KR101329983B1 - A non-metallic expansion joint - Google Patents

Abstract

The present invention relates to corrugated tubular nonmetallic expansion joints.
The corrugated tubular non-metallic expansion joint of the present invention is made of an inorganic insulating material molded into a corrugated pipe form for maximizing the stretching effect as an inner heat insulating layer, and a silicone resin having heat resistance and extensibility as an outer reinforcing layer.
Accordingly, it is possible not only to absorb the amount of displacement of the tube even at a high temperature of 600 ° C. or more, but also to have excellent thermal insulation as a non-metallic material, and to reduce the risk of breakage, thereby preventing the occurrence of a fire or a safety accident.

Description

Corrugated Tubular Nonmetallic Expansion Joint {A non-metallic expansion joint}

The present invention relates to a non-metallic expansion joint for corrugated pipes, and more particularly, it is installed in expansion joints of exhaust pipes of boilers or heating elements used in industry, and has high insulation and heat resistance as well as protection from mechanical and physical deformation. It relates to a corrugated tubular nonmetallic expansion joint that can absorb more displacement such as elongation to increase durability.

In general, exhaust pipes that generate high temperature heat, such as boilers or heating elements used in industrial fields, have expansion joints formed so as to absorb stresses caused by expansion and contraction of heat pipes appropriately so as not to cause axial deformation of the pipes. The expansion joint is provided with a metal expansion joint.

In the case of the expansion joint made of metal, if a large amount of displacement is absorbed at a narrow short distance of the installation space, there is a risk of damage due to fatigue of the material, which is a major cause of a large accident caused by the leakage of internal gas. have.

Therefore, bellows-shaped expansion joints have been developed as a way to have high elasticity even in a short space, and as an example, "expansion joint" (Korean Utility Model Publication No. 20-0203763, Patent Document 1), page 3, FIG. A bellows-shaped expansion and contraction tube is provided inside the cylindrical housing, and an expansion joint including a connection pipe to which an external metal pipe is connected is introduced at both ends of the expansion and contraction tube.

1 is a cross-sectional view illustrating a conventional bellows-type expansion joint, and as shown therein, a bellows-shaped stretch tube 4 is provided inside a cylindrical housing 5, and both ends of the stretch tube 4 are external. The connection pipe (3) is provided is connected to the metal pipe (1) of the installation, the expansion joint is connected to the metal pipe (1) of the piping line through the flange portion (2) of the connection pipe (3) do.

The bellows type expansion joint as described above prevents the metal pipe 1 from being damaged by absorbing the displacement amount according to the length change of the bellows type expansion pipe 4 even if the metal pipe 1 is expanded and deformed according to temperature change. It is designed to be.

On the other hand, in the exhaust system using the expansion joint as described above to reduce the heat emitted to the outside is not only to reduce the energy consumption, but also directly to the prevention of fire and safety accidents to maintain the insulation of the exhaust pipe and expansion joint It is a very important factor.

Due to this importance, in recent years, the insulation inside the metal expansion joint is filled to minimize the heat released, but in this case, the insulation is packed into the limited interior space of the expansion joint and compressed. Although maintaining the function, when the expansion expansion of the expansion joint due to high heat, there was a problem that the thermal insulation effect is sharply reduced due to the generation of empty space not filled with the insulation.

This problem is judged to occur due to the use of a metal material, recently weaved glass fiber in a flat structure and Teflon coating, and then laminated to the coating surface with an acid-resistant resin and then manufactured by molding with a mold and a press nonmetal Sex expansion joints have been developed.

However, the non-metallic expansion joints developed so far do not satisfy sufficient thermal insulation, heat resistance, and durability conditions.

In addition, most non-metallic expansion joints released so far have a ring inserted inside and outside to maintain bellows corrugated tube shape. When the corrugated pipe is broken in the middle of the connecting pipe, the pipe should be cut or split in half.If the pipe is cut in this way, the fluid inside the pipe cannot be processed. Because of the maintenance of the shape of the site assembly is impossible, there was a problem that maintenance is not easy.

KR 20-0203763 (2000.09.07)

The present invention is to solve the problems that occur in the prior art as described above, as well as having a higher heat insulation and heat resistance compared to the conventional products and at the same time absorb more displacement amount such as compression elongation to increase the durability as well as The goal is to provide corrugated non-metallic expansion joints that can be assembled or repaired on site immediately.

Corrugated tubular non-metallic expansion joint of the present invention, in order to solve the above problems, is made of a mineral material having a thermal insulation, is formed in a corrugated pipe shape, the cross-sectional shape takes a shape divided into a plurality of pieces based on the center. An internal insulation layer 10; It surrounds the outer circumferential surface of the inner heat insulating layer 10, the outer reinforcing layer 20 formed by coating a silicone resin on the outer circumferential surface of the inner heat insulating layer 10;

In this case, the internal insulation layer 10 is characterized in that the glass fiber, silica (Silica), Basalt (Basalt), selected from the ceramic (Ceramic) is included.

In addition, the internal insulation layer 10 is selected from a molding method using a mold and a press, a method of forming a corrugated pipe by needling, and a method of forming a stainless steel mesh into a corrugated pipe and inserting an inorganic insulating material therein to form the corrugated pipe. It is characterized by being molded by any one method.

In addition, the outer reinforcing layer 20, at least one inorganic fiber selected from glass fibers, silica fibers, basalt fibers, aramid in the process of applying a silicone resin or The heat-resistant fiber is repeated and wrapped in 2 to 5 layers, characterized in that formed by heat curing.

In addition, the inner insulation layer 10 and the outer reinforcing layer 20 is characterized in that the connection by the stitching (stitching) or quilting (quilting) method.

At this time, the inner insulation layer 10 and the outer reinforcing layer 20 is stitched or quilted by any one of the selected yarns of glass fiber, bazalt, silica, aramid, stainless wire is characterized in that the combined. It is done.

In order to maximize the stretching effect, the present invention forms an inorganic heat insulating material molded into a corrugated pipe as an inner layer, and configures an outer layer of a silicone resin having heat resistance and extensibility as an outer layer, thereby increasing the amount of displacement of the tube even at a high temperature of 500 ° C. or higher. Not only can it absorb, it is a non-metallic material with excellent thermal insulation and can be assembled and repaired on site immediately for easy workability and maintenance.

1 is a cross-sectional view showing a conventional bellows type expansion joint.
Figure 2 is an exploded perspective view showing the inner insulation layer of the corrugated tubular non-metallic expansion joint of the present invention.
3 is a perspective view illustrating an inner insulation layer of FIG. 2;
Figure 4 is a partially cut perspective view showing a state in which the outer reinforcing layer is formed to the outside of the inner insulating layer of FIG.
Figure 5 is a cross-sectional view showing one embodiment of the corrugated tubular nonmetallic expansion joint of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings, but the present invention is not limited to the embodiments shown in the drawings.

2 to 4 are exploded perspective and perspective views for explaining the expansion joint manufacturing method of the present invention, Figure 5 is a cross-sectional view showing the expansion joint of the present invention.

2 to 4, the corrugated tubular nonmetallic expansion joint of the present invention is composed of an inner insulation layer 10 and an outer reinforcement layer 20.

As illustrated, the inner insulation layer 10 is formed in a bellows shape, and the cross-sectional shape has a shape divided into a plurality of pieces based on the center, that is, a shape in which at least two or more are divided in the lateral direction.

The internal insulation layer 10 is made of an inorganic material having heat insulation.

Examples include glass fiber, silica fiber, basalt fiber, ceramic fiber, and the like.

As a method of manufacturing the internal insulation layer 10, a blanket of at least one material selected from glass fibers, silica, silica, basalt and ceramic fibers, which are inorganic insulation materials. Can be molded into a corrugated pipe by using a molding method using a mold and a press, a method of forming a corrugated pipe by needling, a method of manufacturing a stainless mesh in the form of a corrugated pipe, and inserting an inorganic insulating material therein. .

At this time, the method of taking a plurality of divided shapes is formed by molding a plurality of divided pieces (10a, 10b) in the molding process as described above, or a method of facing each other or after a separate cutting process by forming a plurality of divided pieces ( 10a, 10b).

For example, according to the size of the pipe to be applied to form a mold or jig suitable for the standard, wherein the inner mold and the outer mold is separated, all the mold is divided into a mold that can be easily separated after molding Designed and manufactured separately divided pieces (10a, 10b) can be assembled to each other in the field.

As illustrated in FIG. 4, the outer insulation layer surrounds the outer circumferential surface of the inner insulation layer 10, but a silicone resin is formed on the outer circumference of the inner insulation layer 10.

As described above, the outer reinforcing layer 20 is formed by uniformly applying a silicone resin, which is a heat-resistant resin, on the outer circumferential surface of the divided pieces 10a and 10b constituting the inner insulation layer 10 to form a cylindrical shape with each other.

At this time, the silicone resin is to be used as a two-component, before the construction of the two or more divided inner insulation layer 10 in the field using a pipe or jig (jig) to combine in one form, and then apply and cure the silicone resin The outer reinforcing layer 20 is formed.

In order to increase the heat resistance and strength of the outer reinforcing layer 20 in the outer reinforcing layer 20 as described above, glass fiber, silica fiber, basalt fiber, aramid One or more inorganic fibers or heat-resistant fibers selected in the) may be formed by repeatedly wrapping with 2 to 5 layers of silicone resin and heat curing with a hot air blower.

That is, by applying a layer of silicone resin and wrapping the silicone resin with the fiber 2 to 5 times to increase the heat resistance and strength of the outer reinforcing layer (20).

On the other hand, the corrugated tubular non-metallic expansion joint of the present invention configured as described above, the inner insulation layer 10 and the outer reinforcing layer 20 are integrally coupled to each other by the bonding force of the silicone resin, but in an external environment that repeats high and low temperatures When exposed, the external reinforcing layer 20 may be peeled off.

In order to prevent such a problem, in applying the outer reinforcing layer 20 outside the inner insulation layer 10, the inner insulation layer 10 and the outer reinforcing layer 20 are connected by stitching or quilting method. By doing so, the inner insulation layer 10 and the outer reinforcing layer 20 can be configured to be firmly coupled.

In this case, the thread used may be selected from among glass fiber, bazaar, silica, aramid, stainless steel wire.

Corrugated tubular non-metallic expansion joint of the present invention as described above is a non-metallic material using an inorganic insulating material, while faithful to the basic function to prevent mechanical and physical deformation due to the expansion and contraction of the pipe and duct due to high temperature heat, and to allow correction after deformation. At the same time, the shape is manufactured in the form of a corrugated pipe, thereby ensuring higher insulation and extensibility than the conventional metal material, thereby preventing energy reduction and the occurrence of fire or safety accidents.

In addition, the present invention by applying a silicone resin and inorganic fibers immediately after assembling in one form using a jig (jig), etc. in the field divided into at least two by forming an outer reinforcing layer 20 Workability is good, and there is no ring or other auxiliary means to maintain the corrugated pipe shape, and even after repairing the broken part, only the damaged inner insulation layer 10 is removed and a new inner insulation layer 10 is assembled, followed by an external reinforcement layer 20 Maintenance is very easy.

Corrugated pipe-type non-metallic expansion joint according to the present invention may be applied to the expansion joint of the pipe of the boiler or heating element used in the industry, as well as the expansion joint of the pipe, such as a domestic boiler actively changes in temperature.

10: internal insulation layer
10a, 10b: divided pieces
20: external reinforcement layer

Claims (6)

In corrugated tubular nonmetallic expansion joint,
An internal insulation layer 10 formed of an inorganic material having heat insulation and formed in a corrugated pipe shape and having a cross-sectional shape divided into a plurality of shapes based on a center;
It includes the outer circumferential surface of the inner insulation layer 10, the outer reinforcing layer 20 formed by coating a silicone resin on the outer circumferential surface of the inner insulation layer 10;
The inner insulation layer 10,
It is molded by any one method selected from a molding method using a mold and a press, a method of forming a corrugated pipe by needling, a method of manufacturing a stainless steel mesh into a corrugated pipe and inserting an inorganic insulating material therein.
The outer reinforcing layer 20,
In the process of applying the silicone resin, 2 to 5 layers of one or more inorganic fibers or heat resistant fibers selected from glass fiber, silica fiber, basalt fiber and aramid are repeated. It is formed by wrapping and heat curing,
The inner insulation layer 10 and the outer reinforcement layer 20 is characterized in that connected by stitching or quilting (quilting) method,
Corrugated non-metallic expansion joint.
The method of claim 1,
The inner insulation layer 10 is characterized in that made of glass fiber (Silas), silica (Silica), Basalt (Basalt), selected from the ceramic (Ceramic) is included.
Corrugated non-metallic expansion joint.
delete delete delete The method of claim 1,
The inner insulation layer 10 and the outer reinforcing layer 20 is stitched or quilted by any one of the bonding yarn selected from glass fibers, bazalt, silica, aramid, stainless wire, characterized in that the combined ,
Corrugated non-metallic expansion joint.

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