JP2020085099A - Telescopic joint, anticorrosion method for telescopic joint, and maintenance method for telescopic joint - Google Patents

Abstract

To provide a telescopic joint capable of excellently preventing corrosion of a metal member due to drain or corrosive gas without adversely affecting cost and workability.SOLUTION: A telescopic joint 1 for connecting a pair of ducts 3 and 5 through which high-temperature fluid flows in an expandable and contractable manner, has a pair of joint flanges 7a, 9a for connecting with the ducts, and metal frame parts 7b, 9b for holding a bellows 11 and heat insulating materials 13, 15, 17. On the fluid-side inner surfaces of the frame parts 7b and 9b, there is provided an anticorrosion layer 52 comprising an anticorrosion paint undercoat anticorrosion coating, an anticorrosion tape and a topcoat anticorrosion coating in this order.SELECTED DRAWING: Figure 3

Description

The present invention relates to an expansion joint and an anticorrosion method applicable to maintenance of the expansion joint.

Conventionally, expansion joints have been used for the purpose of absorbing thermal expansion and vibration of the duct itself at the connecting part of the duct that transfers fluid such as exhaust gas discharged from combustion devices such as thermal power plants, steel plants, and refuse incinerators. It is used.
FIG. 1 is a perspective view showing an example of an expansion joint.
The expansion joint 10 shown in FIG. 1 connects a pair of ducts (not shown) through which a high temperature fluid flows so as to be expandable and contractable, and includes a pair of joint flange portions 7a and 9a and a metal frame. It is provided with parts 7b and 9b and a cylindrical bellows 11. The pair of joint flange portions 7a and 9a and the bellows 11 are configured in a cylindrical shape as shown in FIG. 1 or in a rectangular tube shape not shown in accordance with the shape of the duct pipe of the object to which the joint is applied. It has been done. The bellows 11 has dimensions necessary for the distance between both ends of the expansion joint (connection surface with the duct pipe) to be sufficiently longer than the distance between the duct pipes to be connected. By mounting the expansion joint between the ducts with the bellows 11 loosened, thermal expansion/contraction of the duct system, axial displacement, vibration, etc. can be absorbed.

FIG. 2 is a vertical sectional view of the expansion joint. The expansion joint 10 is used, for example, in a gas turbine plant, and a high-temperature fluid having a temperature of about 400° C. flows during operation in the pair of ducts 3 and 5 which are a pair of connected members. For this reason, in order to protect the bellows required for maintaining airtightness from abrasion due to dust contained in heat and fluid, a complicated protective structure using a heat insulating material and baffles is provided. The expansion joint 10 is disposed between the upstream duct 3 and the downstream duct 5, and has a pair of flanged joint bodies 7 and 9, and a cylindrical bellows 11 that connects the pair of joint bodies 7 and 9. A plurality of heat insulating materials 13, 15, 17, 19, 21 arranged inside the bellows 11 are provided. Each of the pair of joint bodies 7 and 9 is formed of a tubular member that connects to the corresponding duct 3 or 5. A joint flange portion 7 a is formed on the upstream side of the first joint body 7. On the other hand, a similar duct flange portion 3a is also formed on the downstream side of the upstream duct 3, and the first joint body 7 is formed by connecting the joint flange portion 7a and the duct flange portion 3a with the fastening means 23 or the like. Is hermetically connected to the upstream duct 3. Further, similar joint flange portions 9a and duct flange portions 5a are formed on the downstream side of the second joint body 9 and the upstream side of the downstream duct 5, and these joint flange portions 9a and duct flange portions 5a are fastened. The second joint body 9 is air-tightly connected to the downstream duct 5 by being connected by means 23 or the like.

On the outer surfaces of the first and second joint bodies 7 and 9, annular metal frame portions 7b and 9b are erected by welding. The upstream end and the downstream end of the bellows 11 are engaged with the frame portions 7b and 9b, respectively. Further, pressing plates 7c and 9c are arranged outside the upstream and downstream ends of the bellows 11 engaged with the frame portions 7b and 9b. With the upstream end and the downstream end of the bellows 11 being sandwiched between the frame portions 7b and 9b and the holding plates 7c and 9c, these frame portions and the holding plate are connected by the fastening means 25. In this way, the bellows 11 is fixed between the pair of joint bodies 7 and 9. The pair of pressing plates 7c and 9c are connected by a shipping bolt 27 via L-shaped metal fittings 7d and 9d fixed by fastening means 25. The shipping bolt 27 is used to set the expansion joint to the mounting dimension, and is removed after the connection between the ducts 3 and 5 is completed.

The heat insulating material 13 is arranged on the outermost side of the plurality of heat insulating materials provided inside the bellows 11, and further the first stretchable heat insulating material 15 and the second stretchable heat insulating material 17 are arranged inward from the heat insulating material 13. It is arranged. These heat insulating materials 13, 15 and 17 are located inside the bellows 11 and at the same time outside the joint bodies 7 and 9, and are surrounded by the pair of frame portions 7 b and 9 b and the bellows 11.

Further, an exposed heat insulating material 19 is arranged inside the second expandable heat insulating material 17, and a pair of fixed heat insulating materials 21 is arranged inside the exposed heat insulating material 19. These heat insulating materials 19 and 21 are located inside the bellows 11 and, at the same time, inside the joint bodies 7 and 9. In addition, the pair of fixed heat insulating materials 21 are provided separately on the upstream side and the downstream side, leaving a central portion in the flow direction of the expansion joint 10. Thereby, the exposed heat insulating material 19 is exposed to the flow path between the pair of fixed heat insulating materials 21, that is, in the central portion in the flow direction. A stud bolt 29 is erected from the lower surface of each of the pair of joint bodies 7 and 9 toward the inside, that is, toward the flow path axis. These stud bolts 29 penetrate the exposed heat insulating material 19 and the fixed heat insulating material 21, and the tips thereof project from the inner peripheral surface of the fixed heat insulating material 21. On the other hand, the stud bolts 29 are also erected from the upper surface of each of the pair of joint bodies 7 and 9 toward the outside, that is, in the direction opposite to the flow path axis side, and fix the heat insulating materials 13, 15, and 17. Further, a heat insulating material cover 31 is provided around each fixed heat insulating material 21, and each heat insulating material cover 31 is fixed by a nut screwed to the tip of the stud bolt 29. A baffle 33 is attached to the heat insulating material cover 31 on the upstream side.

The basic structure of the bellows 11 is, for example, a seal layer made of polytetrafluoroethylene (PTFE) from the fluid side flowing through the inside, a reinforcement layer on the outside air side (the side farther from the fluid, that is, the radial outside) than the seal layer, and further It is composed of three elements: an outer skin layer provided on the outside air side, and a protective layer is provided further on the fluid side of the seal layer, if necessary. The heat insulating materials can reduce the thermal influence on the bellows 11 and prolong the life of the bellows 11. Furthermore, by adopting such a structure, even when the bellows material and the heat insulating material are renewed, the metal members such as the flange and the frame portion remain as they are, and only the bellows material and the heat insulating material need to be renewed. Are better.

However, in an expansion joint using a heat insulating material, when an acidic and high temperature internal fluid such as combustion gas enters the bellows 11 side, the gas temperature lowers to the acid dew point in the portion near the bellows 11 due to the heat insulating material. However, there is a problem that the internal fluid becomes acidic drain and corrodes the metal members such as the frame portions 7b and 9b.

Therefore, as a method of preventing the corrosion of the metal member due to such an acid drain, conventionally known methods include the use of corrosion-resistant steel and coating with an anticorrosive paint. However, special corrosion-resistant steel is difficult to process, and large-sized ones are too costly to be realistic.Coating with anticorrosion paint is not suitable for applications such as expansion joints where the temperature difference between operating and stopping is severe. There is a problem that cracks and peeling occur due to failure to follow the expansion and contraction of. Further, a method of preventing the corrosive substance from entering the gap between the flange and the bellows (Patent Document 1), a method of discharging the drain accumulated inside the expansion joint (Patent Document 2), and the like have been devised. The intrusion prevention mechanism has the problem that the structure of the expansion joint becomes complicated and maintenance is complicated.Therefore, although the drain discharge method can be expected to prevent corrosion due to drain, it has reached the drain level. There was a problem that corrosion and thinning occurred due to no acidic gas.

JP-A-63-225786 JP, 10-288291, A

Therefore, an object of the present invention is to provide an expansion joint that can favorably prevent corrosion of a metal member due to drainage or corrosive gas without adversely affecting cost and workability, and a corrosion prevention method and maintenance method applicable to maintenance thereof. To do.

As a result of earnest studies by the present inventor, as a result of applying the heat-resistant anticorrosive paint, which has been conventionally used for exteriors such as outdoor steam pipes and chimney exhausts, for the purpose of salt damage prevention, etc. Then, they found that the above problems can be solved by forming an anticorrosive layer laminated with an inorganic impregnated tape, and completed the present invention.
That is, the present invention is as follows.
1. An expansion joint that expandably connects between a pair of ducts through which a high-temperature fluid flows,
The expansion joint has a pair of flanges for connecting to the duct, and a metal frame portion that holds a bellows and a heat insulating material,
An expansion joint, wherein an inner surface of the frame portion on the fluid side is provided with an anticorrosion layer including an undercoating anticorrosion coating, an anticorrosion tape, and a topcoat anticorrosion coating in this order.
2. 2. The expansion joint according to 1, wherein the anticorrosion tape is obtained by impregnating an inorganic fiber woven fabric with the same paint as the paint used for the undercoating anticorrosion coating and/or the topcoat anticorrosion coating.
3. 3. The expansion joint according to 2 above, wherein the inorganic fiber woven fabric is a glass fiber woven fabric or an alumina fiber woven fabric.
4. The coating used for the undercoating anticorrosion coating and the topcoat anticorrosion coating contains at least a heat-resistant silicone resin, a rust preventive pigment, a coloring pigment and an extender pigment, characterized in that they are dispersed in an organic solvent or water. The expansion joint according to any one of 1 to 3.
5. The expansion joint according to any one of the above 1 to 4, wherein a drain discharge structure is provided in at least a part of a portion on the lower side where the drain is likely to accumulate during installation.
6. A method of connecting a pair of ducts through which a high-temperature fluid flows so as to be able to expand and contract, a method of preventing corrosion of expansion joints,
The expansion joint has a pair of flanges for connecting to the duct, and a metal frame portion that holds a bellows and a heat insulating material,
An anticorrosion method for expansion joints, comprising the step of providing an anticorrosion layer comprising an undercoating anticorrosion coating, an anticorrosion tape and an overcoat anticorrosion coating in this order on the fluid-side inner surface of the frame portion.
7. A method of connecting a pair of ducts through which a high-temperature fluid flows so that it can expand and contract, a corrosion prevention method applied to maintenance of expansion joints in use or after use.
The expansion joint has a pair of flanges for connecting to the duct, and a metal frame portion that holds a bellows and a heat insulating material,
An anticorrosion method for expansion joints applicable to maintenance, comprising the step of providing an anticorrosion layer comprising an undercoating anticorrosion coating, an anticorrosion tape and an overcoat anticorrosion coating in this order on the fluid side inner surface of the frame portion.

The expansion joint of the present invention is for connecting a pair of ducts through which a high-temperature fluid flows so as to expand and contract, and a pair of flanges for connecting with the duct, and a metal holding a bellows and a heat insulating material. And a frame portion made of, and the fluid side inner surface of the frame portion is provided with an undercoating anticorrosion coating, an anticorrosion layer provided with an anticorrosion tape and a topcoat anticorrosion coating in this order, so that a flange easily corroding or The inner surface of the frame is protected by the anticorrosion layer, which prevents the internal fluid from being drained and corroded by corrosive gas, and the presence of the anticorrosion tape provides excellent followability to the expansion and contraction of the metal, resulting in cracks and peeling. The effect is that it can also be prevented. Further, the anticorrosion layer is composed of the undercoating anticorrosion coating, the anticorrosion tape and the topcoat anticorrosion coating, and has a simple structure, so that it is excellent in cost and workability.
Further, according to the maintenance method of the present invention, even for an existing expansion joint in which some corrosion has progressed, a similar anticorrosion layer is provided in connection with the maintenance, so that the drain of the internal fluid is drained in the subsequent use. And, corrosion due to corrosive gas can be effectively prevented.
From the above, according to the present invention, an expansion joint which can favorably prevent corrosion of a metal member due to drain or corrosive gas without adversely affecting cost and workability, and an anticorrosion method and maintenance method applicable to maintenance of the expansion joint Can be provided.

It is a perspective view for showing an example of an expansion joint. It is a longitudinal cross-sectional view of the expansion joint of FIG. It is a longitudinal section of one embodiment of an expansion joint of the present invention. It is sectional drawing of an anticorrosion layer. It is a partially expanded view of an expansion joint for explaining other embodiment of the expansion joint of the present invention.

Hereinafter, embodiments of the present invention will be further described with reference to the drawings.
FIG. 3 is a vertical cross-sectional view of one embodiment of the expansion joint of the present invention.

The expansion joint 1 shown in FIG. 3 has substantially the same structure as the expansion joint 1 shown in FIGS. 1 and 2, but will be described again with reference to FIG. The expansion joint 1 of the present invention is characterized in that an anticorrosion layer 52 including an undercoating anticorrosion coating, an anticorrosion tape and a topcoat anticorrosion coating is provided on the fluid side inner surface of the frame portion in this order.

The expansion joint 1 shown in FIG. 3 is exemplified as being used in a gas turbine plant, like the expansion joint 1 shown in FIGS. 1 and 2.
The expansion joint 1 is disposed between the upstream duct 3 and the downstream duct 5, and has a pair of flanged joint bodies 7 and 9, and a cylindrical bellows 11 that connects the pair of joint bodies 7 and 9. A plurality of heat insulating materials 13, 15, 17, 19, 21 arranged inside the bellows 11 are provided. Each of the pair of joint bodies 7 and 9 is formed of a tubular member that connects to the corresponding duct 3 or 5. A joint flange portion 7 a is formed on the upstream side of the first joint body 7. On the other hand, a similar duct flange portion 3a is also formed on the downstream side of the upstream duct 3, and the first joint body 7 is formed by connecting the joint flange portion 7a and the duct flange portion 3a with the fastening means 23 or the like. It is hermetically connected to the upstream duct 3. Further, similar joint flange portions 9a and duct flange portions 5a are formed on the downstream side of the second joint body 9 and the upstream side of the downstream duct 5, and these joint flange portions 9a and duct flange portions 5a are fastened. The second joint body 9 is air-tightly connected to the downstream duct 5 by being connected by means 23 or the like.

On the outer surfaces of the first and second joint bodies 7 and 9, annular metal frame portions 7b and 9b are erected by welding. The upstream end and the downstream end of the bellows 11 are engaged with the frame portions 7b and 9b, respectively. Further, pressing plates 7c and 9c are arranged outside the upstream and downstream ends of the bellows 11 engaged with the frame portions 7b and 9b. With the upstream end and the downstream end of the bellows 11 being sandwiched between the frame portions 7b and 9b and the holding plates 7c and 9c, these frame portions and the holding plate are connected by the fastening means 25. In this way, the bellows 11 is fixed between the pair of joint bodies 7 and 9. The pair of pressing plates 7c and 9c are connected by a shipping bolt 27 via L-shaped metal fittings 7d and 9d fixed by fastening means 25. The shipping bolt 27 is used to set the expansion joint to the mounting dimension, and is removed after the connection between the ducts 3 and 5 is completed.

The heat insulating material 13 is arranged on the outermost side of the plurality of heat insulating materials provided inside the bellows 11, and further the first stretchable heat insulating material 15 and the second stretchable heat insulating material 17 are arranged inward from the heat insulating material 13. It is arranged. These heat insulating materials 13, 15 and 17 are located inside the bellows 11 and at the same time outside the joint bodies 7 and 9, and are surrounded by the pair of frame portions 7 b and 9 b and the bellows 11.

Further, an exposed heat insulating material 19 is arranged inside the second expandable heat insulating material 17, and a pair of fixed heat insulating materials 21 is arranged inside the exposed heat insulating material 19. These heat insulating materials 19 and 21 are located inside the bellows 11 and, at the same time, inside the joint bodies 7 and 9. In addition, the pair of fixed heat insulating materials 21 are provided separately on the upstream side and the downstream side, leaving a central portion in the flow direction of the expansion joint 1. Thereby, the exposed heat insulating material 19 is exposed to the flow path between the pair of fixed heat insulating materials 21, that is, in the central portion in the flow direction. A stud bolt 29 is erected from the lower surface of each of the pair of joint bodies 7 and 9 toward the inside, that is, toward the flow path axis. These stud bolts 29 penetrate the exposed heat insulating material 19 and the fixed heat insulating material 21, and the tips thereof project from the inner peripheral surface of the fixed heat insulating material 21. On the other hand, the stud bolts 29 are also erected from the upper surface of each of the pair of joint bodies 7 and 9 toward the outside, that is, in the direction opposite to the flow path axis side, and fix the heat insulating materials 13, 15, and 17. Further, a heat insulating material cover 31 is provided around each fixed heat insulating material 21, and each heat insulating material cover 31 is fixed by a nut screwed to the tip of the stud bolt 29. A baffle 33 is attached to the heat insulating material cover 31 on the upstream side.

As described above, the expansion joint 1 shown in FIG. 3 is provided with the undercoating anticorrosion coating, the anticorrosion tape and the topcoat anticorrosion coating in this order on the fluid-side inner surface of the frame portions 7b and 9b, preferably on the entire inner surface. A layer 52 is provided.

FIG. 4 is a cross-sectional view of the anticorrosion layer 52 provided on the fluid-side inner surface of the frame portion 7b. An undercoat anticorrosion coating 522, an anticorrosion tape 524, and an overcoat anticorrosion coating 526 are provided in this order in the direction from the frame portion 7b toward the fluid-side inner surface of the frame portion 7b. It is preferable that the surface of the frame portion 7b on which the anticorrosive layer 52 is provided is preliminarily adjusted with two or more types of kerene.

The coating material (undercoating anticorrosion coating material) for forming the undercoating anticorrosion coating 522 is not particularly limited as long as it has heat resistance and adhesion to the metal frame portion, and examples thereof include a heat-resistant silicone resin, a rust preventive pigment, A pigment containing a coloring pigment and an extender, which is dispersed in an organic solvent or water, is preferable because it is excellent in heat resistance, workability, and cost performance. As the heat-resistant silicone resin, one known in the art can be appropriately selected and used. As the rust preventive pigment, it is possible to appropriately select and use an existing basic rust preventive pigment, a non-conductive film forming rust preventive pigment, a reducing rust preventive pigment and the like. However, since it is necessary to have heat resistance, inorganic rust preventive pigments are preferable, and those containing no lead and chromium are particularly preferable. Further, it is preferable to use an inorganic pigment because the coloring pigment and the extender pigment also need heat resistance.
The thickness of the undercoating anticorrosion coating 522 is, for example, 70 μm to 200 μm, and preferably 100 μm to 150 μm.

As a material of the anticorrosion tape 524, an inorganic fiber woven fabric is preferable, and a glass fiber woven fabric or an alumina fiber woven fabric is preferable from the viewpoint of exhibiting excellent followability with respect to expansion and contraction of a metal, and capable of favorably preventing cracks and peeling. More preferred is cloth.
Such inorganic fiber woven fabric preferably has an amount of 50 to 400 g, and more preferably 100 to 300 g per 1 m ² .
The width of the anticorrosion tape 524 is, for example, 10 mm to 300 mm, preferably 50 mm to 200 mm.
The thickness of the anticorrosion tape 524 is, for example, 0.1 mm to 1.0 mm, preferably 0.3 mm to 0.7 mm.
The anticorrosion tape 524 can be installed as a single layer or by laminating a plurality of layers on the fluid side inner surface of the frame portions 7b and 9b through the undercoating anticorrosion coating 522.

As the paint (top-coat anticorrosion paint) for forming the top-coat anticorrosion paint 526, the same paint as the undercoat anticorrosion paint 522 can be used.
The thickness of the top coat anticorrosive coating 526 is, for example, 50 μm to 200 μm, and preferably 70 μm to 120 μm.

The anticorrosion layer 52 can be formed by applying an undercoating anticorrosive paint to a base, making an anticorrosion tape adhere to it, and then applying an overcoat anticorrosion paint on the anticorrosion tape. As a coating method, a known method may be adopted and is not particularly limited, and examples thereof include brush coating and spray coating.
The same paint as the undercoat anticorrosive paint and/or the top anticorrosive paint may be impregnated into the inorganic fiber woven fabric in advance before construction, and this may be used as the anticorrosion tape. According to this mode, the adhesion between the undercoating anticorrosion coating 522, the anticorrosion tape 524 and the topcoat anticorrosion coating 526 becomes good, and heat resistance, workability, etc. can be further enhanced. In this form, the impregnated amount of the undercoat anticorrosive paint and/or the top anticorrosive paint is preferably 400 to 1,200 g, and more preferably 400 to 800 g per 1 m ² of the anticorrosion tape.
In the above embodiment, the thickness of the anticorrosion layer 52 is, for example, 1,200 μm to 2,000 μm, and preferably 1,200 μm to 1,600 μm.

According to the expansion joint 1 of the present invention as described above, since the inner surface of the metal member of the flange or the frame which easily corrodes is protected by the anticorrosion layer 52, even if acid drain of the internal fluid or corrosive gas is generated. However, these do not come into direct contact with the metal member and can prevent corrosion of the metal member. Further, the anticorrosion layer 52 exhibits excellent followability to the expansion and contraction of the metal due to the presence of the anticorrosion tape 524, so that cracks and peeling are less likely to occur, and the corrosion prevention effect is maintained for a long period of time. Further, since the anticorrosion layer 52 has a simple structure including the undercoating anticorrosion coating 522, the anticorrosion tape 524 and the topcoat anticorrosion coating 526, it is excellent in cost and workability.
In addition, when applying the anticorrosion method of the present invention to an existing expansion joint where some corrosion is progressing, after removing dirt and rust by a cleaning operation etc., the unevenness caused by the corrosion is heat resistant. It is preferable that the anticorrosion layer is formed by filling the surface with the putty and then adjusting the groundwork.

In addition, the expansion joint of the present invention has a drain discharge structure that promotes drain discharge to at least a portion of the lower side where the drain tends to accumulate during installation, from the viewpoint that corrosion of the metal member due to drain can be better prevented. May be provided.
FIG. 5 is a partially enlarged view of the expansion joint for explaining the other embodiment of the expansion joint of the present invention.
FIG. 5 shows a structure near the bottom surface of the expansion joint. The expansion joint has substantially the same structure as the expansion joint 1 of the present invention shown in FIG. 3, but is the bottom surface of the heat insulating material. A drain pipe 72 is connected to the heat insulating material 13. According to this structure, the drain existing near the heat insulating material and the frame portion can be efficiently discharged to the outside of the expansion joint 1 by opening and closing the valve 722, and the corrosion prevention of the metal member is further enhanced. The drain pipe 72 can be made of metal or heat-resistant resin, and can be connected to the frame portions 7b and 9b by welding, bonding, screwing, or the like. When installing a metal drain pipe, it is desirable to use corrosion resistant steel or use a drain pipe that has been subjected to anticorrosion treatment. In addition, as a material when using a drain tube made of heat-resistant resin, a fluororesin such as PTFE, PFA, or FEP is suitable.

According to the present invention, it is possible to realize an expansion joint which can favorably prevent corrosion of a metal member due to drainage or corrosive gas, and an anticorrosion method and maintenance method applicable to the maintenance thereof without adversely affecting cost and workability. be able to.

Hereinafter, the present invention will be further described with reference to examples, but the present invention is not limited to the following examples.

(1) Steel plate As a steel plate, S-TEN2 manufactured by Nippon Steel & Sumitomo Metal Corporation was used.
Steel plate size: 100 mm x 100 mm x 6 mm
(2) Anticorrosion paint Night primer NP-400 manufactured by Carrozzeria Japan Co., Ltd. was used as the undercoat and topcoat anticorrosion paint.
(3) Anticorrosion Tape As an anticorrosion tape, a night tape NT-400 manufactured by Carrozzeria Japan Co., Ltd. was used. The tape is a glass fiber woven cloth impregnated with night primer NP-400, and has a tape width of 50 mm, a thickness of about 0.6 mm, and a mass of about 800 g per 1 m ^{2 of} the tape. Further, the impregnation amount of the night primer NP-400 was about 600 g per 1 m ² of the tape.

Example 1
Apply 1st class keren to the steel plate, apply the first undercoating anticorrosive paint so that the film thickness will be about 60 μm, and then leave an interval of 1 hour, and then apply the film thickness on the first undercoating anticorrosion coating. A second undercoating anticorrosive coating was applied so as to have a thickness of about 60 μm, and an undercoating anticorrosive coating was performed so that the total thickness of the undercoating anticorrosive coating was about 120 μm. After performing the undercoating anticorrosion coating and naturally drying for 12 hours, an anticorrosion tape was attached while applying the anticorrosion paint to the undercoating coated surface so that the film thickness was about 60 μm. As shown in FIG. 4, the anticorrosion tapes were laminated on each other while being shifted by about a half in the width direction of the tapes, so that the anticorrosion tapes had almost two layers on one side of the steel sheet. The anticorrosive paint was applied between the overlapping portions of the anticorrosion tape so that the film thickness was about 60 μm. Then, it was naturally dried for 1 hour, coated with a top coat anticorrosion coating so as to have a film thickness of about 100 μm, and cured at room temperature of 25° C. for 3 days to obtain a test body having a corrosion prevention layer.

Example 2
The same anticorrosion layer as that of Example 1 was formed except that the steel sheet was subjected to the second class kelene, to give a test piece.

Comparative Example 1
The steel plate is coated with Class 1 Keren, and the surface is coated with the first anticorrosion paint so that the film thickness is about 60 μm. After that, 1 hour interval is left, and then the first anticorrosion paint is applied, the film thickness is about 60 μm. The second anticorrosion coating was applied so that the total thickness of the anticorrosion coating was about 120 μm. After coating, the specimen was aged at room temperature of 25° C. for 3 days to obtain a test body coated with only the anticorrosive paint.

Comparative example 2
A test piece was prepared by coating only the anticorrosion paint in the same manner as in Comparative Example 1 except that the steel sheet was treated with the second class keren.

Comparative Example 3
The steel plate was used as it was without any treatment such as shaving.

(4) Evaluation Each test piece was placed in a heating furnace having an atmosphere of 200° C. for 1 hour, taken out, and cooled to room temperature. This cycle was defined as 10 cycles, and this cycle was repeated 10 times, after which the test piece was immersed in 1N sulfuric acid for 24 hours. Then, the appearance was observed. The same test was conducted at an ambient temperature of 400°C.
By visually observing the appearance, there was no abnormality, ◯, cracks in the coating film were △, cracks in the coating film further peeled off, and the exposed part of the steel plate was black and corroded. ..
Only the steel sheet was rated as x because rust occurred.

Table 1 shows the obtained evaluation results.

As is clear from Table 1, by forming the anticorrosion layer in which the anticorrosion tape made of the glass fiber woven fabric was laminated, Examples 1 and 2 had an excellent anticorrosion effect against repeated heating. ..
On the other hand, in Comparative Example 1 and Comparative Example 2 in which the anticorrosion layer was formed only by anticorrosion coating, cracking or peeling of the coating film occurred in the anticorrosion layer due to repeated heating, and further, the portion where the coating film was peeled off was sulfuric acid. It did not have a sufficient anticorrosion effect due to corrosion.

1, 10 Expansion joint 3 Upstream duct 5 Downstream duct 7, 9 Joint body 7a, 9a Joint flange portion 7b, 9b Frame portion 7c, 9c Holding plate 7d, 9d L-shaped metal fitting 11 Bellows 13, 15, 17, 19, 21 Heat Insulation Material 27 Shipping Bolt 29 Stud Bolt 52 Anticorrosion Layer 522 Undercoat Anticorrosion Coating 524 Anticorrosion Tape 526 Topcoat Anticorrosion Coating 72 Drain Pipe 722 Valve

Claims (7)

An expansion joint that expandably connects between a pair of ducts through which a high-temperature fluid flows,
The expansion joint has a pair of flanges for connecting to the duct, and a metal frame portion that holds a bellows and a heat insulating material,
An expansion joint, wherein an inner surface of the frame portion on the fluid side is provided with an anticorrosion layer including an undercoating anticorrosion coating, an anticorrosion tape, and a topcoat anticorrosion coating in this order. The expansion joint according to claim 1, wherein the anticorrosion tape is obtained by impregnating an inorganic fiber woven fabric with the same paint as the paint used for the undercoating anticorrosion coating and/or the topcoat anticorrosion coating. The expansion joint according to claim 2, wherein the inorganic fiber woven fabric is a glass fiber woven fabric or an alumina fiber woven fabric. The paint used for the undercoat anticorrosion coating and the topcoat anticorrosion coating contains at least a heat-resistant silicone resin, an anticorrosive pigment, a coloring pigment and an extender pigment, and these are dispersed in an organic solvent or water. The expansion joint according to any one of Items 1 to 3. The expansion joint according to any one of claims 1 to 4, wherein a drain discharge structure is provided in at least a part of a portion on the lower side where the drain tends to accumulate during installation. A method of connecting a pair of ducts through which a high-temperature fluid flows so as to be able to expand and contract, a method of preventing corrosion of expansion joints,
The expansion joint has a pair of flanges for connecting to the duct, and a metal frame portion that holds a bellows and a heat insulating material,
An anticorrosion method for expansion joints, comprising the step of providing an anticorrosion layer comprising an undercoating anticorrosion coating, an anticorrosion tape and an overcoat anticorrosion coating in this order on the fluid-side inner surface of the frame portion. A method of connecting a pair of ducts through which a high-temperature fluid flows so that it can expand and contract, a corrosion prevention method applied to maintenance of expansion joints in use or after use.
The expansion joint has a pair of flanges for connecting to the duct, and a metal frame portion that holds a bellows and a heat insulating material,
An anticorrosion method for expansion joints applicable to maintenance, comprising the step of providing an anticorrosion layer having an undercoating anticorrosion coating, an anticorrosion tape, and an overcoat anticorrosion coating in this order on the fluid-side inner surface of the frame portion.

Images