KR102505564B1 - Fireproof foam unit and Fireproof foam device having the same - Google Patents

Abstract

A fireproof foam unit is disclosed. The fire-resistant foam unit of the present invention is to shield a through-hole formed in a floor or wall of a building so that a passage member passes through, and includes a fire-resistant foam material that expands when heated to block the through-hole, and when the fire-resistant foam material expands, a fire-resistant foam material unit including a fire-resistant mesh body made of a fire-resistant material and combined with the fire-resistant foam material so that the fire-resistant foam material does not escape from the floor or wall of the building; and a fixed support bracket coupled to the refractory foam member and fixed to the passage member to support the refractory foam member to the passage member. According to the present invention, the fire-resistant foam member is made to have a cross-sectional shape corresponding to the area between the passage member and the inner wall of the through-hole in a state that does not cover the floor or wall of the building, and uses a fixed support bracket and a fixing member to pass through it By fixing to the member, it is possible to stably implement the shielding function while drastically reducing material costs.

Description

Fireproof foam unit and fireproof foam device including the same {Fireproof foam unit and Fireproof foam device having the same}

The present invention is a fire-resistant foam material capable of preventing flame and smoke from spreading through the penetration hole due to a fire by shielding a penetration hole formed in the floor or wall of a building so that passage members such as pipes or ducts can pass therethrough. It relates to a unit and a refractory foam material device including the same.

In general, the internal space of a building is divided into a plurality of spaces by floors and walls, and through-holes through which various pipes or ducts can pass are formed in the framework of the building, such as the floor or walls. The through-hole of the building frame is formed in a size larger than the width of the pipe or duct, so that the pipe or duct can pass through the through-hole even if there is a design error when installing the pipe or duct.

However, since the penetration hole of the building frame is formed in a size larger than the width of the pipe or duct, a gap inevitably forms between the building frame and the pipe or duct during installation of the pipe or duct, and this gap prevents flame or smoke from occurring in the event of a fire. There is a problem of spreading the damage caused by fire by becoming a passage.

In order to solve this problem, it is currently legally compulsory to block the penetration part of the building frame, which can spread the fire in the event of a fire, with a fire-resistant material. Various devices are used as devices for blocking through-holes of building frames for the installation of pipes or ducts.

For example, the device shown in FIG. 1 includes a cover 10 made of synthetic resin or metal and having an open central portion, and a sleeve coupled to the central portion of the cover 10 in a hollow shape so that a duct can pass therethrough. (20). In this device, the cover part 10 is fixed to the wall surface by fixing members such as screws so that the duct is inserted into the sleeve 20, and the fireproof sealant 30 is applied around the cover part 10 and the sleeve 20. is applied

However, these conventional devices are difficult to manufacture, expensive to manufacture, and divided into two or more divided bodies for construction, so construction is difficult and construction costs are high.

In addition, the conventional device must be customized according to the size of the through-hole formed in the building frame or the shape or width of the pipe or duct passing through the through-hole, and if the size of the through-hole, the shape of the pipe or duct passing through the through-hole, etc. When this is changed, it must be newly customized in response to this change, which inevitably leads to poor compatibility and low productivity.

Republic of Korea Patent Registration No. 1743932 (2017. 06. 07 announcement)

The present invention has been devised to solve the above-mentioned conventional problems, and is composed of a compatible structure that can be easily interchanged and used at various work sites to improve construction convenience and to drastically reduce material costs. In addition, it is an object of the present invention to provide a refractory foam unit and a refractory foam device including the same, which can greatly improve installation efficiency due to reduced working hours by having a structure in which workers can easily install the installation site.

According to one aspect of the present invention, a fireproof foam material that blocks a through hole formed in a floor or a wall of a building so that a passage member passes therethrough, expands when heated to block the through hole, and when the fireproof foam material expands, the fire resistant foam material expands. a fire-resistant foam material unit including a fire-resistant net made of a fire-resistant material and combined with the fire-resistant foam material so that the foam material does not escape from the passage member; and a fixed support bracket coupled to the refractory foam member and fixed to the passage member to support the refractory foam member to the passage member.

The fixing support bracket includes first and second contact plates provided to be in close contact with both surfaces of the fire-resistant foam material in the thickness direction, respectively, and capable of holding the fire-resistant foam material; and a fixing plate connected to the first and second contact plates, bent in a direction inclined with respect to the first and second contact plates, fixed to the passage member, and capable of supporting the fireproof foam member with respect to the passage member. can

At least one insertion protrusion piece formed in a wedge shape may be provided on at least one of the first contact plate and the second contact plate so as to be inserted into the fire-resistant foam member at least a certain amount.

The fixing support bracket may be made of a material having a certain level of ductility so as to adjust a distance between the first and second contact plates.

The fixing support bracket may include an L-shaped structure.

A plurality of grooves spaced apart from each other may be provided on at least one of both surfaces of the fire-resistant foam member.

A plurality of the fire-resistant foam parts are disposed in a region between the passage member and the inner wall of the through-hole in a state in which the floor or wall of the building is not covered, and the plurality of fire-resistant foam parts are disposed along the circumferential direction of the passage member. In a continuously arranged state, the combination of the plurality of fireproof foam parts may have a cross-sectional shape corresponding to a region between the passage member and the inner wall of the through hole.

According to another aspect of the present invention, a device for shielding a through-hole formed in a floor or wall of a building so that a passage member passes therethrough, comprising: a fire-resistant foam unit; and a fixing member capable of fixing the fire-resistant foam unit to the passage member.

According to the fire-resistant foam unit of the present invention described above and the fire-resistant foam device including the same, the cross section corresponding to the area between the passage member and the inner wall of the through-hole in a state where the fire-resistant foam part does not cover the floor or wall of the building It is made to have a shape and by fixing it to the passage member using a fixed support bracket and a fixing member, it is possible to stably implement a shielding function while dramatically reducing material costs.

In addition, when fixing the fixing support bracket to the floor or wall of a building using a fixing member, a separate tool is required for fixing, as the floor or wall of the building is generally made of a concrete structure, and more than a certain amount of labor is required to fix it. However, when fixing the fixing member to the passage member made of a metal material, the operator can easily fix the fixing member with relatively little force compared to the case of performing the fixing work on the concrete structure described above.

In addition, by using a fixed support bracket to support the refractory foam member to the passage member, it is possible for the operator to perform the construction easily, and the insertion protrusion is provided on the fixed support bracket to stably grip the refractory foam member during installation work. Safety accidents due to departure can be prevented in advance.

In addition, since the fire-resistant foam material can be easily cut according to the shape of the passage member and the shape of the through hole and placed around the passage member, it can be universally used to shield the through hole in which various types of passage members are installed, and the construction is easy. It is convenient, in particular, since a plurality of grooves are provided in the fire-resistant foam material, the operator can easily cut and use the fire-resistant foam material according to the working environment, and quickly check the construction direction of the fire-resistant foam material, thereby improving the convenience of construction and various It can be easily compatible and used in the workplace.

In addition, since the simple structure of the fireproof net, which is not easily damaged by heat, is supported by the passage member made of metal and supports the fireproof foam material that expands due to heat, the fireproof foam material is not separated from the frame or passage member of the building in the event of a fire. It can expand while covering the through hole of the frame, and can effectively block the propagation of flame or smoke through the through hole of the building frame.

In addition, since the refractory foam material can be supported by combining a refractory mesh that is not easily damaged by heat with the refractory foam material, the unit price is low and the market competitiveness is excellent.

In addition, since the fire refractory foam material has a simple structure in which a thin, bendable refractory net is coupled to the fire refractory foam material, it can be easily deformed and used in various shapes.

1 is a view showing a device for blocking a through-hole portion of a conventional building frame;
2 is an exploded perspective view showing a state in which a fire resistant foam device including a fire resistant foam unit according to an embodiment of the present invention is installed to shield a through-hole of a building;
3 is a perspective view showing a state in which a fire resistant foam device including a fire resistant foam unit according to an embodiment of the present invention is installed to shield a through-hole of a building;
4 is a front view showing a state in which a fire resistant foam device including a fire resistant foam unit according to an embodiment of the present invention is installed to shield a through-hole of a building;
Figure 5 is a cross-sectional side view of Figure 4;
6 is a view showing various installation modifications of a refractory foam device including a refractory foam unit according to an embodiment of the present invention;
7 and 8 are cross-sectional views showing a refractory foam unit according to an embodiment of the present invention;
9 is a cross-sectional view showing a state in which a refractory foam unit according to an embodiment of the present invention is cut into various sizes and used;
10 is a perspective view showing a fixed support bracket of a fireproof foam unit according to an embodiment of the present invention;
11 is a view showing a state in which the fixed support bracket and the fireproof foam member of FIG. 10 are coupled;
12 is a perspective view showing a modified example of FIG. 10;
13 is a view showing a state in which the fixed support bracket of FIG. 12 and the fireproof foam member are coupled.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, only these embodiments will complete the disclosure of the present invention, and will fully cover the scope of the invention to those skilled in the art. It is provided to inform you. Like reference numerals designate like elements in the drawings.

The fireproof foam device according to a preferred embodiment of the present invention is composed of a compatible structure that can be easily interchanged and used at various work sites, thereby improving construction convenience and adopting a structure that can significantly reduce material costs compared to the prior art. In addition, it is structured so that workers can easily install it at the installation site, so the installation efficiency can be greatly improved due to the reduction of working time.

Hereinafter, the present invention will be described in detail with reference to examples.

As shown in FIGS. 2 to 5, the fireproof foam apparatus 100 according to the embodiment of the present invention is formed on the floor or wall of a building so that passage members 50 such as ducts having passages 51 pass therethrough. By shielding the through-hole 60, it is possible to prevent flame or smoke from spreading to the through-hole in the event of a fire.

The refractory foam device 100 includes a refractory foam unit 200 that substantially shields a penetration hole by receiving and expanding high-temperature heat generated in the event of a fire, and the refractory foam unit 200 as a passage member 50. It includes a fixing member 240 that can be fixed to.

The fireproof foam device 100 according to the embodiment of the present invention is fixed and supported by the passage member 50, and the passage member 50 passes through a through hole formed in a building frame such as a pipe, duct, electric cable, or communication cable. It can be applied in various ways to do, and is made of a metal material.

In an embodiment of the present invention, as shown in FIGS. 2 to 5, the refractory foam material unit 200 includes a refractory foam material unit 210 including a refractory foam material 211 and a refractory mesh 212, and a fixed A support bracket 220 is included.

Prior to the detailed description of each configuration, the refractory foam unit 200 has a passage member 50 in the region between the passage member 50 and the inner wall of the through hole 60 as shown in FIGS. 3 to 6 A plurality of are continuously installed along the circumferential direction of, and as shown, it can be installed by applying various shapes and arrangement structures. there is. Hereinafter, the case illustrated in FIG. 4 will be illustrated and described.

First, the refractory foam material 211 can substantially block the through hole 60 by expanding more than a certain amount based on the initial state when heated, and is made in a flat plate shape that can cover the through hole 60 during initial installation. It is made of a thermally expandable material that expands when heated.

In addition, the fire-resistant foam material 211 expands by receiving high-temperature heat in the event of a fire, so that the gap between the wall W and the passage member 50 and the through hole 60 can pass through all flames or smoke. The passage can be effectively shielded. The refractory foam material 211 may be manufactured by extruding a refractory foam mixture in which expanded graphite or various thermally expandable materials are mixed.

Next, the refractory mesh 212 is combined with the refractory foam material so that the refractory foam material 211 does not escape from the passage member 50 when the refractory foam material 211 expands due to heating and is made of a refractory material. The prevention of separation of the refractory mesh 212 from the passage member 50 will be described later.

The refractory net 212 is made of a kind of mesh structure having a plurality of nets, and may be made of various refractory materials having heat resistance of a certain level or more, such as metal or refractory fiber. For example, the refractory net may be made of a metal material.

The refractory mesh 212 may be made of metal (including SUS) wire having a thickness of 0.1 to 0.6 mm.

It is preferable that the thickness T of the refractory foam member 210 is 0.1 to 0.6 mm so that the refractory foam member 210 can be cut with a tool such as scissors. When the thickness of the fire resistant mesh 212 is less than 0.1 mm, the fire resistant mesh 212 has a weak supporting force for supporting the fire resistant foam material 211, making it difficult for the fire resistant mesh 212 to function smoothly. On the other hand, when the thickness of the refractory mesh 212 exceeds 0.6 mm, it is difficult to cut the refractory mesh 212 with a tool such as scissors, and there is a problem in that price competitiveness is low.

The refractory mesh 212 is made of a material that is not easily damaged by high-temperature heat and is combined with the refractory foam material 211, so that the refractory foam material is separated from the refractory mesh while the fire retardant foam material expands due to the occurrence of a fire, and eventually the through hole 60 can be prevented from being separated from the passage member 50 without being shielded. Accordingly, in the event of a fire, the fire-resistant foam material 211 can expand while maintaining the state of covering the through-hole 60 of the wall W, and the propagation of flame or smoke through the through-hole of the wall W can be stabilized. can be blocked with

In an embodiment of the present invention, the refractory foam material 211 and the refractory mesh 212 may be bonded to each other by a compression method, for example. The refractory foam material 211 has a brittle property that can be easily deformed in a high-temperature environment. When the fire resistant foam material 212 is pressed against one surface of the fire resistant foam material 211 in a soft state, at least a portion of the fire resistant foam material 212 penetrates into the fire resistant foam material and is buried in the fire resistant foam material. Therefore, it is possible to combine the fire resistant foam material 211 and the fire resistant mesh 212 without using a separate adhesive or fixing means.

As shown in FIG. 7, the fire resistant foam material 211 and the fire resistant mesh 212 are formed on one side of the fire resistant foam material so that at least a portion thereof is buried in the fire resistant foam material 211 so that a stable coupling state can be maintained. Can be press-fitted. Preferably, the depth at which the fire resistant mesh 212 is buried in the fire resistant foam material 211 is greater than the height at which the fire resistant mesh 212 protrudes from one surface of the fire resistant foam material 211 to ensure stable coupling between the fire resistant foam material and the fire resistant mesh. It is advantageous.

In addition, as shown in FIG. 8 , the fire resistant foam material 211 and the fire resistant net body 212 may be press-coupled so that the entire fire resistant net body 212 is buried in the fire resistant foam material 211 . In this case, when the refractory foam material 211 is cured, it completely covers the refractory mesh 212, so that the refractory mesh 212 becomes invisible from the outside of the refractory foam material 211, and the bonding strength between them can be improved compared to the former. .

In the embodiment of the present invention, as shown in FIGS. 3 to 5, between the passage member 50 and the inner wall of the through-hole 60 in a state where the fire-resistant foam member 210 does not cover the wall W of the building. A plurality is arranged in the region between. The fireproof foam member 210 can effectively block the propagation of flame or smoke by shielding only the passage through which flame or smoke can pass, such as the gap between the wall W and the passage member 50 and the through hole 60. It is possible, for example, to cover in a form partially overlapping the wall W of a building, resulting in waste of material due to an increase in the area of a part unrelated to the function.

As will be described below, the fire-resistant foam member 210 is fixedly supported to the passage member 50 through the fixed support bracket 220 and the fixing member 240, and the fire-resistant foam member 210 covers the wall W of the building. It is continuously arranged along the circumferential direction of the passage member 50 in a state where it is not, and the combination of the plurality of fire-resistant foam parts 210 corresponds to the area between the passage member 50 and the inner wall of the through hole 60, respectively. As it is made to have a cross-sectional shape, it is possible to prevent material waste and reduce product cost.

Here, the "cross-sectional shape corresponding to the region between the passage member 50 and the inner wall of the through-hole 60" means a cross section in which a combination of a plurality of fire-resistant foam parts 210 exactly matches the shape of the region between It does not mean that it is made of shape. As will be explained below, in a state in which the fire-resistant foam member 210 is clamped to the fixed support bracket 220, the gap between one end of the fire-resistant foam member 210 and the passage member 50 is at least as large as the thickness of the fixed support bracket 220. There is a separation region of . Therefore, the "cross-sectional shape corresponding to the area between the passage member 50 and the inner wall of the through-hole 60" means having a cross-sectional shape corresponding to (matching) the rest of the area except for the separation area. do.

On the other hand, in the state in which the construction is completed, Cerak wool (not shown) is provided to surround the passage member 50 in the circumferential direction, such that the separation area is not exposed to the outside, and the fire-resistant foam material is exposed to the heat caused by the fire. 210 expands so that the spaced area is filled.

Here, as shown in FIG. 5, in the fire resistant foam material part 210, one side of the fire resistant foam material 211 to which the fire resistant mesh 212 is coupled faces the outside and the other surface of the fire resistant foam material 211 faces the wall (W). It is relatively adjacent to and fixed to the passage member 50 through the fixing member 240 so as to face the inside of the through hole 60.

In the embodiment of the present invention, the refractory foam material 211 is made of a soft material and has a certain ductility, and the operator cuts the refractory foam material 210 to an appropriate size using a cutting tool such as scissors as needed. It can be used according to the work site. In this way, since the fireproof foam member 210 can be easily cut to implement an appropriate shape, it can be universally used to shield penetration holes in which various types of passage members are installed, and construction is convenient.

In other words, as shown in FIG. 4 , the passage member 50 is disposed at the center of the through hole 60 so that the distance D between the inner wall of the through hole 60 and the passage member 50 is 50 mm. In this case, the operator may cut and use a plurality of fire-resistant foam parts 210 having a width of 50 mm, for example, in the form of a roll having a width of 1,000 mm.

In the present invention, by cutting and using a plurality of fireproof foam parts 210 such that the width is the same as the distance between the inner wall of the through-hole 60 and the passage member 50, the area (dead area) substantially unrelated to the shielding of the through-hole can be reduced. Material waste due to increase can be prevented. Although not shown in the drawing, the gap between the passage member 50 and the fire-resistant foam member 210, the gap between the fire-resistant foam member 210 and the wall W, and between the plurality of fire-resistant foam members 210 adjacent to each other It may be finished with a caulking material such as a fireproof sealant, but is not necessarily limited thereto.

As shown in FIG. 9 , a plurality of grooves 213 spaced apart from each other may be provided on at least one of both sides of the refractory foam member 210 . A plurality of grooves 213 are spaced apart from each other in the width direction of the refractory foam material part 210 and extend in the longitudinal direction, and a worker cuts the refractory foam material part 210 along an appropriate groove among the plurality of grooves 213. and can be used. In other words, depending on the working conditions, the passage member is not disposed in the center of the through-hole, but is biased to one side, so that the distance between the inner wall of the through-hole 60 and the passage member 50 is different for each region along the circumferential direction of the passage member. It may be formed, for example, a worker may use a plurality of refractory foam parts 210 by cutting them to have a width of 60 mm or 40 mm or to have a width of 70 mm or 30 mm.

The groove 213 may be formed by 1) using a separate cutter on at least one surface of a molded article formed by extruding a refractory foam material and pressing and bonding a refractory mesh to the extruded molded product, and 2) extruding the refractory foam material. At least one side of the molded product may be formed by using a separate cutter after simultaneously supplying a refractory net and integrally extruding, and 3) simultaneously supplying a refractory net and integrally extruding and extruding the refractory foam material at the time of extrusion molding of the refractory foam material. Grooves may be formed simultaneously with molding.

In the above description, the case where the plurality of grooves 213 can be provided on at least one of both sides of the fire-resistant foam material, that is, on both sides has been described, but when the fire-resistant foam material 210 is fixed to the wall of a building, the worker It is more preferable that it is provided only on one side in order to easily distinguish the inside and outside of the material 210 .

In other words, in the refractory foam material part 210, one side of the refractory foam material 211 to which the refractory mesh 212 is coupled faces the outside (opposite of the direction toward the inside (inside) of the through-hole) and the As the other surface is fixed to face the inside (inside) of the through-hole 60, the operator must check the orientation of arrangement during installation. When the groove 213 is provided on only one side, it is possible to easily distinguish the inside and outside of the fire-resistant foam member to induce prompt installation by a worker.

The direction of arrangement of the refractory foam member 210 is not the direction in which the expansion of the refractory foam material 211 is limited by the refractory mesh 212 when the fire occurs, but the opposite direction, that is, the refractory net. This is to stably close the through hole 60 by expanding in the direction opposite to the direction in which the sieve is disposed (inward (inward) direction of the through hole).

In the present invention, as the fireproof foam material 211 is made of a certain or more soft and flexible material and can be cut (cut), the cross-sectional size of the passage member 50, the size of the through hole 60, etc. may vary depending on the construction site. Even when variously changed, it is possible to cut the refractory foam member 210 to an appropriate size and place it in an appropriate location for use, so installation compatibility in a work space can be greatly improved.

Next, as shown in FIGS. 3 to 5, the fixed support bracket 220 is coupled to the fire-resistant foam member 210 and fixed to the passage member 50 to substantially set the fire-resistant foam member 210 to the passage member 50. ) to support. In addition, since both the passage member 50 and the fixed support bracket 220 are made of a metal material that is not deformed by being burned by a flame, even if high-temperature heat due to the occurrence of a fire acts, the fixed support bracket 220 ) It is possible to stably maintain a fixedly supported state in the passage member 50.

As shown in FIGS. 3 to 5 , 10 and 11 , the fixed support bracket 220 includes a first contact plate 221 , a second contact plate 222 and a fixing plate 223 .

The first contact plate 221 and the second contact plate 222 are provided to be in close contact with both surfaces of the fire-resistant foam part 210 in the thickness direction, respectively, and can grip the fire-resistant foam part 210 . The fixing plate 223 connects the first contact plate 221 and the second contact plate 222 and is fixed to the passage member 50 through a fixing member, which will be described later. ) is provided.

In the embodiment of the present invention, the fixed support bracket 220 has a certain strength or more, but has a certain ductility so that the operator can easily adjust the distance between the first contact plate 221 and the second contact plate 222. It is preferably made of a metal material.

To elaborate, the operator inserts the fire-resistant foam material part 210 into the inside between the first contact plate 221 and the second contact plate 222, and then the first contact plate and the second contact plate are respectively inserted into the fire-resistant foam material part 210. ) side, it is possible to maintain a state in which the first contact plate and the second contact plate stably grip the refractory foam member 210 by pressing the contact plate to the side. When the operator presses and brings the first and second contact plates into close contact, more than a certain shape deformation is required, and as described above, it is preferably made of a ductile metal material.

Therefore, the operator fixes the fire resistant foam member 223 to the passage member 50 using a fixing member in a state where the first contact plate 221 and the second contact plate 222 hold the fire resistant foam member 210. The foam member 210 may be installed to be stably supported by the passage member 50 .

As shown in FIG. 10, the fixing plate 223 is bent in an inclined direction with respect to the first and second contact plates 221 and 222, for example, in a perpendicularly inclined direction, and is fixed to the passage member 50 so that the passage member ( 50), the fireproof foam member 210 is supported, and the fixing support bracket 220 has an L-shaped structure as a whole by such bending of the fixing plate 223.

Additionally, as shown in FIGS. 12 and 13, at least one of the first contact plate 221 and the second contact plate 222 has a wedge shape to be inserted into the fire-resistant foam member 210 at least a certain amount. One insertion protrusion piece 225 may be provided. The insertion protrusion 225 makes second contact with the first contact plate after a worker spreads the first contact plate 221 and the second contact plate 222 apart at least a certain amount and inserts the refractory foam member 210 therein. When the plates are pressurized and brought into close contact with the refractory foam member portion 210, the refractory foam member portion can be gripped more stably.

The insertion protrusion piece 225 is inserted into the refractory foam member 210 and caught on the refractory foam member 211 and, in some cases, caught on the refractory net 212, so that the mutual bonding force with the refractory foam member is greater than in the former case. This effect can be increased as the weight of the refractory foam member 210 increases.

In other words, when the size and weight of the refractory foam member 210 increase and there is no insertion protrusion 225, the first contact plate 221 and the second contact plate 222 grip the refractory foam member 210. When the operator holds the fixing plate 223 with his or her hand and lifts it in such a state, a phenomenon in which the refractory foam material part is separated downward may occur. However, when the insertion protrusion piece 225 is provided, it is possible to grip more stably by improving the bonding force as described above, thereby increasing work efficiency and preventing safety accidents due to falling of the fireproof foam member. .

Although the case where the insertion protrusion piece 225 is provided only on the first contact plate 221 is shown in the related drawings, it is not limited thereto, and it may be provided on both the first contact plate and the second contact plate, or only on the second contact plate. there is.

Next, as shown in FIGS. 2 to 5, the fixing member 240 fixes the fireproof foam unit 200 to the wall of the building, and specifically penetrates the fixing member fastening hole 224 of the fixing plate 223. By being fastened to the passage member 50, the refractory foam unit 200 can be stably fixed to the passage member and can be applied with a screw nail or the like. The fixing member 240 may be changed into various other structures capable of supporting the refractory foam unit 200 to the passage member 50 by being directly or indirectly coupled to the passage member in addition to the screw nail structure.

In the above, the present invention has been shown and described in relation to preferred embodiments for illustrating the principles of the present invention, but the present invention is not limited to the configuration and operation as shown and described. Rather, it will be appreciated by those skilled in the art that many changes and modifications may be made to the present invention without departing from the spirit and scope of the appended claims.

50: passage member 60: through hole
100: refractory foam unit 200: refractory foam unit
211: fireproof foam material 212: fireproof mesh
213: groove 220: fixed support bracket
221: first contact plate 222: second contact plate
223: fixed plate 225: insertion protrusion
240: fixing member

Claims (8)

Shielding the through-hole formed in the floor or wall of a building so that the passage member passes through,
A refractory foam comprising a refractory foam material that expands when heated to block the penetration hole, and a refractory net made of a refractory material coupled to the refractory foam material so that the refractory foam material does not escape from the passage member when the refractory foam material expands. wealth; and
A fixed support bracket coupled to the refractory foam member and fixed to the passage member to support the refractory foam member to the passage member;
The fixed support bracket,
first and second contact plates provided to be in close contact with both surfaces of the fire-resistant foam material in the thickness direction, respectively, and capable of gripping the fire-resistant foam material; and
A fixing plate connecting the first and second contact plates, bent in an inclined direction with respect to the first and second contact plates, and fixed to the passage member to support the fireproof foam member with respect to the passage member,
At least one insertion protrusion piece formed in a wedge shape is integrally provided on at least one of the first contact plate and the second contact plate so as to be inserted into the fire-resistant foam member at least a certain amount,
The fire-resistant foam part is disposed in a plurality in a region between the passage member and the inner wall of the through-hole in a state in which the through-hole does not directly come into surface contact with the floor or wall surface of a building adjacent to the through-hole,
In a state where the plurality of fire-resistant foam parts are continuously arranged along the circumferential direction of the passage member, the combination of the plurality of fire-resistant foam parts has a cross-sectional shape corresponding to a region between the passage member and the inner wall of the through-hole. Fireproof foam unit to be. delete delete According to claim 1,
The fireproof foam unit, characterized in that the fixed support bracket is made of a material having a certain or more ductility so as to be able to adjust the distance between the first and second contact plates. According to claim 1,
The fireproof foam unit, characterized in that the fixed support bracket comprises an L-shaped structure. According to claim 1,
Fire-resistant foam unit, characterized in that a plurality of grooves spaced apart from each other are provided on at least one of both sides of the fire-resistant foam unit. delete A device for shielding a through-hole formed in the floor or wall of a building so that a passage member passes through,
Claim 1, claim 4, claim 5, any one of the fire-resistant foam material unit of claim 6; and
Fire resistant foam device comprising a fixing member capable of fixing the fire resistant foam unit to the passage member.

Images