the furnace shell 11 of the heat treatment furnace is completed, one side of the binding portion 43 between the openings 41 and 42 on the surface of the stainless protection plate 14 is cut to bind the binding portion 43. To remove the band 32 from the ceramic fiber block 10.

As described above, by fixing the ceramic fiber blocks 10 and 34 to 36 inside the furnace shell 11 of the heat treatment furnace, the ceramic fiber blocks 10 and 34 to 36 and the respective stainless steel protection plates 14 are installed simultaneously. Thus, the installation design of the stainless steel protection plate 14 and the drawing work are not required, and the construction period of the ceramic fiber block can be shortened. In the adjacent ceramic fiber blocks 10 and 34 to 36, the corner portions of the end side bent portions 21 and 22 of the stainless steel protective plates 14 do not contact each other, so that the stainless steel when the ceramic fiber blocks 10 and 34 to 36 are attached is used. Competing between the protection plates 14 can be prevented, and competition due to thermal expansion of the stainless protection plate 14 can be prevented when the heat treatment furnace is in operation. In addition, between the adjacent ceramic fiber blocks 10 and 34 to 36, the protruding portions 23 and 24 of one stainless steel protective plate 14 overlap the corners covered by the end side bent portions 21 and 22 of the other stainless steel protective plate 14. Therefore, it is possible to more reliably prevent the scattering of the furnace material shot into the heat treatment furnace.

Here, as shown in FIG. 6, in the stainless steel protective plate, the ceramic fiber provided with the stainless steel protective plate 39 in which the end side bent portions 37 and 38 are formed at positions different from the end side bent portions 21 and 22, respectively. It is also possible to manufacture the block 40 and arrange the ceramic fiber blocks 10 and 40 so that the stacking directions of the adjacent stacked bodies 16 are different. By disposing the adjacent stacked bodies 16 so that the stacking directions thereof are different from each other, it is possible to prevent deformation due to thermal expansion of the stacked bodies 16 from overlapping in one direction.

As described above, the present invention has been described with reference to the embodiment. However, the present invention is not limited to the configuration described in the above-described embodiment, and the matters described in the scope of claims. Other embodiments and modifications conceivable within the scope are also included.
For example, the corners of any two adjacent sides of the inner wall surface forming the furnace inner surface are covered with the end side bent portion of the stainless steel protective plate, but the corner portion of any one side of the inner wall surface is made of stainless steel. You may make it cover with the edge side bending part of a protection board.

It is a perspective view of the ceramic fiber block which concerns on one embodiment of this invention. (A) is a perspective view of the laminated body and channel of the ceramic fiber block, and (B) is a side sectional view of the ceramic fiber block. It is a perspective view which shows the state before attachment of the ceramic fiber block. It is a sectional side view which shows the state which attached the ceramic fiber block inside the furnace shell. It is a perspective view which shows the state at the time of arranging the ceramic fiber block side by side. It is a top view which shows the state which concerns on the modification which attached the ceramic fiber block inside the furnace shell.

10: Ceramic fiber block, 11: Furnace shell, 12: Thermal insulation wall, 13: Inner wall surface, 14: Stainless steel protective plate, 15: Ceramic fiber blanket, 16: Laminate, 17: Channel, 18: First bolt hole , 19: Beam, 20: Fixing member, 21, 22: End side bent part, 23, 24: Projection part, 25: Connection part, 26: First stud bolt, 27: Box nut, 28: Second bolt Hole: 29: Washer, 30: Nut, 31: Second stud bolt, 32: Band, 33: Ceramic fiber blanket, 34, 35, 36: Ceramic fiber block, 37, 38: End side bent part, 39: Stainless steel Protection plate made of 40: Ceramic fiber block, 41, 42: Opening, 43: Bundling part

Claims (4)

A ceramic fiber block that is arranged side by side inside the furnace shell of the heat treatment furnace to form a heat insulating wall of the heat treatment furnace, and the inner wall surface forming the furnace inner surface of the heat insulating wall is covered with a stainless protection plate ,
A laminated body formed by continuously folding a ceramic fiber blanket, a channel provided outside the fold of the laminated body and disposed on the inside of the fold of the laminated body, to which a support member for supporting the laminated body is attached, and A box nut that penetrates through the laminated body and is fastened to the front side of the first stud bolt that is attached to the inside of the furnace shell and passes through the first bolt hole formed in the channel is provided on the base side. A ceramic fiber block comprising: a second stud bolt that passes through a second bolt hole formed in the protective plate and into which a nut is tightened . 2. The ceramic fiber block according to claim 1, wherein the inner wall surface is rectangular when viewed from the front, and a corner portion of any one side of the inner wall surface or each corner portion of any two adjacent sides is protected by the stainless steel. A ceramic fiber block which is covered with a bent portion on the end side of the plate. In the ceramic fiber block according to claim 1 or 2, wherein the area of the stainless steel protective plate viewed in front ceramic fiber blocks being larger than an area of the inner wall surface. 2. The ceramic fiber block according to claim 1 , wherein a slit-like pair of openings is formed on the surface of the stainless steel protective plate, and a binding member for bundling the laminated body passes through the pair of openings. Ceramic fiber block characterized by.

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