KR100879770B1 - Chimney assembly for preventing waterdrop invasion - Google Patents

Abstract

A dew invasion-free flue assembly for the exhaustion of exhaust gas is provided to prevent waterdrop from penetrating into sound absorbing holes by directly dropping the dew without passing through dew invasion-preventing grooves while dew generated in a flue flows down along an inner wall surface of a sound absorbing inner cylinder. A dew invasion-free flue assembly for the exhaustion of exhaust gas comprises a sound absorbing inner cylinder(12) positioned inside the insulating inner cylinder, an insulating inner cylinder(16) surrounding a sound insulating material(14) filled between the sound absorbing inner cylinder and insulating inner cylinder, and an outer cylinder(18) forming an air insulating layer. The sound absorbing inner cylinder has dew invasion-preventing grooves(120) formed in one or more places thereof. The dew invasion-preventing grooves are projected to the outside to prevent dew from penetrating into the sound insulating material. The dew invasion-preventing grooves a "Ý¿" shaped cross-sectional shape having predetermined width(w) and depth(t). The dew invasion-preventing grooves have a plurality of sound absorbing holes(120a) formed therein to absorb noise in the flue onto the sound insulating material.

Description

Chimney assembly for preventing waterdrop invasion without condensation infiltration

The present invention relates to a flue assembly for exhaust gas discharge, and in particular, to prevent the dew condensation generated within the flue is absorbed by the heat insulating material to improve the sound absorption performance and at the same time to improve the strength of the flue exhaust gas discharge without condensation The present invention relates to a dragon year assembly.

In general, the flue is combusted using fuel such as petroleum, coal and gas to obtain the energy required in power plants, incinerators, district heating chimneys and factories. It refers to the connecting line, the flue is usually in the form of a double tube having a thermal insulation structure so that the hot air is not discharged to the outside when the exhaust gas passes through the flue using a ceramic coated stainless steel or steel sheet material The internal temperature of the flue exhausting the exhaust gas rises to 200-600 ° C. and adopts a structure having a heat insulation layer to prevent the exhaust gas from being emitted around the flue.

As a flue assembly of the prior art for obtaining the flue, Korean Patent No. 10-0728137 is known. It fills a heat insulating member between the sound absorbing inner cylinder and the heat insulating inner cylinder, and forms a plurality of sound absorbing holes in the sound absorbing inner cylinder, and surrounds the circumference of the heat insulating inner cylinder to form an air insulation layer, thereby suppressing noise generation and obtaining a heat insulating function. To make it work.

However, it was difficult for the sound insulation and insulation to function as the condensation inside the flue penetrated into the insulation member through the sound absorbing hole, which caused the condensation member to sag down under the condensation.

In order to solve this problem, Korean Patent No. 10-0855218 is known as another conventional technology. The spacer is installed on the upper and lower outer periphery of the flue tube to form an air insulation layer at a predetermined interval when the outer tube is inserted, and the two sound-absorbing inner cylinders formed by the plurality of sound absorbing holes inserted into the flue can be inserted into the upper and lower parts. A holder is installed on the upper and lower outer periphery of the sound absorbing inner cylinder, and the inner surface of the inner cylinder and the inner cylinder of the sound absorbing inner cylinder is clamped by clamping the sound absorbing insulation layer formed by winding glass cloth and glass wool in order. The sound-absorbing insulating layer can be formed between the peripheral edges.

However, this requires additional manufacturing and installation of the spacer, and the manufacturing process of winding the insulation member is complicated. Moreover, condensation cannot be prevented from penetrating into the glass cloth and glass wool through the sound absorbing hole, and thus, it is difficult to exert the function of insulation and sound insulation.

Therefore, the present invention was created in view of the above circumstances, and the structure and manufacturing are simple and prevent the condensation generated in the year from being absorbed into the insulation without the use of additional parts to improve the sound absorption performance and at the same time the strength of the flue It is an object of the present invention to provide a flue assembly for exhaust gas emission without condensation intrusion to improve the efficiency of the gas.

Specific means of the present invention for achieving the above object,

A flue gas exhaust flue assembly comprising a heat insulating inner cylinder positioned between an inner sound absorbing inner cylinder and a sound absorbing inner insulating tube disposed between the inner sound absorbing insulation and an outer cylinder disposed outside the inner heat insulating inner cylinder to form an air insulation layer.

There is one condensation intrusion prevention groove in the sound absorbing inner cylinder which is formed in an annular groove shape having a "⊃" -shaped cross section having a predetermined width and depth so as to prevent condensation formed on the inner circumferential surface of the sound absorbing insulating material. The above-mentioned condensation intrusion preventing groove is characterized in that a plurality of sound absorbing holes are formed to transmit and absorb the noise in the flue to the sound absorbing insulation.

Also according to the invention,

The condensation intrusion preventing groove is formed in an annular groove shape having a predetermined width and depth, and the sound absorbing hole is formed in one or more rows at a predetermined interval in the condensation intrusion preventing groove.

Also according to the invention,

The condensation intrusion preventing groove is characterized in that each formed in one upper and one lower portion of the sound-absorbing inner cylinder.

Also according to the invention,

The condensation intrusion preventing groove is characterized in that formed at regular intervals in the longitudinal direction of the sound-absorbing inner cylinder.

Also according to the invention,

The sound absorbing inner cylinder is supported by the heat insulating inner cylinder via an inner cylinder side connecting bracket spanning the condensation intrusion preventing grooves formed on the upper and lower sides.

Also according to the invention,

The condensation intrusion preventing groove is formed in a plurality of spirals that are swiveled in the flue direction, and the sound absorbing hole is formed in one or more rows at a predetermined interval in the spiral condensation intrusion preventing groove.

According to the flue assembly for exhaust gas discharge without condensation intrusion of the present invention, while the condensation generated in the flue flows downward through the inner wall of the sound absorbing cylinder, it is dropped directly without passing through the condensation intrusion preventing groove and is formed in the condensation intrusion preventing groove. The droplets do not penetrate the ball.

As a result, the infiltration of condensation into the sound absorbing hole is prevented, so that the insulated heat insulating material does not contain moisture, and the sound insulating insulating material does not contract or collapse. Therefore, the performance of sound absorption and heat insulation does not deteriorate.

Therefore, as in the prior art, it is not necessary to perform a complicated installation work in which a glass wool or the like, which is installed as a heat insulating material, is made, and production is simplified.

In addition, the condensation intrusion preventing grooves formed in the sound absorbing inner cylinder have an advantage of providing an installation stability as well as reinforcing the duct since the moment increases the bending stiffness.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As illustrated in FIGS. 1 to 3, the flue assembly 10 for exhaust gas discharge includes a sound absorbing inner cylinder 12 disposed inside and a sound absorbing heat insulating member 14 filled between the sound absorbing inner cylinder 12. 16) and the outer cylinder 18 is disposed outside the heat insulating inner cylinder 16 to form an air insulation layer (17).

At this time, the size of the diameter is made to increase in the order of the sound absorbing inner cylinder 12, the heat insulating inner cylinder 16 and the outer cylinder 18, the material is all made of a metal plate, preferably made of a stainless material.

Here, the sound absorbing heat insulating material 14 may be a glass wool, ceramic wool, polyester sound absorbing heat insulating material, polyol, etc., capable of absorbing and / or insulating.

Flanges 16a and 16b are formed in the upper and lower portions of the insulated inner cylinder 16 to connect the same to the flue assembly 10 for exhaust gas discharge to each other. It is treated with silicone and connected by bands.

In the sound absorption inner cylinder 12, the condensation intrusion prevention groove | channel 120 which protrudes outward is formed in one or more places so that the dew condensation which may generate | occur | produce on the inner peripheral surface may not flow in into the sound absorption heat insulating material 14. As shown in FIG. The condensation intrusion preventing groove 120 has a plurality of sound absorbing holes 120a for transmitting and absorbing noise in the flue to the sound absorbing heat insulating material 14. Sound absorbing hole (120a) is formed in a circular shape is not limited to this form.

The condensation intrusion preventing groove 120 is formed as an annular groove having a cross-section having a “⊃” shape having a predetermined width w and depth t in the first embodiment, and the sound absorbing hole 120a is formed in the condensation intrusion preventing groove. It may be formed in one row as shown in Figure 3 or a plurality of rows or two as shown in Figure 4 at a predetermined interval (120). 4 shows that the sound absorbing holes 120a are arranged in two rows in the condensation intrusion preventing grooves 120 located on the upper and lower sides of the sound absorbing inner cylinder 12.

When the condensation intrusion prevention groove 120 is formed in only one upper part and one lower part as shown in FIGS. 3 and 4, the sound absorbing inner cylinder 12 is welded through the inner cylinder side connecting bracket 15 to absorb the sound absorbing inner cylinder. (12) can be simply supported in the adiabatic inner cylinder (12).

In addition, the condensation intrusion preventing groove 120 may be formed in an annular groove shape at regular intervals in the longitudinal direction of the sound absorbing inner cylinder 12 as shown in FIG. 5.

At this time, the condensation intrusion preventing groove 120 not only prevents the infiltration of condensation, but also installs the sound absorbing insulation 14 wrapped around the outer circumferential surface of the sound absorbing inner cylinder 12 at a predetermined depth t into the sound absorbing insulation 14 to absorb the sound absorbing insulation. It also serves to prevent sagging of (14).

Meanwhile, as a third embodiment, the condensation intrusion preventing groove 120 is formed in at least one spiral groove shape that is pivoted on the inner circumferential surface of the flaw inner cylinder 12 as shown in FIGS. 6 and 7, and the condensation intrusion preventing groove of the spiral groove type is formed. The sound absorbing holes 120a may be formed in one row or in a plurality of rows at the 120.

Such a spiral groove-type condensation intrusion preventing groove 120 is pivoted in the direction of the flue, and when exhaust gas is discharged into the flue, the pivotal lifting force is provided to facilitate the discharge of the exhaust gas upwards and easily.

Reference numeral '19' indicates 'outer connection bracket'.

The fabrication method and operation of this embodiment configured as described above will be described.

First, the sound absorbing heat insulating material 14 is wrapped around the outer circumferential surface of the prepared sound absorbing inner cylinder 12 and inserted into the inner heat insulating inner cylinder 16.

In this case, the sound absorbing heat insulating material 14 is in a state filled between the sound absorbing inner cylinder 12 and the heat insulating inner cylinder 16.

Next, the sound absorbing inner cylinder 12 is connected to and fixed to the inner heat insulating inner cylinder 16 via a plurality of inner cylinder side connecting brackets 15 on the upper and lower sides, respectively. At this time, the inner cylinder side connecting bracket 15 is welded with one end supported by the protruding jaw of the condensation intrusion preventing groove 120 of the sound absorbing inner cylinder 12, and the other end thereof is welded and fixed to the inner surface of the heat insulating inner cylinder 16. . In this case, the sound absorption inner cylinder 12 and the heat insulation inner cylinder 16 are easily installed in concentric circles.

Then, the inner heat insulating inner cylinder 16 is inserted into the inner cylinder 18 and then connected and fixed to the outer cylinder 18 and the inner heat insulating inner cylinder 16 by welding the outer cylinder side connecting bracket 19.

The flue gas exhaust assembly 10 configured as described above is connected to a plurality of straight lines to form a flue, wherein the sound absorbing inner cylinder 12 is a passage of the combustion gas. Condensation generated by the temperature difference inside and outside the flue assembly 10 for exhaust gas discharge, ie, water droplets, flows downward along the inner surface of the sound absorbing inner cylinder 12 in which the condensation intrusion preventing groove 120 is not formed.

This water droplet flows from the upper side to the lower side of the flue immediately before reaching the condensation intrusion preventing groove 120, and immediately passes through the condensation intrusion preventing groove 120 by the drop flow force as in the direction of the arrow (D). It falls off.

Therefore, the condensation intrusion prevention groove 120 prevents water droplets caused by condensation from entering. For this reason, intrusion of condensation is interrupted by the sound absorbing hole 120a, and water is not absorbed by the sound absorbing heat insulating material 14. Therefore, the sound absorbing heat insulating material 14 does not absorb water and does not hesitate to reduce the volume. Therefore, the sound absorption performance of the sound absorption heat insulating material 14 does not fall.

In addition, the condensation intrusion preventing groove 120 increases the cross-sectional moment of the sound-absorbing inner cylinder 12 to obtain a reinforcement by increasing the bending strength, thereby giving an advantage of improving the installation safety of the flue.

In addition, since the condensation intrusion preventing groove 120 penetrates into the sound absorbing insulation 14, even if a small amount of condensation penetrates, the condensation intrusion preventing groove 120 serves to support the sound absorbing insulation 14 in the middle. Do not sit down.

In addition, when the condensation intrusion preventing groove 120 is formed in a plurality of spirals that turn in the flue direction as shown in FIGS. 6 and 7, not only reinforcement of the flue but also a rising turning force of the exhaust gas are obtained, and exhaust is quickly performed.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

The following drawings, which are attached in this specification, illustrate preferred embodiments of the present invention, and together with the detailed description of the present invention, serve to further understand the technical spirit of the present invention. It should not be construed as limited to.

1 is a perspective view of a flue assembly for exhaust gas discharge according to the present invention.

Figure 2 is an exploded perspective view of the flue gas exhaust assembly according to the invention.

Figure 3 is a cross-sectional view of the flue gas exhaust assembly according to the first embodiment of the sound absorbing inner cylinder applied to the present invention.

Figure 4 is a cross-sectional view of the flue gas exhaust assembly according to the second embodiment of the sound absorbing inner cylinder applied to the present invention.

5 is a cross-sectional view of a flue gas exhaust assembly according to a third embodiment of the sound absorbing cylinder applied to the present invention.

6 and 7 are a plan view and a front sectional view according to a third embodiment of the sound-absorbing inner cylinder applied to the present invention.

<Explanation of symbols for the main parts of the drawings>

12: sound absorption

14: Sound Insulation Material

15: inner cylinder connecting bracket

16: insulation cylinder

17: External connection bracket

18: outer barrel

120: groove for preventing dew condensation

120a: sound absorber

Claims (6)

A sound absorbing inner cylinder 12 located inside, a heat insulating inner cylinder 16 filling and wrapping the sound absorbing insulating material 14 between the sound absorbing inner cylinder 12, and disposed outside the heat insulating inner cylinder 16 to form an air insulation layer. In the flue gas exhaust flue assembly consisting of an outer cylinder (18), Condensation that forms on the inner circumferential surface of the sound absorbing inner cylinder 12 flows outward to prevent entry into the sound absorbing insulation 14 and has an annular shape having a cross-sectional shape having a predetermined width w and a depth t. One or more condensation intrusion preventing grooves 120 are formed in the groove shape of the groove, and a plurality of sound absorbing holes 120a are formed in the condensation intrusion preventing grooves 120 to transmit and absorb the noise in the flue to the sound absorbing heat insulating material 14. Flue assembly for exhaust gas emission without condensation intrusion, characterized in that. The method of claim 1, The sound absorbing hole (120a) is a flue assembly without condensation infiltration exhaust flue assembly, characterized in that formed in one or more rows at a predetermined interval in the condensation intrusion prevention groove (120). The method of claim 2, The condensation intrusion preventing groove (120) is a flue assembly for condensation-free exhaust gas discharge, characterized in that formed in each of the upper one and the lower one of the sound-absorbing inner cylinder (12). The method of claim 2, The condensation intrusion preventing groove 120 is a flue gas exhaust assembly without condensation infiltration, characterized in that formed at a predetermined interval in the longitudinal direction of the sound-absorbing inner cylinder (12). The method of claim 3, wherein The sound-absorbing inner cylinder 12 is supported by the heat-insulating inner cylinder 12 via an inner cylinder-side connecting bracket 15 spanning the condensation intrusion preventing groove 120 formed on the upper and lower sides. Flue assembly for exhaust gas emissions. The method of claim 1, The condensation intrusion preventing groove 120 is formed in a plurality of spirals turning in the flue direction, the sound absorbing hole (120a) is formed in one or more rows at a predetermined interval on the spiral condensation intrusion preventing groove (120). Flue assembly for exhaust gas emission without condensation intrusion.

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