KR102412548B1 - fireproof foam sleeve and sleeve assembly for cable tray connection having the same and construction method of fireproof filling structure using the same - Google Patents

Abstract

A sleeve assembly for cable tray connection is disclosed. The sleeve assembly for connecting the cable tray of the present invention is installed in a through hole provided in the floor or wall of a building, and has a structure in which first and second cable trays to which cables are fixed at upper and lower sides can be connected, respectively, in a concrete structure A through hole is formed so that the plurality of cables embedded in the cable tray and fixed to the first and second cable trays pass through the inside, and it expands and expands by heat. sleeve; and a tray coupling portion detachably coupled to the fireproof and foaming sleeve, the first and second cable trays being coupled to each other. According to the present invention, by providing a fireproof foam sleeve capable of foaming and expanding by heat inside the through hole, it is possible for the operator to easily proceed with the fireproof filling construction work for shielding the through hole.

Description

A fireproof foam sleeve and a sleeve assembly for connecting a cable tray including the same, and a fireproof filling structure construction method using the same

The present invention provides a fire-resisting foam sleeve with improved fire resistance performance by completely shielding the through-hole when shielding the inside of a through-hole provided in the floor or wall of a building, a sleeve assembly for connecting a cable tray including the same, and a sleeve assembly using the same It relates to the construction method of the fireproof filling structure.

With the development of industry, the construction of large-scale and high-rise buildings is increasing for the purpose of efficient use of space and creation of high added value. In the construction of these buildings, the limits of public firefighting power are clear, and self-reliance of their own disaster prevention system is an important required performance.

In extinguishing a fire, a mechanical solution such as a sprinkler is called an active system, and a method through architectural solutions such as flame retardancy, fire protection division, and fire-resistance structure is called a passive system. Compared to the active system, the passive system is a more fundamental approach to the occurrence and suppression of fire, suppresses ignition through building materials, the spread and propagation of fire, and saves a certain amount of time required for evacuation from toxic gases, smoke, and heat. It can be secured to prevent personal injury.

Electricity and plumbing facilities are included in all buildings, and there is a through hole to connect these facilities. The fire-resistance filling structure is to prevent the rapid spread of flames or toxic gases to adjacent rooms or floors when a fire occurs in a building. It serves to prevent the spread of fire through

In other words, when constructing a high-rise apartment or building, a sleeve is installed on the floor to make a through hole for cable tray installation on each floor.

An OPEN-type sleeve in which the cable tray is installed through the top and bottom, and an integrated sleeve connected to the cable tray through separate brackets at the top and bottom without the cable tray going through the top and bottom are applied.

Among them, as shown in FIG. 1 , when the cable tray 20 is installed by applying the OPEN type sleeve 10 , the cable tray 20 is almost in close contact with the back (rear inner surface) of the sleeve 10 . It is installed through the

After that, the operator fixes the cable to the rung 21 of the cable tray 20 and performs the cable installation work, and then installs a fire-resistant charging structure using the fire-proof foam pad 40 in the inner space of the sleeve, as shown in FIG. As shown, due to the close contact state between a pair of support bars of the cable tray and the rear inner surface of the sleeve, a work space (work space for installing a fire protection foam pad) for a fire-resistant charging structure on the rear side of the cable does not come out. For reference, the fire protection foam pad 40 can be charged at least once inside the sleeve according to a change in the height of the sleeve 10, and FIG. 1 shows a case where it is charged twice.

In other words, the operator performs the fire protection foam pad installation work to shield the through hole inside the sleeve from the front side of the cable. Due to the fact that it does not come out, it is difficult to perform the fire protection foam pad installation work on the rear side of the work cable 50 .

Republic of Korea Patent Publication No. 10-1984860 (Notice on May 31, 2019)

The present invention has been devised to solve the above-mentioned problems of the prior art, and by providing a sleeve assembly of a structure and material capable of shielding the through hole by foaming and expanding by heat in a through hole provided in the floor or wall of a building, the operator can A fire-resistant foam sleeve that can completely and completely secure the fire-resistance charging structure performance by making the shielding work for fire-resistance charging of the through-hole (inner region of the sleeve assembly) easier and more complete, and connection of a cable tray including the same An object of the present invention is to provide a sleeve assembly for and a method for constructing a fire resistant filling structure using the same.

According to one aspect of the present invention, it is installed in a through hole provided in the floor or wall of a building and has a structure in which first and second cable trays to which cables are fixed at upper and lower sides, respectively, can be connected, and are embedded in a concrete structure, a fireproof foam sleeve including a foamable material having a through hole formed so that the plurality of cables fixed to the first and second cable trays pass through the inside, and expandable by heat to shield the inside of the through hole; and a tray coupling part detachably coupled to the fireproof and foaming sleeve, the first and second cable trays being respectively coupled to each other.

The fire-resisting foam sleeve may include: a sleeve body having a through-shaped opening with upper and lower ends, molded through injection molding made of the foam material, and provided with a plurality of bolt through-holes on both sides, respectively; and a plurality of bolts coupled to the sleeve body in a state of being inserted into the bolt through-hole, embedded in the concrete structure during concrete pouring, and capable of fixing the head portion by the concrete structure.

The sleeve body may further include a nut coupled to the inside of the bolt through hole for coupling with the bolt.

The sleeve body may be molded in a state in which the nut is integrated through insert injection.

The tray coupling portion is disposed on both sides of the inner side of the sleeve body, a plurality of bolt insertion holes are provided so that the plurality of bolts can be inserted therethrough, and a plurality of screws are fastened so as to be respectively screwed with the first and second cable trays. a coupling bracket made of a metal material in which a hole is provided; and a fixing nut coupled to the body portion of the bolt to couple and fix the coupling bracket to the sleeve body.

The sleeve body may be integrally provided with at least one additional cable insertion portion made of a foam material that is expanded and expanded by heat and provided with a preliminary through-hole to allow the additional cable to pass in the vertical direction.

The additional cable insertion part may be integrally made of the same material as that of the sleeve body.

The sleeve body and the additional cable insertion part may be integrally molded through one injection.

The sleeve body may include: a front plate in which the at least one additional cable insertion part is integrally provided with an overall rectangular frame shape penetrating up and down; a rear plate spaced apart from the front plate; a left plate coupled to one end of each of the front plate and the rear plate; a right plate coupled to the other ends of the front plate and the rear plate; and a plate coupling unit coupling the front plate, the rear plate, the left plate and the right plate to each other.

The plate coupling part is a coupling screw, or a plurality of first coupling protrusions provided at both ends of the front plate and the rear plate, respectively, and the plurality of first coupling protrusions are respectively provided at both ends of the left plate and the right plate so that they are respectively inserted a plurality of first coupling grooves or first coupling holes, or a plurality of second coupling protrusions provided at both ends of the left and right plates, respectively, and the plurality of second coupling protrusions to be respectively inserted into the front plate and the rear plate It may be a plurality of second coupling grooves or second coupling holes respectively provided at both ends of the.

According to another aspect of the present invention, there is provided a fireproof charging structure construction method for shielding a through hole provided in a floor or wall of a building, (a) of a sleeve assembly for connecting a cable tray to a formwork for forming the floor or wall of the building fixing the fire-resistant foam sleeve; (b) pouring concrete so that the head portion of the bolt is embedded in the concrete structure and fixed by the concrete structure; (c) coupling the tray coupling portion to the body portion of the bolt protruding into the inner space of the fire-resistant foam sleeve and fixing the combination with the fire-resistant foam sleeve; (d) coupling and connecting the first and second cable trays to the upper and lower sides of the tray coupling part, respectively, and fixing a plurality of cables to the first and second cable trays so as to penetrate the inside of the fireproof and foaming sleeve ; and (e) installing a fire protection foam pad inside the fire resistant foam sleeve to block the inner through hole of the fire resistant foam sleeve.

In step (e), the fire-resistant foam pad is compressed and inserted into the fire-resistant foam sleeve, and the fire-resistant foam pad presses the plurality of cables so that the cable is in close contact with the inner surface of the fire-resistant foam sleeve. have.

In step (e), the at least one additional cable insertion part may be formed in a shape that protrudes upward by a certain amount or more with respect to the fire protection foam pad.

According to another aspect of the present invention, it is installed in a through hole provided in the floor or wall of a building, is embedded in a concrete structure, a through hole is formed to pass through the inside, and expands by foaming and expansion by heat to shield the inside of the through hole A fire-resistant foam sleeve comprising a foamable material is provided.

According to the fire-resisting foam sleeve of the present invention described above, the sleeve assembly for connecting the cable tray including the same, and the fire-resistant charging structure construction method using the same, by providing a fire-resistant foam sleeve capable of foaming and expanding by heat inside the through hole, an operator can use the through hole It is possible to easily proceed with the fire-resistance filling construction work to shield the

In other words, since the cable can be installed in close contact with the fire-resisting foam sleeve by means of the fire-resistant foam pad, even if the operator installs the fire-resistant foam pad on the front side of the cable within the through hole of the fire-resistant foam sleeve, the fire-resistant foam pad and the fire-resistant foam sleeve By wrapping the cable in the circumferential direction, fire-resistance shielding work can be performed perfectly.

In addition, since the additional cable insertion unit is provided, when additional cable installation is required after the cable installation work and the fire protection foam pad installation work are completed, the additional cable can be easily installed without dismantling the fire protection foam pad.

1 is a cross-sectional view showing a fire resistant filling construction structure in a sleeve according to the prior art;
2 is a cross-sectional view showing a state in which fireproof charging construction is made using a sleeve assembly for connecting a cable tray according to an embodiment of the present invention;
3 is a front view showing a state in which fire-resistance charging construction is made using a sleeve assembly for connecting a cable tray according to an embodiment of the present invention;
4 is a perspective view showing a state in which the cable tray is connected to the sleeve assembly for connecting the cable tray according to an embodiment of the present invention;
Figure 5a is an exploded perspective view showing a sleeve assembly for connecting a cable tray according to an embodiment of the present invention, Figure 5b is a perspective view showing a front plate in the sleeve assembly;
6 to 10 are views sequentially showing a method for constructing a fire resistant charging structure using a sleeve assembly according to an embodiment of the present invention;
11 is a plan view after the construction method of the fire resistant filling structure using the sleeve assembly according to the embodiment of the present invention is completed.

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 allow the disclosure of the present invention to be complete, and the scope of the invention to those of ordinary skill in the art completely It is provided to inform you. In the drawings, like reference numerals refer to like elements.

According to a preferred embodiment of the present invention, a fire resistant foam sleeve, a sleeve assembly for connecting a cable tray including the same, and a method for constructing a fire resistant charging structure using the same include installing a cable tray to be connected to a sleeve installed in a through hole provided on the floor or wall of a building A structure and a construction method are provided so that the operator can perform the shielding operation for fireproof filling of the through hole more easily and perfectly after the completion of the process.

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

2 to 4, the sleeve assembly 200 (hereinafter referred to as the sleeve assembly) for connecting the cable tray according to the embodiment of the present invention is installed in the through hole 100 provided in the floor or wall of the building, It has a structure capable of connecting the first and second cable trays 140 and 150 to which the cables 120 are fixed at the upper and lower sides, respectively.

In general, the sleeve includes an open-type sleeve that is opened in the vertical direction so that the cable tray penetrates vertically, and an integral sleeve that is connected through rails from the top and the bottom without the cable tray passing through. In the embodiment of the present invention, the sleeve body 212 of the sleeve assembly 200 described below corresponds to the latter, the integral sleeve.

2 to 4, the sleeve assembly 200 according to the embodiment of the present invention is detachably coupled to the fire-resistant foam sleeve 210, and the fire-resistant foam sleeve 210 embedded in the concrete structure, and the second The first and second cable trays 140 and 150 include a tray coupling unit 260 that can be coupled.

First, the fire-resistant foam sleeve 210 is embedded and fixed in a concrete structure, and a through hole ( 211) is formed.

This fireproof foam sleeve 210 includes a foamable material that can be expanded and expanded by heat to shield the inside of the through hole 100 by itself, and may be manufactured through an injection molding process. Specifically, the fire-resistant foam sleeve 210 expands in a direction to close the through hole 100 by fire heat.

In an embodiment of the present invention, the fire-resistant foam sleeve 210 contains a thermal foam material by itself, unlike the existing metallic sleeve. 100), it is possible to more effectively block movement from one space to the other space, and more details will be described later.

Specifically, as shown in FIGS. 2 to 5 , the fire-resistant foam sleeve 210 includes a sleeve body 212 and a plurality of bolts 250 .

First, the sleeve body 212 has a through hole 211 formed therein, and is formed in a through shape with open top and bottom, is made of a foamable material and is molded through injection, and a plurality of bolt through holes 213 are provided on both sides, respectively. In the embodiment of the present invention, as the sleeve body 212 is made of a thermally foamable material that expands and expands by heat as described above, it expands by heat in the event of a fire to close the through hole 100 of the floor or wall of the building. It can block the propagation of flame and smoke by completely shielding it.

In the embodiment of the present invention, as shown in Figs. 3 to 5, the sleeve body 212 is made of a foam material that expands and expands by heat, and a preliminary through-hole 216 to allow the additional cable 121 to pass in the vertical direction. ) may be provided integrally with at least one additional cable insertion part 215 provided.

This additional cable insertion part 215 is the through hole 100, that is, the inner through hole 211 of the sleeve body 212 so that the fire protection foam pad 400 blocks the propagation of flame and smoke in the description of the construction method to be described later. In the state where the installation is completed to close, if there is a need to additionally install an additional cable 121 in addition to the cable 120 fixed to the first and second cable trays 140 and 150, the fire protection foam pad 400 is separated and It is prepared to enable this without the reinstallation process.

The additional cable insertion unit 215 is made in the form of a hollow tube having a preliminary through-hole 216 formed therein, and an electric wire, a communication line, etc. may be inserted through the preliminary through-hole 216 as an additional cable. Here, the additional cable insertion unit 215 is in a state in which the fire protection foam pad 400 is installed, and in particular, the upper end of the additional cable insertion unit 215 protrudes upward more than a certain amount with respect to the upper surface of the fire protection foam pad 400 . It is desirable to have Accordingly, the operator can more easily insert the additional cable 121 into the additional cable insertion portion when necessary. A related amplification will be described later.

In an embodiment of the present invention, the additional cable insertion part 215 is made of the same material as the sleeve body 212 and may be integrally formed during an injection molding process for manufacturing the sleeve body 212 .

The additional cable insertion unit 215 has a problem in that it functions as a propagation path for flames and smoke in case of fire unless the preliminary through hole 216 is formed on the inside and the preliminary through hole is not closed, but the additional cable insertion unit 215 is As the sleeve body 212 is made of a material expandable by heat, it is expanded by the heat of fire, so that the preliminary through-hole 216 can be closed to block the propagation of flames and smoke.

Additionally, when an additional cable is not inserted into the preliminary through-hole 216 , a fire resistant sealant is applied to the inside of the preliminary through-hole 216 to close the preliminary through-hole, or a rubber cap is placed on the upper end of the additional cable insertion part 215 . (not shown) may be mounted to block the opening of the preliminary through-hole 216 .

4 and 5, in one embodiment of the present invention, the sleeve body 212 is formed in the overall rectangular frame shape penetrating up and down.

Specifically, as an example, the sleeve body 212 includes a front plate 220 , a rear plate 221 , a left plate 222 , a right plate 223 , and a plate coupling part 225 , and the plurality of plates In some of them, a separate flange 240 is provided for fixing and installing the sleeve body 212 to a formwork (not shown) for forming a floor or wall of a building in a construction method to be described later. A bolt fastening hole is provided so that the bolt is through-fastened for fixing of the .

In an embodiment of the present invention, for example, the sleeve body 212 is fixed to the formwork in a state in which the above-described four plates are respectively manufactured through an individual injection process and then coupled to each other through a plate coupling part 225 to become integral with each other. can be

However, the present invention is not limited thereto, and as another example, the sleeve body 212 may have a rectangular frame-shaped structure having a through-hole formed at a time through one injection process, and upon completion of one injection, the sleeve body 212 has an additional cable The insertion part 215 is also provided integrally. That is, the sleeve body 212 and the additional cable insertion part 215 are integrally molded through one injection.

In the former case, since the space occupied by the former can be reduced compared to the latter case by separately injecting and manufacturing four thin plates, there is an advantage in storage and transport. Hereinafter, the former case will be described in detail.

The front plate 220 is provided integrally with at least one additional cable insertion part 215 , and the rear plate 221 is spaced apart from the front plate 220 by a predetermined interval.

The left plate 222 is coupled to one end of each of the front plate 220 and the rear plate 221 , and the right plate 223 is coupled to the other end of each of the front plate 220 and the rear plate 221 .

As shown in Figures 4 and 5, the plate coupling portion 225 is to couple the front plate 220, the rear plate 221, the left plate 222 and the right plate 223 to each other, as follows It can be applied in various forms.

For example, although not specifically shown in the drawings, the plate coupling part is applicable as a coupling screw (not shown) for connecting and fixing each adjacent plate to each other.

As another example, as shown in FIGS. 4 and 5 , the plate coupling part 225 includes a plurality of first coupling protrusions 231 provided at both ends of the front plate 220 and the rear plate 221 , respectively, and a plurality of It may be applied as a plurality of first coupling grooves 232 provided at both ends of the left plate 222 and the right plate 223 so that the first coupling protrusions 231 of the are respectively inserted correspondingly.

Here, the first coupling protrusion 231 can be fixed through forced press-fitting into the first coupling groove 232, and in this way, when the first coupling protrusion and the first coupling groove structure are employed, the above-described coupling screw (not shown) is used. Compared to the applied case, the operator can more quickly and easily combine the respective plates at the job site to increase the working efficiency. That is, the front plate 220 , the rear plate 221 , the left plate 222 and the right plate 223 are forced by the first coupling protrusion 231 and the first coupling groove 232 without the need for other coupling means. Bonding to each other is achieved through press-fitting.

Here, the first coupling groove 232 may be applied as a first coupling hole.

As another example, although not specifically shown in the drawings, the plate coupling portion includes a plurality of second coupling protrusions (not shown) provided at both ends of the left plate 222 and the right plate 223, respectively, and a plurality of second coupling protrusions. (not shown) may be applied as a plurality of second coupling grooves (not shown) respectively provided at both ends of the front plate 220 and the rear plate 221 so that they are respectively inserted correspondingly.

Here, the second coupling groove may be applied as a second coupling hole.

This structure is a case in which the formation positions of the above-described first coupling protrusion and the first coupling groove are changed opposite to each other, and the effective part generated by this is the same as described above.

Next, as shown in Figures 3 to 5, the bolt 250 is coupled to the sleeve body 212 in a state inserted into the bolt through hole 213 of the sleeve body 212, and when concrete is poured, the concrete structure ( It is embedded in the floor or wall of the building) and the head part can be fixed by the concrete structure.

That is, in the construction process, the sleeve body 212 is first fixed to the mold, and then the bolt 250 is inserted into the bolt through hole 213. It is preferable to have a length of more than a certain length so that it can be fastened and to have a state protruding more than a certain amount toward the inner central direction of the sleeve body 212 .

Thereafter, concrete is poured into the formwork and the sleeve body 212 is embedded in the concrete structure formed by pouring and fixed. In this process, the head of the bolt 250 is fixed in a state embedded in the concrete structure as well. In this state, the tray coupling part 260 may be coupled and fixed to the body part of the bolt 250 , and related details will be described later.

As will be described in detail below, the bolt 250 is preferably disposed in a substantially horizontal state, specifically, in a state approximately perpendicular to the inner wall of the sleeve body 212 in a state where it is embedded and fixed to the concrete structure. If the bolt 250 is disposed in an inclined state, it may be difficult to easily couple the tray coupling part 260 in a set posture, which may cause a problem.

On the other hand, after fixing the sleeve body 212 to the formwork and simply inserting the bolt 250 into the bolt through hole 213, when concrete is poured, the concrete to be poured presses the head of the bolt 250 or more to cure the concrete. After the bolt 250 may not be able to maintain a horizontal posture, it may be disposed in an inclined state.

In order to prevent such a problem from occurring, as shown in FIG. 3 , the sleeve body 212 preferably further includes a nut 214 coupled to the inside of the bolt through hole 213 for coupling with the bolt 250 . do.

In an embodiment of the present invention, the sleeve body 212 may be molded in an integrated state with the nut 214 through insert injection, and the bolt 250 before concrete pouring is coupled to the nut 214 to achieve a horizontal state. By maintaining it stably, even if the head of the bolt is pressed by the concrete being poured, the bolt 250 can be arranged in a horizontal state (a state approximately perpendicular to the inner wall of the sleeve body).

Next, as shown in FIGS. 2 to 5 , the tray coupling part 260 is detachably coupled to the fireproof foam sleeve 210 , and the first and second cable trays 140 and 150 are provided to be coupled respectively. .

The tray coupling part 260 includes a coupling bracket 261 and a fixing nut 267 .

The coupling bracket 261 is made of a metal material and is made of a pair so as to be respectively disposed on both sides of the inner side of the sleeve body 212 . Specifically, the coupling bracket 261 is disposed in a state of being in surface contact with the inner surfaces of the left plate 222 and the right plate 223 , and a plurality of bolt insertion holes 262 so that a plurality of bolts 250 can be inserted therethrough. ) is provided, and a plurality of screw fastening holes 265 having a long hole shape are provided so as to be screw-coupled to the first and second cable trays 140 and 150, respectively.

The first and second cable trays 140 and 150 are respectively coupled to the upper and lower sides of the coupling bracket 261. Separate bolts in a state where the screw fastening hole 265 and the fastening hole formed in the first and second cable trays penetrate each other. , the coupling is made through a nut.

The bolt insertion hole 262 is formed to communicate with the first bolt insertion hole 263 of the long hole type and one end of the first bolt insertion hole 263 and has a substantially circular shape. It includes a second bolt insertion hole 264 having an enlarged diameter compared to the width.

When describing the coupling process of the coupling bracket 261 to the sleeve body 212 , the operator operates the coupling bracket so that the body portion of the bolt 250 fixed to the sleeve body 212 passes through the second bolt insertion hole 264 . After positioning the 261, when the hand holding the coupling bracket is released, the coupling bracket 261 moves downward by its own weight and the body portion of the bolt 250 is guided to the other end of the first bolt insertion hole 263. It is in a state in which the coupling bracket 261 is spanned on the body portion of the bolt 250 . According to the present invention, by providing a second bolt insertion hole 264 having an enlarged diameter compared to the first bolt insertion hole 263, a worker can quickly attach the coupling bracket 261 to the sleeve body 212 at the work site. It can be combined to improve the working speed.

Next, the fixing nut 267 is coupled to the body portion of the bolt 250 to firmly couple and fix the coupling bracket 261 with respect to the sleeve body 212 .

Hereinafter, a method for constructing a fire resistant filling structure using a sleeve assembly according to an embodiment of the present invention will be described.

As shown in FIGS. 2 and 3 , in the fire resistant charging structure construction method using the sleeve assembly according to the embodiment of the present invention, the sleeve assembly 200 is installed in the through hole 100 provided in the floor or wall of the building, and then After installing the first and second cable trays 140 and 150 and completing the cable installation work, the through hole 100 , that is, the inner through hole of the sleeve body, is shielded from one area to the other area based on the sleeve assembly 200 . This is a method to block the spread of flame and smoke caused by fire.

The fire resistant filling structure construction method using the sleeve assembly according to the embodiment of the present invention comprises a fire resistant foam sleeve fixing step (S100), a concrete pouring step (S200), a tray coupling section fixing step (S300), first and second cable trays and It includes a cable installation and fixing step (S400), a fire protection foam pad installation step (S500).

First, as shown in FIG. 6, the fire-resistant foam sleeve 210 of the sleeve assembly 200 for connecting the first and second cable trays 140 and 150 to the formwork for forming the floor or wall of the building is fixed (S100) ). In step S100, the fire-resistant foam sleeve 210 is fixedly coupled to the formwork using bolts or the like. At this time, the bolt 250 is coupled to the sleeve body 212 .

Next, as shown in FIG. 7, by pouring and curing the concrete, the head portion of the bolt 250 is embedded in the concrete structure and fixed by the concrete structure, as well as a penetration that functions as a passage to penetrate the cable in the vertical direction. A sphere 100 is formed (S200).

Next, as shown in FIG. 8 , the tray coupling part 260 is coupled using a nut to the body part of the bolt 250 protruding toward the inner space of the fireproof foam sleeve 210 , that is, the sleeve body 212 . to be coupled and fixed with the fire-resistant foam sleeve 210 (S300).

Next, as shown in FIG. 9 , the first and second cable trays 140 and 150 are respectively coupled to the upper and lower sides of the tray coupling unit 260 using bolts, nuts, etc. and connected, and the fire-resistant foam sleeve 210 ) A plurality of cables 120 are fixed to the first and second cable trays 140 and 150 so as to penetrate inside (S400). Here, the cables 120 such as electric lines and communication lines can be fixed to the rung of the cable tray through a cable tie. In addition, the cable is fixed to the cable tray through a cable tie or the like after the cable tray is installed first.

Next, as shown in FIG. 10 , the fire protection foam pad 400 is placed inside the fire resistant foam sleeve 210 to block the through hole 100 , that is, the inner through hole 211 region of the fire resistant foam sleeve 210 at least. It is installed more than once (S500).

Specifically, in a state where the cable 120 and the additional cable insertion part 215 disposed in the through hole 100 do not interfere with the installation work of the fire protection foam pad 400, It can be installed in the through hole 211 of the 210 to cover the through hole with the fire protection foam pad 400 (sealing).

The fire-resistant foam pad 400 substantially shields the through-hole 211 of the fire-resistant foam sleeve 210, and is interfered by the cable 120 and the additional cable insertion part 215 to form the through-hole 211 as a whole. This should be done so that a situation where the shielding fails does not occur.

To this end, in an embodiment of the present invention, the fire protection foam pad 400 may be formed in a form having more than a certain degree of ductility, for example, may have a form such as a sponge, and inserted into the through hole 211 in a compressed state. Thus, the through-hole is reliably shielded. The fire-resistant foam pad 400 is a fire-resistant charging structure, and when the temperature rises when a fire occurs, it expands in the same way as the sleeve body 212 .

In other words, when a fire occurs in one space with respect to the floor or wall, the fire protection foam pad 400 expands by receiving heat to more firmly close the through hole 100 , that is, the through hole 211 . By holding it, it is possible to prevent the spread of flames and smoke into the space on the other side. The fire protection foam pad 400 has a shape and structure that is elastically contracted when an operator applies a compressive force or more.

After the fire protection foam pad 400 is installed to cover the through hole 211, a fire resistant sealant (not shown), etc. may be provided for sealing between the fire protection foam pad 400 and the fire resistant foam sleeve 210, which are in contact with each other. have.

As described above, the fire protection foam pad 400 has a characteristic that can be elastically compressed and restored over a certain period. It can be completely and stably closed without failing to close partially.

In the embodiment of the present invention, in step S500, as shown in FIG. 10, the operator compresses the fire protection foam pad 400 and inserts it into the fire resistant foam sleeve 210, and the fire foam pad 400 is a plurality of The cable 120 is pressed backward so that the rear side of the cable 120 is in close contact with the fire-resistant foam sleeve 210 made of a thermally foamed material, specifically, the sleeve body 212 .

In addition, as shown in FIGS. 10 and 11, as the cable 120 is in close contact with the sleeve body 212 by the fire protection foam pad 400, the fire protection foam pad 400 and the sleeve body 212, Specifically, the rear plate 221 is formed to surround the cables 120 in a circumferential direction in a state of being in close contact with the plurality of cables 120 .

By such installation, the fire protection foam pad 400 and the sleeve body 212 can completely shield the penetration hole 100 of the floor or wall without interference by cables, etc., thereby reliably blocking the propagation of flames and smoke.

In addition, in step S500, the at least one additional cable insertion part 215 is formed in a shape that protrudes upward more than a certain amount with respect to the fire protection foam pad 400 . Accordingly, when additional installation of the additional cable 121 is required, the operator installs the additional cable 121 from the upper side to the lower side, or from the lower side to the upper direction without disassembling the pre-installed fire protection foam pad 400 . It can be easily inserted. On the other hand, if additional installation of the additional cable 121 is not required, it is applied to the opening of the additional cable insertion unit 215 through a fireproof sealant, etc. to block the insertion hole of the auxiliary cable insertion unit with a fireproof sealant or combine a rubber cap can be prevented

In the foregoing, the present invention has been shown and described in connection with preferred embodiments for illustrating the principles of the present invention, but the present invention is not limited to the construction and operation as shown and described as such. Rather, it will be apparent to those skilled in the art that many changes and modifications can be made to the present invention without departing from the spirit and scope of the appended claims.

10: sleeve 20: cable tray
40: fire foam pad
50: cable 100: through hole
120: cable 121: additional cable
140: first cable tray 150: second cable tray
200: sleeve assembly 210: fire-resistant foam sleeve
211: through hole 212: sleeve body
213: bolt through hole 214: nut
215: additional cable entry 220: front plate
221: rear plate 222: left plate
223: right plate 225: plate coupling portion
231: first coupling protrusion 232: first coupling groove
250: bolt 260: tray coupling portion
261: coupling bracket 267: fixing nut
400: fire foam pad

Claims (14)

It is installed in a through hole provided in the floor or wall of a building, and has a structure capable of connecting first and second cable trays in which cables are fixed at upper and lower sides, respectively,
A through hole is formed so that a plurality of cables embedded in a concrete structure and fixed to the first and second cable trays pass through the inside, and it expands by foaming by heat and contains a foamable material capable of shielding the inside of the through hole fire-resistant foam sleeves; and
It is detachably coupled to the fireproof and foam sleeve, and the first and second cable trays each include a coupleable tray coupling unit,
The fire-resistant foam sleeve,
a sleeve body having an upper and lower open penetrating shape and made of the foamed material and molded through injection; and
A plurality of bolts coupled to the sleeve body in a state of being inserted into the bolt through-hole, embedded in the concrete structure during concrete pouring, and capable of fixing the head portion by the concrete structure,
The sleeve body for cable tray connection, characterized in that the at least one additional cable insertion portion made of a foam material that expands and expands by heat and provided with a preliminary through-hole for the additional cable to pass in the vertical direction is integrally provided. assembly. delete According to claim 1,
The sleeve body,
The sleeve assembly for cable tray connection, characterized in that it further comprises a nut coupled to the inside of the bolt through hole for coupling with the bolt. 4. The method of claim 3,
The sleeve body is a sleeve assembly for cable tray connection, characterized in that the nut is molded in an integrated state through insert injection. According to claim 1,
The tray coupling portion,
Metal disposed on both sides of the inner side of the sleeve body, a plurality of bolt insertion holes are provided so that the plurality of bolts can be inserted therethrough, and a plurality of screw fastening holes are provided so as to be screw-coupled to the first and second cable trays, respectively material bonding bracket; and
and a fixing nut coupled to the body of the bolt to couple and fix the coupling bracket to the sleeve body. delete According to claim 1,
The sleeve assembly for cable tray connection, characterized in that the additional cable insertion part is integrally made of the same material as the sleeve body. According to claim 1,
The sleeve assembly for cable tray connection, characterized in that the sleeve body and the additional cable insertion part are integrally molded through one injection. According to claim 1,
The sleeve body is made of a rectangular frame shape as a whole that penetrates up and down,
a front plate integrally provided with the at least one additional cable insertion part;
a rear plate spaced apart from the front plate;
a left plate coupled to one end of each of the front plate and the rear plate;
a right plate coupled to the other ends of the front plate and the rear plate; and
and a plate coupling part for coupling the front plate, the rear plate, the left plate and the right plate to each other. 10. The method of claim 9,
The plate coupling portion,
a bonding screw, or
A plurality of first coupling grooves or first coupling grooves respectively provided at both ends of the left plate and the right plate so that the plurality of first coupling protrusions respectively provided at both ends of the front plate and the back plate and the plurality of first coupling protrusions are respectively inserted 1 coupling hole,
A plurality of second coupling grooves or first coupling grooves respectively provided at both ends of the front plate and the back plate so that a plurality of second coupling protrusions respectively provided at both ends of the left plate and the right plate and the plurality of second coupling protrusions are respectively inserted 2 Sleeve assembly for cable tray connection, characterized in that the coupling hole. A fireproof filling structure construction method for shielding a through hole provided in a floor or wall of a building, comprising:
(a) fixing the fire-resistant foam sleeve of the sleeve assembly for connecting the cable tray of claim 1 to the formwork for forming the floor or wall of the building;
(b) pouring concrete so that the head portion of the bolt is embedded in the concrete structure and fixed by the concrete structure;
(c) coupling the tray coupling portion to the body portion of the bolt protruding into the inner space of the fire-resistant foam sleeve and fixing the combination with the fire-resistant foam sleeve;
(d) coupling and connecting the first and second cable trays to the upper and lower sides of the tray coupling part, respectively, and fixing a plurality of cables to the first and second cable trays so as to pass through the inside of the fire-resistant foam sleeve ; and
(e) installing a fire protection foam pad inside the fire resistant foam sleeve to block the inner through hole of the fire resistant foam sleeve. 12. The method of claim 11,
In step (e),
Using a sleeve assembly, characterized in that the fire protection foam pad is compressed and inserted into the fire resistant foam sleeve, and the fire foam pad presses the plurality of cables so that the cables are in close contact with the inner surface of the fire resistant foam sleeve. Construction method of fireproof filling structure. 12. The method of claim 11,
In step (e),
The fire resistant charging structure construction method using the sleeve assembly, characterized in that the at least one additional cable insertion part is formed in a shape that protrudes upward by a certain amount or more with respect to the fire protection foam pad. delete

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