JPH0446355B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention is a method of inserting a ceramic fiber furnace wall into a ceramic fiber layer from the inner surface of the furnace, rotating it in either the left or right direction, and inserting the ceramic fiber into the ceramic fiber layer on the outside of the furnace. The present invention relates to a method for locking a ceramic fiber inside a furnace by locking the ceramic fiber at the inside of the furnace.

BACKGROUND ART Various methods have been devised to attach ceramic fibers to furnace casings as furnace wall insulation materials.

The basic method is to pierce a ceramic fiber through a metal pin welded vertically to the furnace casing and secure it with washers and nuts.

However, as operating temperatures rose, ceramic pins with high heat resistance or ceramic adhesives were used on the high-temperature side near the inside of the furnace.

For example, as shown in FIG. 6, only the high-temperature position can be connected to ceramics through a metal pin 2 directly welded to the furnace wall casing 1, or by connecting a pin 4 to a metal pipe 3 by screwing or other means. A method was adopted in which the stack of ceramic fibers 6 was fixed with a pin 4 or a cup 5, which was a blank pin.

However, this method has the disadvantage that the connecting portion between the metal pin and the ceramic pin is oxidized, resulting in a short service life.

Further, to the block of ceramic fiber 6 as shown in FIG. 7, another ceramic fiber block 6a is fixed inside the furnace with an adhesive 7, and also with overlapping long metal pins 2.

The latter construction method improves the reliability of the adhesive 7 by using a long metal pin 2 connected to the casing in addition to the adhesive method in order to prevent peeling between the adhesive layers due to repeated thermal history at high temperatures. There is.

However, it has the disadvantage that the temperature of the furnace escapes through the metal pin 2, and that it is necessarily expensive because it requires the use of extremely heat-resistant metal in large dimensions.

As a method to improve this, as shown in FIG. 8, the relatively hard layer 8 is fixed in the middle with a pin that reaches the casing, and another ceramic pin 9 is used to penetrate the inner ceramic fiber layer 8a. There is a method of drilling a hole 10 in 8, applying adhesive mortar to the threaded part, and screwing it in from the inside of the furnace.

Problem to be Solved by the Invention In the method shown in FIG. 8, the ceramic pin 9 is locked in the hole, but the hole 10 is provided with a female thread inside, and the ceramic pin 9 and the female thread are connected by a screw mechanism. It is not a tight mechanical connection; it is just a hole, and the holding force relies solely on the adhesive force of the mortar.

For this reason, even though layer 8 is made of a relatively hard layer, the area around hole 10 is not hard enough to firmly hold mortar, and the adhesiveness and holding power of ceramic pins are still unreliable. There is. Moreover, you have to go to the trouble of using a relatively hard layer, specifically an expensive ceramic fiberboard hardened with an inorganic binder, and hard items like board are susceptible to heat shrinkage during use at high temperatures. Since cracks are likely to occur through the holes 10, the ceramic pins 9 cannot be locked.

In other words, there are problems in that it is not possible to reliably and directly engage inexpensive and flexible blankets or felts, or products made from them.

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a method for locking ceramic fibers that has high locking reliability at high temperatures and can reliably and directly lock flexible ceramic fibers together. The purpose is

Means for Solving the Problems Therefore, in order to achieve this object, the present invention provides a ceramic fiber locking method for locking a ceramic fiber to another ceramic fiber, in which one end of the shaft rod is A holding part for the ceramic fiber is provided, and a chevron-shaped locking protrusion is provided on the shaft rod.A locking pin made entirely of ceramics is inserted into the ceramic fiber from the locking protrusion, and the chevron-shaped locking pin is inserted into the ceramic fiber. The gist of this invention is a method for locking a ceramic fiber that rotates in either the left or right direction around a shaft rod to a position that does not overlap the position of a locking protrusion.

Function: After inserting the locking protrusion 24 through the innermost high-temperature ceramic fiber layer 15 and further inserting it to the outer soft low-temperature ceramic fiber layer 14, the locking pin 16 is inserted around the shaft rod 22. The high-temperature ceramic fiber layer 15 is locked to the low-temperature ceramic fiber layer 14 by turning it in either the left or right rotation direction.

The rotation angle at this time is appropriately selected so as to select and stop at a position other than the place where the locking protrusion 24 first hit.

Example Examples of this invention will be described.

First Embodiment A first embodiment of the present invention will be described with reference to FIG.

In the figure, a metal pin 12 is vertically attached to the furnace casing 1 in advance using a welding machine. This pin 12 is pierced with four layers of low-temperature ceramic fiber blankets having a thickness of, for example, 25 mm.

These constitute a low-temperature ceramic fiber layer 14 with a thickness of 100 mm, which is fixed with washers and nuts 13. (It is omitted in the figure for the sake of simplicity.) In this way, the low-temperature ceramic fiber layer 14 is previously provided on the furnace casing 1.

The surface of the low-temperature ceramic fiber layer 14 is covered with a high-temperature ceramic fiber layer 15 via a locking pin 16. The high-temperature ceramic fiber layer 15 is a block made of a high-temperature ceramic fiber blanket having a thickness of, for example, 50 mm.

The locking pin 16 has a structure as shown in FIGS. 2 and 3. That is, one end of the shaft rod 22 is provided with a holding portion 21 of the high-temperature ceramic fiber layer 15, and the other end of the shaft rod 22 is provided with a chevron-shaped locking protrusion 24.

The shaft rod 22 has a circular cross section as shown in FIG. 3B. The holding portion 21 has a circular cross section with a larger diameter than the shaft rod 22, as shown in FIG. 3C.

The locking projection 24 has a rhombic cross section as shown in FIG. 3A.

The maximum width of the locking protrusion 24 in the A-B cross section is
The locking protrusion 24 is larger than the maximum diameter of the shaft rod 22, has a large cross section, and has a flattened tip.

The holding portion 21 is provided with a groove 20 into which a tool (not shown) is inserted to turn the locking pin 16. (See Figure 3D and Figure 2) From the tip of the locking protrusion 24 to the end surface 2 of the holding portion 21
The length up to 1a is, for example, 100 mm, and the length of the locking projection 24 is 20 mm.

That is, the locking pin 16 has a length such that the locking protrusion 24 penetrates the high-temperature ceramic fiber layer 15 and reaches into the low-temperature ceramic fiber layer 14.

This locking pin 16 is entirely made of alumina ceramics, but it can also be made of other highly refractory ceramics such as silicon nitride, mullite, zirconia, and silicon carbide.

Actually, when attaching the ceramic fiber layer 15 for high temperature use, the locking pin 16 is first attached to the ceramic fiber layers 15, 15 for high temperature use and for low temperature use.
Push it to 4.

After pressing the high temperature ceramic fiber layer 15 until the pressing part 21 comes into contact with the surface, the groove 20
Insert a tool such as a screwdriver and rotate it, for example, 90 degrees to the left or right.

By doing this, the locking protrusion 24 is attached to the shaft rod 2.
It rotates around center point 2 and cuts through the low-temperature ceramic fiber layer 14, while being able to securely lock onto the same layer 14 without getting wedged.

By appropriately selecting the position at which the rotation is stopped, the locking pin 16 requires a large resistance force to be pulled out. Therefore, the high temperature ceramic fiber layer 15 sandwiched between the locking projection 24 and the holding portion 21 is firmly locked by the locking pin 16.

Second Example In the first example, a high temperature ceramic fiber blanket was used as the high temperature ceramic fiber layer.

Instead of this blanket, the high-temperature ceramic fiber layer may be constructed from a relatively hard ceramic fiber board.

In this case, the locking pin 36 of the second embodiment shown in FIGS. 4A and 4B can be used.

This locking pin 36 is similar to the locking protrusion 2 of the first embodiment.
It has almost the same shape as 4. A knob 30 is provided on the presser portion 31.

The holding portion 31, the shaft rod 32, and the locking protrusion 34 are made of the ceramics used in the first embodiment.

The locking protrusion 34 is fitted and fixed to the shaft rod 32.

When using the locking pin 36, make a hole in advance at the position where the locking pin 36 will be inserted, so that the locking protrusion 34 can easily pass through, and insert the locking pin 3 through this hole.
6 and rotate it, for example, 90 degrees around the shaft rod 32. By doing so, the high-temperature ceramic fiber layer can be firmly locked to the low-temperature ceramic fiber layer.

Third Embodiment The low-temperature ceramic fiber layer uses a block made of a low-temperature ceramic fiber blanket instead of the low-temperature ceramic fiber blanket of the first embodiment, and the high-temperature ceramic fiber layer uses a block made of a high-temperature ceramic fiber blanket. A high temperature ceramic fiber blanket is used instead of a block made of fiber blanket.

In this case, the locking pin 46 of the third embodiment shown in FIGS. 5A and 5B can be used.

The holding portion 41 of the locking pin 46 is similar to that of the first embodiment and has a groove 40. However, the other end (tip) and side surface of the shaft rod 42 have chevron-shaped locking protrusions 4.
A plurality of 4 are provided in a staggered pattern. This locking protrusion 44 is flat.

In use, the locking pin 46 is inserted into the high-temperature ceramic fiber layer and rotated, for example, 90 degrees about the shaft rod 42 to lock the high-temperature ceramic fiber layer.

The locking projection 44 at the tip is locked to the low-temperature ceramic fiber layer, while the other locking projections 44 are locked to the high-temperature ceramic fiber layer.

However, the present invention is not limited to the embodiments already described.

For example, in the first embodiment, the groove 20 may be replaced with a tab (as shown in FIG. 4A). Further, neither a knob nor a groove may be provided.

In the second embodiment, the knob 30 may be replaced by a groove. Further, neither a knob nor a groove may be provided.

In the third embodiment, a knob may be provided instead of the groove 40. Further, neither a knob nor a groove may be provided. The second and third embodiments may be entirely made of ceramics.

Effects of the Invention As is clear from the above explanation, according to the method of locking ceramic fibers of the present invention,
Two or more ceramic fiber layers, that is, soft ceramic fiber layers, can be directly and tightly secured to each other without intervening a hard layer. Further, two or more ceramic fiber layers can be locked by a simple rotation operation from only one direction.

Furthermore, by making the entire locking pin from ceramic, it can withstand use at extremely high temperatures.

[Brief explanation of drawings]

FIG. 1 is a sectional view showing how the locking pin of the first embodiment of the present invention is used, FIG. 2 is a front view of the first embodiment of FIG. 1, and FIG. 3B is a sectional view along CD in FIG. 2, FIG. 3C is a sectional view along E-F in FIG. 2, and FIG. 3D is a bottom view of the presser part. Figure 4A is
A front view showing a second embodiment of the locking pin of the present invention, FIG. 4B is a bottom view of the holding portion of the second embodiment, and FIG. 5A is a front view showing the third embodiment of the present invention. FIG. 5B is a bottom view of the presser portion of the third embodiment, and FIGS. 6 to 8 are views showing how the conventional locking pin is used. 14... Ceramic fiber layer for low temperature, 15
...High temperature ceramic fiber layer, 16,3
6, 46... Locking pin, 24, 34, 44... Locking protrusion, 21, 31, 41... Holding portion, 22,
32, 42... Axis rod.

Claims (1)

[Claims] 1. In a ceramic fiber locking method for locking one ceramic fiber to another ceramic fiber, one end of the shaft rod is provided with a holding portion of the ceramic fiber, the shaft rod is provided with a chevron-shaped locking protrusion, Insert the locking pin, which is made entirely of ceramics, into the ceramic fiber from the locking protrusion, and rotate it in either the left or right direction around the shaft until it does not overlap with the chevron-shaped locking protrusion when inserted. How to lock ceramic fiber.