JP2002098303A - Repairing method for furnace wall - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a repairing method for a furnace wall wherein dismantlement and repair of a furnace wall protective layer that is changed in properties and worn owing to use over a long period of time are simply achieved without damaging the furnace wall, etc. SOLUTION: Among refractory furnace wall protective layer 3 formed of an inner peripheral surface of a furnace wall 1 of an incinerator a normal layer 33 is left behind, and layers 31, 32 changed in quality on the surface are decomposed with a sand blast method. Hereby, a tip end of a stud pin 2 welded onto the inner peripheral surface of the furnace wall 1 including the surface of a boiler tube 10 is exposed, and a repairing stud pin 4 is joined with the former tip end of the stud pin, and thereafter a new furnace wall protective layer 34 is formed on the remaining furnace wall protective layer 33.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for repairing a furnace wall, and more particularly to a method for easily disassembling and repairing a furnace wall protective layer that has been deteriorated or worn due to long-term use without damaging the furnace wall and the like. The present invention relates to a method of repairing a furnace wall that can be performed.

[0002]

2. Description of the Related Art Conventionally, incinerators used for incinerating refuse and the like have their furnace walls constantly exposed to high temperatures and combustion gases generated by incineration of refuse and the like. A boiler tube through which cooling water flows along the furnace wall to protect the furnace wall from heat and maintain a constant temperature, and a refractory furnace on the inner peripheral surface of the furnace wall including the surface of the boiler tube A wall protection layer is formed.

The furnace wall protective layer is made of, for example, castable material of alumina or silicon carbide, plastic material, etc., but is always exposed to high temperature and combustion gas generated by incineration of refuse. For,
It is deteriorated, deteriorated, and further worn due to erosion, peeling, and the like. Therefore, its useful life varies depending on the usage of the incinerator, but is generally said to be 2 to 5 years.

In this case, the refractory furnace wall protective layer used for a long period of time is deteriorated and deteriorated by being constantly exposed to high temperature and combustion gas, the surface deteriorated layer, the infiltrated deteriorated layer into which impurities of the lower layer have penetrated, Furthermore, the lower layer is constituted by a normal layer in which a predetermined quality is ensured, but the normal layer that prevents the influence of high temperature and combustion gas on the furnace wall including the boiler tube exists. The furnace wall protection layer is updated.

[0005]

By the way, the renewal of the furnace wall protective layer is performed by manually cutting the old furnace wall protective layer using a tool such as an air pick, and then renewing the new furnace wall protective layer. It is performed by forming a wall protection layer, but this renewal work has the following problems. When shaving the old furnace wall protection layer, it is not possible to cut only the altered layer, so it is necessary to cut the entire old furnace wall protection layer including the normal layer, and use the normal layer where the required quality is secured. And the amount of furnace wall protective material required to form a new furnace wall protective layer and the amount of debris generated by dismantling the old furnace wall protective layer increase, and the cost of the furnace wall protective material itself increases. In addition, the cost of dismantling scraps is high. In particular, it is expected that demolition debris from the furnace wall protection layer containing demolition debris contaminated by dioxin, etc., will be required to be landfilled at a controlled final disposal site in the future, and disposal costs for demolition debris will be required. Will take more. When shaving the entire old furnace wall protective layer including the normal layer, the furnace wall including the boiler tube and the stud pins welded to the inner peripheral surface thereof are easily damaged, and it takes time and money to repair it. The work of shaving the old furnace wall protection layer takes a long time, and the worker is exposed to a poor working environment in which harmful substances such as dust and dioxin are present for a long time.

The present invention has been made in view of the above-mentioned problems associated with the renewal of the furnace wall protection layer, and has been developed to disassemble and repair the furnace wall protection layer which has been deteriorated or worn due to long-term use without damaging the furnace wall and the like. It is an object of the present invention to provide a method of repairing a furnace wall which can be easily performed.

[0007]

In order to achieve the above object, a method for repairing a furnace wall according to the present invention is directed to a method for repairing a normal layer of a fire-resistant furnace wall protective layer formed on an inner peripheral surface of a furnace wall of an incinerator. By disassembling the deteriorated layer on the surface by sandblasting, the tip of the stud pin welded to the inner peripheral surface of the furnace wall including the surface of the boiler tube is exposed, and the remaining furnace wall protective layer A new furnace wall protective layer is formed thereon.

[0008] This method of repairing the furnace wall is carried out by leaving a normal layer of a predetermined quality among the refractory furnace wall protective layers formed on the inner peripheral surface of the furnace wall of the incinerator. By dismantling the deteriorated layer by sandblasting method,
Since the tip of the stud pin welded to the inner peripheral surface of the furnace wall including the surface of the boiler tube is exposed, and then a new furnace wall protective layer is formed on the remaining furnace wall protective layer, Disassembly and repair of the furnace wall protective layer that has been altered or worn due to long-term use can be easily performed without damaging the furnace wall and the like.

In this case, the repair stud pin can be added to the stud pin welded to the inner peripheral surface of the furnace wall including the surface of the boiler tube.

[0010] Thus, compared with the case where the stud pins are newly welded to the inner peripheral surface of the furnace wall, a load is not applied to the furnace wall, and the furnace wall and the new furnace wall protective layer can be sufficiently provided. Adhesive strength can be easily secured.

[0011] Further, from the demolition waste obtained by dismantling the furnace wall protective layer,
The blast material can be collected and recycled.

As a result, the amount of blast material used can be reduced, and the cost required for renewing the furnace wall protective layer can be reduced. In addition, the amount of debris generated is reduced, and the cost required for dismantling debris is reduced. Can be reduced.

[0013] Further, the operation of the incinerator can be restarted in a state where the demolition waste obtained by dismantling the furnace wall protective layer remains in the incinerator.

[0014] Thus, the dismantled debris obtained by dismantling the furnace wall protective layer containing the dismantled debris contaminated with dioxin and the like is detoxified and discharged together with incineration ash and slag generated when incinerating waste and the like. Not only does the labor and cost required for disposal of the waste become unnecessary, but also the dismantling waste can be safely processed.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a method for repairing a furnace wall according to the present invention will be described below with reference to the drawings.

As shown in FIG. 4 (a), a water tube incinerator used for incinerating refuse and the like protects the furnace wall 1 from high temperature and combustion gas generated by incineration of refuse and the like, and maintains a constant temperature. A boiler tube 10 through which cooling water flows is provided along the furnace wall 1 and the inner peripheral surface of the furnace wall 1 including the surface of the boiler tube 10 is made of, for example, castable alumina or silicon carbide. The refractory furnace wall protective layer 3 made of a material, a plastic material, or the like is formed. The thickness D of the furnace wall protective layer 3
Depends on the usage of the incinerator, etc.
It is formed to a thickness of 0 to 80 mm. In this case, the inner peripheral surface of the furnace wall 1 including the surface of the boiler tube 10 (in this embodiment, the boiler tube 10 is used) so that a sufficient adhesive strength between the furnace wall 1 and the furnace wall protective layer 3 can be secured. Stud pins 2, for example, 330 pins / m ²
Welding is performed at a ratio of about 3%, and the furnace wall protective layer 3 is formed thereon. In addition, in a portion exposed to a particularly high temperature, such as a combustion chamber side wall, as shown in FIG. 4B, the stud pin 2 is coated with a refractory material in order to prevent the stud pin 2 from being damaged by melting. The formed cap 2A can be covered.

Meanwhile, the furnace wall protective layer 3 of the incinerator is constantly exposed to the high temperature and the combustion gas generated by the incineration of dust and the like, so that it is deteriorated and deteriorated, and is further worn away due to erosion and peeling. . Thus, the refractory furnace wall protective layer 3 used for a long period of time, as shown in FIG.
It is composed of a deteriorated and deteriorated surface layer 31 constantly exposed to high temperature and combustion gas, a deteriorated and deteriorated layer 32 into which impurities below have penetrated, and a normal layer 33 below which a predetermined quality is secured. However, it is necessary to update the furnace wall protection layer 3 while the normal layer 33 for preventing the high temperature and the influence of the combustion gas from being present on the furnace wall 1 including the boiler tube 10.

In renewing the furnace wall protective layer 3, here, a conventional worker employs a tool such as an air pick, instead of manually cutting the old furnace wall protective layer by sand blasting. As shown in FIG. 1 (2), a fire-resistant furnace wall protective layer 3 formed on the inner peripheral surface of a furnace wall 1 of an incinerator.
Of these, the normal layer 33 having a thickness of about several tens of mm is left so that the altered layer on the surface, specifically, the altered layer 3
1 and the infiltrated affected layer 32 are dismantled, thereby exposing the tip of the stud pin 2 welded to the inner peripheral surface of the furnace wall 1 including the surface of the boiler tube 10. Then, if necessary, an appropriate surface treatment such as spraying of a binder solution is performed on the remaining normal layer 33 (layer thickness: D2) which is the old furnace wall protection layer. ), A new furnace wall protection layer 34 (layer thickness: D1)
By forming by casting (casting) or spraying, the thickness D of the layer is 50 to 80 mm as a whole.
Is formed.

In this case, as the blasting material used in the sand blasting method, silica sand generally used as a blasting material can be used, but the furnace wall protective layer 3 is made of a castable material such as alumina or silicon carbide, a plastic material or the like. In view of the fact that it is further hardened by being exposed to high temperature, it is made of alumina (brown alumina) or silicon carbide based high average particle diameter of about 0.5 to 3 mm. It is desirable to use a blast material in terms of work efficiency (the dismantling speed can be improved to about 5 times as compared with the case where silica sand is used).

When the protective furnace material 3 has an extremely hard surface layer on the side wall of the combustion chamber or the like, only the surface layer is
The old furnace wall protection layer 3 can be dismantled by shaving using a tool such as an air pick or the like, and then switching to the sand blasting method so that the normal layer 33 of the furnace wall protection layer 3 remains.

As described above, by applying the sandblasting method to the renewal of the furnace wall protective layer, there are the following advantages. In the case of shaving the old furnace wall protection layer, since it is possible to sequentially dismantle the furnace wall protection layer from the surface part to the deep part,
Only the deteriorated layers 31 and 32 can be accurately cut (the external appearance can be visually confirmed), so that the old furnace wall protective layer can be cut while leaving the normal layer 33, and a predetermined quality can be obtained. The secured normal layer 33 can be utilized, and the amount of the furnace wall protective material required to form the new furnace wall protective layer 34 and the amount of debris generated by dismantling the old furnace wall protective layer are required. Therefore, the cost of the furnace wall protection material itself and the cost of dismantling debris can be reduced. Since the old furnace wall protection layer can be cut away while leaving the normal layer 33, the furnace wall 1 including the boiler tube 10 is not exposed, and the stud pins 2 welded to the furnace wall 1 including the boiler tube 10 and the inner peripheral surface thereof. Is less susceptible to damage, reducing the time and cost required for repair. It can efficiently cut the old furnace wall protection layer, prevent workers from being exposed to poor working environment for a long time in the presence of harmful substances such as dust, dioxin, etc. In addition, the operation can be easily automated by mechanization using a robot or the like, whereby the influence of harmful substances such as dust and dioxin on workers can be further reduced. Since the surface of the normal layer 33, which is the remaining old furnace wall protective layer, has a rough surface, a sufficient adhesive strength between the new and old furnace wall protective layers 33, 34 can be easily secured.

In this case, it is possible to collect the blast material by sieving the dismantling debris obtained by disassembling the furnace wall protective layer, and to reuse the collected blast material. As a result, it is possible to reduce the amount of blast material used, reduce the cost required for renewing the furnace wall protective layer, reduce the amount of demolition waste, and reduce the cost required for processing demolition waste. Can be done.

In addition, the debris obtained by dismantling the furnace wall protective layer may remain in the incinerator without being collected (fall into the ash pit), and the operation of the incinerator may be restarted in this state. it can. As a result, the demolition debris obtained by dismantling the furnace wall protective layer containing demolition debris contaminated with dioxin, etc., is detoxified and discharged together with incineration ash and slag generated when incinerating garbage, etc. In addition to eliminating the labor and cost required for the disassembly, it is possible to safely dismantle debris.

By the way, the stud pins 2 welded to the inner peripheral surface of the furnace wall 1 including the surface of the boiler tube 10 (only the surface of the boiler tube 10 in this embodiment) are the same as those of the furnace wall protective layer 3. Since it is constantly exposed to high temperature and combustion gas generated by incineration of refuse through the furnace wall protective layer 3, it is often worn by melting. In such a case, before forming a new furnace wall protection layer 34, as shown in FIG. 2 (2), the tip of the worn stud pin 2 is exposed by at least about 1 mm. By carrying out the method, it can be performed without any difficulty, and the pre-processing of the exposed stud pins 2 for the post-process is not necessary.) The repair stud pins 4 are welded to the worn stud pins 2. Refilling may then be performed to form a new furnace wall protection layer 34. Accordingly, compared to the case where the stud pins are newly welded to the inner peripheral surface of the furnace wall, a load is not applied to the furnace wall 1 including the boiler tube 10, and the furnace wall 1 and a new furnace wall protection are not provided. A sufficient adhesive strength of the layer 34 can be easily secured.

FIG. 3 shows an example of a method for welding a repair stud pin 4 to the worn stud pin 2. First, as shown in FIG.
A spark shield S attached to a stud welding machine (not shown) is installed so as to surround the outer periphery of the spark shield S. Next, FIG.
As shown in (2) and FIG. 3 (3), the repair stud pin 4 loaded into the stud welding machine is brought into contact with and pressed against the tip of the worn stud pin 2 and the argon gas is introduced into the spark shield S. By injecting a welding current from a stud welding machine while injecting an inert shielding gas such as carbon dioxide gas, the repair stud pin 4 is stud welded to the worn stud pin 2 as shown in FIG. S
CG welding method (see Japanese Patent No. 2777778) can be used. The SCG welding method includes an arc stud (ferrule) welding method and a capacitor welding method (CD
A welding method utilizing the advantages of the above-described welding method, by injecting an inert shield gas into the spark shield S instead of using a ferrule, it is possible to improve welding accuracy while securing welding strength. .

As described above, the method for repairing a furnace wall according to the present invention is described below.
Although the description has been given based on the embodiment, the present invention is not limited to the configuration described in the above embodiment, and the configuration can be appropriately changed without departing from the gist of the invention.

[0027]

According to the method for repairing a furnace wall of the present invention, of the fire-resistant furnace wall protective layers formed on the inner peripheral surface of the furnace wall of an incinerator, a normal layer having a predetermined quality is secured. By disassembling the deteriorated layer on the surface by sandblasting so as to leave it, the tip of the stud pin welded to the inner peripheral surface of the furnace wall including the surface of the boiler tube is exposed, and then the remaining furnace wall protection Since a new furnace wall protective layer is formed on the layer, it will be deteriorated by long-term use,
Disassembly and repair of the worn furnace wall protection layer can be easily performed without damaging the furnace wall and the like, and problems associated with the replacement of the furnace wall protection layer can be solved.

Further, the stud pin for repair is added to the stud pin welded to the inner peripheral surface of the furnace wall including the surface of the boiler tube, so that the stud pin is newly welded to the inner peripheral surface of the furnace wall. As compared with the case where a furnace wall is provided, a load is not applied to the furnace wall, and a sufficient adhesive strength between the furnace wall and the new furnace wall protective layer can be easily secured.

Further, from the demolition waste obtained by disassembling the furnace wall protective layer,
By collecting and recycling the blast material, it is possible to reduce the amount of blast material used, reduce the cost of renewing the furnace wall protective layer, and reduce the amount of debris generated. In addition, the cost required for dismantling scraps can be reduced.

In addition, by restarting the operation of the incinerator while the debris obtained by dismantling the furnace wall protective layer remains in the incinerator, the furnace wall protective layer containing the debris contaminated with dioxin or the like can be obtained. The demolition debris is detoxified and discharged together with the incineration ash and slag generated when incinerating garbage, etc., which not only eliminates the labor and cost required for dismantling debris, but also makes demolition debris safe. Can be processed.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing a construction order of a first embodiment of a method for repairing a furnace wall according to the present invention.

FIG. 2 is an explanatory view showing a construction order of a second embodiment of the method for repairing a furnace wall according to the present invention.

FIG. 3 is an explanatory view showing a welding method of a repair stud pin.

FIG. 4 is a sectional view of a furnace wall of the water tube incinerator.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Furnace wall 10 Boiler tube 2 Stud pin 2A cap 3 Old furnace wall protective layer 31 Surface damaged layer 32 Infiltrated damaged layer 33 Normal layer 34 New furnace wall protective layer 4 Repair stud pin

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI theme coat ゛ (Reference) F27D 1/10 F27D 1/10 1/12 1/12 F 1/16 1/16 A FT (72) Inventor Takashi Sumiyoshi 5-13-4 Esakacho, Suita-shi, Osaka Japan Stud Welding Co., Ltd. Osaka Sales Office (72) Inventor Hiroshi Nagai 2-6-17 Kitahama, Chuo-ku, Osaka-shi, Osaka OSE Osaka Branch Office (72) Inventor Takashi Ogiya 4-15-6 Yamate-minami, Kyotanabe-shi, Kyoto (72) Inventor Keisuke Hashimoto 2-7-1-7-507, Miyakojima-Nantori, Miyakojima-ku, Osaka-shi, Osaka F-term (reference) 4K051 AA03 AB03 GA05 GA08 GA09 HA08 LA01 LC01 LH00

Claims (4)

[Claims] 1. A boiler comprising: disassembling a deteriorated layer on the surface by a sandblasting method so that a normal layer remains in a refractory furnace wall protective layer formed on an inner peripheral surface of a furnace wall of an incinerator. Furnace characterized in that the tip of a stud pin welded to the inner peripheral surface of the furnace wall including the surface of the tube is exposed, and a new furnace wall protective layer is formed on the remaining furnace wall protective layer. How to repair a wall. 2. The method for repairing a furnace wall according to claim 1, wherein a stud pin for repair is added to a stud pin welded to an inner peripheral surface of the furnace wall including a surface of the boiler tube. 3. The method for repairing a furnace wall according to claim 1, wherein the blast material is recovered from the demolition scraps obtained by disassembling the furnace wall protection layer, and the blast material is recycled. 4. The furnace wall according to claim 1, wherein the operation of the incinerator is restarted in a state where the debris obtained by dismantling the furnace wall protective layer remains in the incinerator. Repair method.