KR20210136548A - Fireproof damper - Google Patents

Abstract

According to one embodiment of the present invention, a fireproof damper is provided. The fireproof damper includes: a body part installed at one end of a duct; at least one blade member mounted inside the body part to be rotatable through a shaft member, and formed to open and close an internal space of the body part through rotation; a blade rotation means rotating the blade member in an open state under a specific condition to close the internal space; and a thermal-expandable fire-resistant structure mounted on the surface of the blade member to be expanded in case of a fire. The thermal-expandable fire-resistant structure includes a thermal-expandable fire-resistant material expanded by heat, and a support member having a net-shaped structure having a plurality of holes and manufactured of a metal material or an inorganic fiber which can endure a high temperature. Therefore, the present invention is capable of preventing an increase in an ambient temperature of the fireproof damper.

Description

Fire damper {FIREPROOF DAMPER}

The present invention relates to a fire damper, and more specifically, to a fire damper configured to prevent a flame, toxic gas, etc. from spreading through a duct in case of a fire. A fire resistant filler for more effectively blocking heat transfer, and a fire damper to which the fire resistant filler is applied.

In general, a duct is installed for the purpose of ventilation of indoor air as a type of air conditioning system in multi-story buildings or various buildings including apartments.

Ducts installed in buildings are very useful facilities in terms of ventilation. However, when a fire occurs, the duct serves as a passage through which a flame or toxic gas spreads. Accordingly, flames or toxic gases are propagated from the place where the fire occurs to other places where the duct is connected, and a fire at one place may lead to a large fire.

To prevent this, a fire damper for ducts that normally maintains an open state so that indoor and outdoor air is ventilated, but switches to a closed state when a fire occurs, and prevents flames and toxic gases from propagating to other places, has been proposed. Yes (eg, Patent Registration No. 10-1533333).

According to the fire damper, when the temperature rises due to a fire and the fire fuse is disconnected, the blade is closed by the elastic force of the spring. That is, when the fire fuse is melted and separated, for example, the blade rotates rapidly at the same time as a fire occurs to block the passage inside the duct, thereby preventing the propagation of flames or toxic gases through the duct.

However, due to the nature of the fire, it frequently occurs over a relatively long time of several hours or more, rather than a short time within a few minutes. The fire damper including the blade is made of a metal material having fire resistance. When this structure is exposed to a flame for a long time, heat can be transferred through the structure, and the gap between the edge of the blade and the body, the fire damper and the Flames may propagate through gaps between structures (ducts, walls, etc.) in which the dampers are installed. That is, when the fire damper is exposed to flames for a long time, the fire damper cannot sustain the high temperature, resulting in a problem in that high-temperature heat is propagated to the structure around the fire damper. In fact, in relation to the certification of the fire damper, a test of exposure to a high temperature of 2 hours or more is usually performed.

Registered Patent No. 10-1533333

The present invention is to solve the problems of the prior art, and an object of the present invention is to provide a fire damper for a duct that can reduce heat transfer through the fire damper for a duct itself.

Another object of the present invention is to provide a thermally expandable fire resistant structure for a fire damper that is mounted on a specific part of the fire damper for a duct and can reduce heat transfer through the fire damper.

In order to achieve the above object, a fire damper is provided according to one aspect of the present invention. The fire damper includes a main body installed at one end of the duct; one or more blade members rotatably mounted on the inside of the main body through a shaft member and configured to open and close the inner space of the main body by rotation; a blade rotating mechanism for rotating the blade member in an open state under a specific condition to close the inner space; and a thermally expansible fire resistant structure mounted on the surface of the blade member and configured to expand when a fire occurs, wherein the thermally expansible fire resistant structure comprises a thermally expansible fire resistant material that expands by heat, and a net-shaped structure having a plurality of holes formed therein. and a support member made of a metal material or inorganic fiber capable of withstanding a high temperature.

In one embodiment, the thermally expansible refractory material and the support member may be coupled to each other with the thermally expansible refractory material at least partially filling the opening of the support member, or the support member may be embedded within the thermally expansible refractory material.

In one embodiment, the thermally expansible fire resistant structure may be provided over the surface of the blade member, or divided into a plurality of band-shaped members may be provided.

In one embodiment, the thermally expansible fire resistant structure may be provided on one or both surfaces of the blade member.

In one embodiment, the thermally expansible fire resistant structure may be alternately provided with respect to the surfaces of the plurality of blade members when viewed in a cross-sectional view of a closed state.

In one embodiment, the thermally expansible fire resistant structure may be mounted to the blade member with the support member facing the blade member surface.

In one embodiment, the thermally expandable fire resistant structure may be mounted to the blade member by a plurality of fastening elements.

In one embodiment, the thermally expansible fire resistant structure may be mounted to the blade member with the thermally expansible fire resistant material facing the blade member surface.

In one embodiment, the thermally expansible fire resistant structure is mounted to the blade member using a plurality of fastening elements having a wide head and a long fastening portion, and the thermally expansible between the support member and the fastening element in the mounted state. An expansion space in which the refractory material can be expanded may be secured.

In one embodiment, the thermally expansible refractory material may be made of an organic binder and expanded graphite.

In one embodiment, when each of the blade members is viewed from the side, the front end and the rear end thereof may be configured to be inclinedly bent in opposite directions.

According to another aspect of the present invention, there is provided a thermally expandable fire resistant structure for use in a fire damper mounted at one end of a duct, converted into a closed state in the event of a fire, to prevent propagation of flames and gases through the duct. The thermally expansible fire resistant structure is configured to be mounted on the blade member of the fire damper in the form of a belt, and the thermally expansible fire resistant structure includes a thermally expansible fire resistant material that expands by heat, and a support member of a net-shaped structure having a plurality of holes formed therein. characterized in that

In the above structure, the thermally expansible refractory material and the supporting member may be coupled to each other with the thermally expansible refractory material at least partially filling the opening of the supporting member, or the supporting member may be embedded in the thermally expansible refractory material.

In the structure, the support member may be made of a metal material or an inorganic fiber capable of withstanding high-temperature heat.

In the structure, the thermally expansible refractory material may be made of an organic binder and expanded graphite.

In the above structure, the thermally expansible fireproof structure may be obtained by press-fitting the support member against the fireproof material after manufacturing the thermally expansible fireproof material.

According to the present invention, a thermally expandable fire resistant structure is mounted on the blade member of the fire damper for duct. In the thermally expansible refractory structure, the thermally expansible refractory material is supported by a support member of a net-like structure. This fire resistant structure is mounted to the blade member by a predetermined fastening means. Therefore, even if the fire damper is exposed to a high-temperature flame for a long time, the thermally expansible refractory material is supported by the support member, so that the refractory material remains attached to the blade member as much as possible during the flame exposure. Therefore, the propagation of the flame through the fire damper, blade, etc., specifically, the transfer of high-temperature heat can be blocked as much as possible, thereby preventing the temperature around the fire damper from rising.

1 is a partially cut perspective view showing the configuration of a fire damper for a duct to which the present invention is applied.
2 is a partially cut-away perspective view showing that the fire damper for the duct is in a closed state when a fire occurs.
3 is a perspective view showing the configuration of a thermally expandable fire resistant structure according to an embodiment of the present invention.
FIG. 4 is a schematic view showing a state in which the thermally expansible fire resistant structure of FIG. 3 is mounted on the blade member of the fire damper of FIG. 1 via a fastening means.
Fig. 5 is a partially cut-away perspective view showing a fire duct for a duct equipped with a thermally expansible fire resistant structure in an open state;
Fig. 6 is a partially cut-away perspective view showing a fire duct for a duct equipped with a thermally expandable fire resistant structure is in a closed state;
Fig. 7 is a schematic cross-sectional view showing a fire duct for a duct equipped with a thermally expandable fire resistant structure in a closed state;

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. In the following description, descriptions of configurations that are already well known in the art will be omitted. In particular, since the structure, function, operation, etc. of the fire damper for ducts are already widely known, a detailed description thereof will be omitted. Even if such description is omitted, those skilled in the art will be able to easily understand the characteristic configuration of the present invention through the following description.

1 and 2, an example of the configuration of a fire damper for a duct to which the present invention is applied is schematically shown in a partially cut form. Fig. 1 shows that the fire damper is in a normal state, that is, in an open state, and Fig. 2 shows that a fire has occurred and the fire damper is in a closed state.

The fire damper (A) is, for example, installed between the duct (not shown) through which air flows and the duct, and when a fire occurs, blocks the flow path between the ducts, so that a flame or toxic gas passes through the duct, causing a fire Prevent the spread to indoors, etc. near the place. On the other hand, the fire damper (A) may be installed between the duct and the duct, it may be installed in the inlet or outlet of the duct. That is, the fire damper (A) is installed at one end of the duct, and it should be noted that the present invention is not particularly limited in relation to the installation location and method of the fire damper. In addition, the present invention is not particularly limited with respect to the configuration of the fire damper itself.

When the structure of the fire damper A is described with reference to FIG. 1 and the like, the fire damper A is a rectangular parallelepiped body part 100 having a cross-section approximately the same shape and size as the outer shape of the duct in which the damper is installed. (It should be noted that in FIG. 1, etc., it is shown in a partially cut form, and the blade member 110 to be described later is also the same), and is rotatably mounted on the inside of the main body 100 via the shaft member 110a. A plurality of blade members 110 for opening and closing the inner space of the main body, and blade rotation mechanisms 120 and 130 for closing the inner space of the main body 100 by rotating the blade member 110 in an open state when a fire occurs. , 140).

The main body 100 constitutes a hollow rectangular parallelepiped shape with an open front facing outward and a rear facing toward the inside, and the front end and the rear end are respectively connected to the duct, so as to connect between the two ducts. On the other hand, the shape of the main body does not necessarily have to be a rectangular parallelepiped shape, and the shape of the fire damper may also be changed according to the shape of the duct in which the fire damper is installed. For example, when installed in a cylindrical duct, the overall external shape of the main body may also be configured in a cylindrical shape.

The blade member 110 is arranged in plurality in the vertical direction in the inner space of the body part 100, and the shaft member 110a disposed on both sides (only one shaft member is shown in FIG. 1, etc.) as a medium, the body part (100) is rotatably mounted on the inside. On the other hand, instead of a plurality of bollade members, one blade member may be mounted on the main body according to an embodiment. On the other hand, in one embodiment of the present invention, the front end and the rear end (in FIG. 1, etc., when viewed from the side of the blade member) of the blade member 100 is configured to be inclined in the opposite direction. Therefore, when the blade member is rotated and closed by the blade rotating mechanism, the front end and the rear end of each blade member are disposed overlapping each other while being inclined. As a result, as the ends of each blade member are disposed obliquely overlapping each other, when viewed from the front or rear side, the gap between the ends of the blade member is substantially eliminated, compared to that the front and rear ends are configured to be flat, flame or It is possible to effectively prevent the toxic gas from propagating through between the blade members.

The blade member 110 is configured to be opened and closed by a blade rotation mechanism. Specifically, the blade rotation mechanism is connected between any of the plurality of blade members (in the illustrated embodiment, the upper blade member) and the main body 100 , and applies a rotational force to rotate the blade member 110 . The elastic member 140, which is connected via a wire member between any of the plurality of blade members (in the illustrated embodiment, the lower blade member) and the main body 100, in normal times, the elastic member 140 ) by restraining the blade member 110 to open the inner space of the main body 100, and when a fire occurs, it is melted (eg, at 70° C.), the force binding the blade member 110 is By interconnecting the fire fuse member 130 and the blade member 110 that are lost to release the restraint of the blade member 110 to allow rotation, the rotation of any blade member is transmitted to another blade member, and a plurality of blades It includes a link member 120 for allowing the members 110 to rotate in cooperation with each other.

In normal times, the fire protection fuse member 130 pulls the blade member 110 in the opposite direction to the elastic force of the elastic member 140 , so that the blade member 110 is maintained in an open state, so that the internal space of the body part 100 is maintained. is opened (Fig. 1). However, when a fire occurs and the temperature rises, the fire protection fuse member 130 is melted, and the upper blade member is rotated by the elastic force of the elastic member 140 , and the rotation of the blade member is caused by the link member 120 . is transmitted by the lower blade member through the lower blade member is also rotated in conjunction with the upper blade member. As a result, the blade member is switched to the closed state, so that the internal space of the main body is closed, and thus it is possible to prevent the propagation of flames, toxic gases, and the like (see FIG. 2 ).

However, fires persist over a relatively long period of time. The fire damper (A) including the blade member 110 is made of a metal material having fire resistance. When this structure is exposed to a flame for a long time, heat can be transferred through the structure, and the edge and body of the blade Flames can propagate through the gap between the fire dampers and the gaps between the fire damper and the structure (duct, wall, etc.) in which the damper is installed. That is, when the fire damper is exposed to flames for a long time, the fire damper cannot support the high temperature, resulting in a problem in that high-temperature heat is transferred to the structure around the fire damper.

In order to effectively reduce heat transfer through the fire damper itself, a thermally expandable fire resistant structure (B) is provided according to the present invention. Specifically, referring to FIG. 3 , the thermally expansible fire resistant structure B includes a support member 10 having a porous structure (net-shaped structure) made of a metal, and a thermally expansible fire resistant material supported by the support member and expanded by heat ( 20). As shown, the supporting member 10 is not simply attached to the surface of the thermally expansible refractory material 20 , but the thermally expansible refractory material 20 extends the opening 10a of the supporting member 10 in the height direction at least partially. It is filled and supported by the supporting member (in the illustrated embodiment, the surface of the thermally expansible refractory material and the open surface of the opening 10a are the same, that is, the thermally expansible refractory material completely fills the opening 10a in the height direction). However, in some embodiments, the refractory material may be supported by the support member while protruding beyond the height of the opening.

More specifically, the thermally expansible refractory material 20 is made of an organic binder and expanded graphite, and it is preferable that the expanded graphite contains 40% or more. In the event of a fire, all of the binder evaporates due to the temperature of the flame, but expanded graphite has a property of expanding 10 to 30 times. The thermally expansible refractory material 20 is flexible and resilient, and may be configured in a flat strap form, a pad form, a film or sheet form, and the blade member 110 and the blade member 110 by mechanical fastening elements such as screws, bolts, clips or adhesives It can be attached or bonded to the same metal surface.

When this thermally expansible refractory material 20 itself is attached to the surface of the blade member 110, due to the expanded graphite when a fire occurs, the thermally expansible refractory material expands approximately 10 to 30 times, and the internal space of the body portion together with the blade member without any gap By sealing, it is possible to prevent flames or the like from spreading through the duct. However, when the fire continues for a relatively long time, such as 1 hour or more, the binder constituting the thermally expansible refractory material evaporates, and the expanded graphite becomes so-called crumbly, and falls from the blade member by gravity. A problem arises that the effectiveness of providing a thermally expandable refractory material decreases with the time of the fire. When the thermally expansible refractory material is attached by means of an adhesive as well as when the thermally expansible refractory material is attached by means of an adhesive, the expanded graphite is separated by gravity due to evaporation of the adhesive, and the expanded graphite is also subjected to gravity except where the fastening element is provided. separated by For this reason, in particular, in the certification test for fire ducts, when exposed to high temperatures for about 2 hours, many fire ducts fail to pass the test.

In the present invention, in order to more stably support the thermally expansible refractory material on the blade member, the support member 10 is provided. As shown in FIG. 3 and the like, the support member 10 has a porous, that is, a net-like structure and is made of a metal material. The thermally expandable refractory material is coupled with the support member while at least partially filling the inside of the opening 10a of the support member. That is, the thermally expandable refractory material is usually manufactured by an extrusion process. The thermally expandable refractory material immediately after being manufactured through the extrusion process is in the form of a somewhat sticky gel. In this state, when the support member 10 of the net-like structure is press-fitted against the thermally expansible refractory material, the thermally expansible refractory material at least partially fills the opening 10a of the supporting member, and then left to stand or dried, the thermally expansible The refractory material is fixedly mounted with respect to the support member, and the thermally expansible refractory structure B is completed. In the thermally expansible refractory structure B, the support member and the thermally expansible refractory material are not separated from each other unless a special external force is applied.

The thermally expandable fire resistant structure (B) manufactured through the above process is mounted on one surface of the blade member 110 (FIG. 4). That is, after disposing the thermally expansible fire resistant structure (B) on one surface of the blade member, the bolt of the fastening element (C) passes through the blade member and the thermally expansible fire resistant structure (B), and then fastens with the bolt using a nut do. Thereby, the thermally expansible fire resistant structure B is fixedly mounted with respect to the blade member 110. As shown in FIG. An embodiment of the fire damper of the present invention in which the thermally expansible fire resistant structure (B) is mounted on the blade member through this process is shown in FIGS. 5 and 6 . 5 and 6 are views corresponding to FIGS. 1 and 2, and since the thermally expandable fire resistant structure (B) is substantially the same except that it is mounted on the blade member, the overlapping description will be omitted.

On the other hand, as shown, according to a preferred embodiment of the present invention, the support member 10 is mounted on the blade member facing the surface of the blade member (110). That is, the thermally expansible refractory material expands several tens of times by heat. When the support member is mounted with the support member facing outward, that is, the thermally expansible refractory material is mounted facing the blade member surface, stable support of the thermally expansible refractory material by the support member 10 during expansion may be affected. Accordingly, in a preferred embodiment of the present invention, the thermally expandable fire resistant structure B is mounted to the blade member by means of a fastening element, with the supporting member 10 side facing the blade member surface.

Fig. 7 is a schematic cross-sectional view showing a fire duct for a duct equipped with a thermally expandable fire resistant structure in a closed state; As shown, when a fire occurs, the fire protection fuse member 130 is melted, and the upper blade member is rotated by the elastic member 140 , and this rotation is caused by the link member 120 to the lower blade member. is transmitted and rotates, and the two blade members are vertically disposed with the inclined ends overlapped, and close the inner space of the main body 110 . In addition, due to the high temperature, the thermally expansible refractory material expands, thereby further sealing the inner space of the body portion together with the blade member. Although it is shown that the refractory material is expanded by about several times in FIG. 7, it actually expands by about 10 to 30 times. On the other hand, the thermally expansible refractory material 20 is supported by the support member 10 . Therefore, even when exposed to a high temperature flame over a long period of time, the thermally expansible refractory material 20 can be stably maintained without being separated from the blade member. That is, when the thermally expansible refractory material 20 is exposed to a high temperature, all of the binder is evaporated. At this time, when the expanded graphite is exposed to high temperature, it is changed to a state of being entangled with each other in the form of a finished skein. At this time, if the support member is not provided, this entangled expanded graphite may fall by gravity, but according to the present invention, these expanded graphite remain entangled with each other within the opening 10a of the support member, and thus the thermally expandable refractory material (20) can be prevented from being separated from the blade member (110). As a result, even if the fire damper A is exposed to a high-temperature flame for a long time, it is possible to prevent high-temperature heat from being transferred through the fire damper, and the high-temperature heat is transferred to the structure around the fire damper, and the temperature of the structure is lowered. rise can be prevented.

As mentioned above, although the present invention has been described with reference to the embodiments, the present invention is not limited to the above embodiments, and can be variously modified and modified within the scope of the claims.

For example, in the above embodiment, the thermally expandable fire resistant structure is provided over the entire surface of the blade member. However, the thermally expansible fire resistant structure may be provided only on a part of the blade surface, or divided into a plurality of straps having a small width and provided on the blade member surface.

Further, in the above embodiment, the thermally expansible fire resistant structure was provided on only one surface of the blade member. However, the thermally expansible fire resistant structure may be provided on both surfaces of the blade member. Further, in relation to the plurality of blade members, the thermally expansible fire resistant structure may be provided on a first surface with respect to any one blade member, and on a second surface opposite to the first surface with respect to the other blade member. That is, in relation to the plurality of blade members, when viewed in a cross-sectional view in a closed state, the thermally expandable fire resistant structures may be alternately provided.

Further, in the above embodiment, the thermally expansible fire resistant structure fixed the supporting member while facing the surface of the blade member for stable support of the fire resistant material. However, the present invention is not limited thereto. For example, by using the double fixing structure, the thermally expansible fire resistant structure may be mounted to the blade member with the fire resistant material facing the surface of the blade member. That is, a fastening member, for example, a bolt having a wide head and a long fastening portion is prepared. Using these bolts, the thermally expansible fire resistant structure is fixed to the blade member with the fire resistant material facing the surface of the blade member. For example, similar to the above embodiment, after the bolt is passed through the thermally expansible fire resistant structure and the blade member, it is fixed using a nut or the like. In this case, an additional adhesive force may be secured by using an adhesive or the like on the fire resistant material facing the surface of the blade member. In this way, in the state in which the thermally expansible fire resistant structure is mounted on the blade member, since the fastening portion of the bolt is long, a long space is secured between the thermally expansible fire resistant structure and the head of the bolt. Therefore, even if the fireproof material expands in case of fire, the support member is constrained by the head of the bolt after it expands through the empty space, and eventually the expanding fireproof material can be stably supported by the support member and the fastening member (bolt).

Further, in the above embodiment, the support member is press-fitted into the refractory material to configure the thermally expansible fire resistant structure in such a way that the refractory material fills at least a part of the opening of the support member, but the present invention is not limited thereto. For example, the thermally expansible fire resistant structure may be configured in a form in which the support member is built into the fire resistant material in the same manner as in the above embodiment or using a separate method.

In addition, although the support member is made of a metal material in the above embodiment, the present invention is not limited thereto. That is, the support member having the above configuration can also be produced from inorganic fibers capable of withstanding a high temperature.

A: Fire damper for duct
100: body part
110: blade member
120: no link
130: fire protection fuse member
140: elastic member
B: Thermally expandable fire resistant structure
10: a support member of a net-shaped structure
10a: opening
20: thermally expandable refractory material

Claims (16)

a body part installed at one end of the duct;
one or more blade members rotatably mounted on the inside of the main body through a shaft member and configured to open and close the inner space of the main body by rotation;
a blade rotating mechanism for rotating the blade member in an open state under a specific condition to close the inner space;
Thermally expandable fire resistant structure mounted on the surface of the blade member and configured to expand when a fire occurs
including,
The heat-expandable fire-resistant structure includes a heat-expandable fire-resistant material that expands by heat, and a support member made of a metal material or inorganic fiber that has a net-like structure in which a plurality of holes are formed and can withstand high temperatures. fire damper. The thermally expansible refractory material and the support member are coupled to each other with the heat-expandable refractory material at least partially filling the opening of the support member, or the support member is embedded within the heat-expandable refractory material fire damper. The fire damper according to claim 2, wherein the thermally expandable fire resistant structure is provided over the surface of the blade member or divided into a plurality of band-shaped members. The fire damper according to claim 3, wherein the thermally expansible fire resistant structure is provided on one or both surfaces of the blade member. The fire damper according to claim 3, wherein the thermally expansible fire resistant structure is alternately provided with respect to the surfaces of the plurality of blade members when viewed in a cross-sectional view in a closed state. The fire damper according to any one of claims 1 to 5, wherein the thermally expandable fire resistant structure is mounted to the blade member with the support member facing the surface of the blade member. The fire damper according to claim 6, wherein the thermally expandable fire resistant structure is mounted to the blade member by a plurality of fastening elements. The fire damper according to any one of claims 1 to 5, wherein the thermally expansible fire resistant structure is mounted to the blade member with the thermally expansible fire resistant material facing the surface of the blade member. The method according to claim 8, wherein the thermally expansible fire resistant structure is mounted to the blade member using a plurality of fastening elements having a wide head and a long fastening portion, and in this mounted state, the thermally expansible fireproofing material is disposed between the support member and the fastening element. Fire damper, characterized in that the expansion space that can be expanded is secured. [6] The fire damper according to any one of claims 1 to 5, wherein the thermally expansible refractory material comprises an organic binder and expanded graphite. [6] The fire damper according to any one of claims 1 to 5, wherein, when each of the blade members is viewed from the side, the front end and the rear end thereof are inclined in opposite directions to be bent. As a thermally expandable fireproof structure for use in a fire damper to prevent the propagation of flames and gases through the duct by being mounted on one end of the duct and converted to a closed state in the event of a fire,
The thermally expansible fire resistant structure is configured to be mounted on the blade member of the fire damper in the form of a band,
The thermally expansible fireproof structure comprises a thermally expansible fireproof material that expands by heat, and a support member having a net-like structure in which a plurality of holes are formed. The thermally expansible refractory material and the support member are coupled to each other with the heat-expandable refractory material at least partially filling the opening of the support member, or the support member is embedded within the heat-expandable refractory material Thermally expandable fire resistant structure. The thermally expandable fire resistant structure according to claim 13, wherein the support member is made of a metal material or inorganic fibers capable of withstanding high-temperature heat. 15. The thermally expansible fire resistant structure according to claim 14, wherein the thermally expansible refractory material comprises an organic binder and expanded graphite. The thermally expansible fire resistant structure according to any one of claims 12 to 15, wherein the thermally expansible fire resistant structure is obtained by press-fitting the supporting member against the fire resistant material after manufacturing the thermally expansible fire resistant structure.

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