KR102042337B1 - Fireproof filling structure of building through-hole for prevention of interlayer fire spread - Google Patents

Abstract

The present invention relates to a vertical pipe-through fire-resistant structure for preventing the spread of fire between floors, and more particularly, vertical pipe or duct for the treatment of vertical water supply, heating, hot water supply, sewage, etc. leading to the floor and ceiling of the building. It is provided between the penetration part and the vertical pipe which are installed at the bottom of the building for the installation of lamps, etc. will be.
The vertical pipe through-fire refractory filling structure (1) for preventing the spread of fire between the layers of the present invention is a predetermined width, a predetermined thickness and a predetermined length that can cover the pipe with the adhesive applied to the lower surface of the front surface. An upper foaming agent 230 and a lower foaming agent 220 which are refractory fillers on the front surface of the aluminum foil 210 having a rectangular inorganic insulating material sheet 100 and a rear lower area bonded to a lower surface area of the front surface of the inorganic insulating material sheet 100. Is integrally configured to include a refractory filler sheet 200 is attached to the upper surface of the aluminum foil 210 is peeled off from the front surface of the inorganic insulating material sheet 100, the lower surface of the rear surface, A rectangular foot having a predetermined thickness, a predetermined width, and a predetermined length capable of wrapping a pipe in the front lower region of the aluminum foil 210, which is adhered to the adhesive surface 101 of the lower front region of the inorganic insulation sheet 100. The lower foaming agent 220, which is a refractory filler, is bonded, and the upper upper area has a predetermined width spaced part 240 from an upper end of the lower foaming agent 220 to an upper portion, and has a predetermined thickness, predetermined width, and predetermined height. A plurality of isosceles triangle-shaped upper foaming agent 230 is bonded side by side, characterized in that configured as a whole as a whole.
The vertical pipe through-hole refractory filling structure for preventing fire spreading between layers of the present invention is configured as described above, can be applied regardless of the wide and narrow of the gap between the through-hole and the vertical pipe of the building, or the thick and thin of the floor structure thickness of the building, It can be applied to the vertical pipe side or the through hole side or the upper side or the lower side, and is exposed when the vertical pipe of the synthetic resin material is burned or dropped by sealing the through hole through the foaming of the refractory filler provided in the through hole. In the case of preventing the spread of fire through the through-hole or the metal pipe is provided with a vertical pipe through-fire refractory filling structure for preventing the spread of fire between the layers to prevent the fire from spreading to the other layer from the metal pipe heated to a high temperature flame.

Description

Fireproof filling structure of building through-hole for prevention of interlayer fire spread}

The present invention relates to a vertical pipe-through fire-resistant structure for preventing the spread of fire between floors, and more particularly, vertical pipe or duct for the treatment of vertical water supply, heating, hot water supply, sewage, etc. leading to the floor and ceiling of the building. It is provided between the penetration part and the vertical pipe which are installed at the bottom of the building for the installation of lamps, etc. will be.

Since many high-rise buildings, such as apartments and residential complexes, are difficult to extinguish quickly, the importance of fire-resistant structures that can prevent the fire from spreading in the event of fires is increasing.

In modern buildings, the amount of ducts due to various piping and large-scale air-conditioning system is increasing, and the amount of power and communication cables has increased rapidly due to OA of buildings. As it is very vulnerable to fire, the treatment to ensure safety from fire will be very important.

In particular, in case of high-rise and large buildings, flame or toxic gas spreads along the vertical pipe-through hole (hereinafter, 'mixed with the pipe'), and it often leads to human damage. Filling with a refractory filler that is long lasting and is less likely to burn is of paramount importance.

In addition, in the case of the plastic vertical pipe, the fire can rapidly spread between layers through the through-hole which is revealed as the plastic vertical pipe is burned or lowered by a high temperature flame when a fire occurs. Filling the space between the ball and the vertical pipe with a foaming refractory filler (graphite foam, etc.) in the event of a fire, the fire filler blocks the spread of flame through the air gap between the through-hole and the vertical pipe, and burns the vertical pipe due to the high temperature flame. It is of utmost importance to prevent rapid interlayer fire spreading through the through-holes that are revealed when descending.

Here, the refractory filler refers to a flame through the gap between the vertical through-hole and the vertical pipe, which is installed for the installation of vertical pipes (floor, ceiling), water supply, heating, hot water, sewage, etc. It refers to a material that can withstand fire without burning and filling the through hole that is exposed when the vertical pipe is burned or lowered by a high temperature flame.

In addition, the refractory-filled structure here means that if a fire breaks out in a building, the floors can be withstand the flame for more than a certain time to prevent the spread of flame or toxic gas to the adjacent layer.層 別) means a structure that seals the gap between the through hole and the vertical pipe, and seals the through hole that is exposed when the vertical pipe is burned or dropped by a high temperature flame.

In modern buildings, which are becoming larger and higher, fire-resistant structures prevent the spread of flames and prevent the influx of toxic gases in the event of a fire, thus allowing tenants to evacuate sufficiently. It will play an important role in preventing the collapse of buildings.

Since the fireproof charging system for building through-holes contains insulation materials, fillers, etc., and includes fixing materials for coupling and support with other structures, it requires several stages of construction procedures. However, despite the current regulations, many cases of inadequate construction or incomplete construction due to lack of understanding on site are caused by insensitivity to safety.

Conventionally, the gap was prevented from spreading between layers of fire by blocking only the inorganic insulation materials such as ceramic wool, rock wool, mineral wool, and glass wool, which have fireproof performance and have thermal insulation and thermal insulation performance.

However, the thickness of the inorganic heat insulating material before construction may be thicker or thinner than the gap between the through hole and the vertical pipe, and the height of the inorganic heat insulating material before construction may be higher or lower than the thickness of the floor structure. That is, the thickness of the building floor structure is different depending on the site construction environment, the size of the through-holes are constructed differently depending on the thickness of the pipe.

Therefore, there is a problem in that it is difficult to be applied to all the construction sites with only the inorganic insulating material of a specific standard, there is a problem that the performance of preventing the spread of fire between layers depending on the construction quality.

In addition, when the plastic granular pipe melts or falls to the lower layer due to a fire, the flame spreads to the upper layer through the through hole even before the foamable refractory filler, which was fixed in the through hole, is automatically foamed by the high temperature flame. The fire had a problem that will spread more greatly.

In addition, in the case of a metal tube, there is a problem in that a fire spreads to another layer from the metal tube heated to a high temperature flame.

The present invention has been made to solve the above problems, and can be applied regardless of the wide and narrow gap between the through hole of the building and the vertical pipe, or thick and thin of the thickness of the floor structure of the building, the vertical pipe side or the through hole side Alternatively, it can be applied anywhere regardless of the upper side or the lower side, and the fire spread through the through hole, which is revealed when the vertical pipe of synthetic resin is burned or dropped by sealing the through hole through the foaming of the refractory filler provided in the through hole. In the case of the prevention of the metal pipe or the high temperature flame to provide a fire-resistant filling structure of the vertical pipe through-hole for preventing the spread of fire between the layer to prevent the fire spread to the other layer.

In order to achieve the above object, the vertical pipe through-hole refractory filling structure 1 for preventing fire spreading between layers is a predetermined width, a predetermined thickness, and a pipe in which a pressure-sensitive adhesive is applied to a lower surface of the front surface, and an adhesive surface 101 is formed. Rectangle inorganic insulating material sheet 100 having a predetermined length that can be wrapped and the upper foaming agent which is a refractory filler on the front surface of the aluminum foil 210 to which the lower area is bonded to the lower area of the front surface of the inorganic heat insulating material sheet 100 ( 230 and the lower foaming agent 220 is formed integrally including the refractory filler sheet 200 is formed, the upper region of the back surface of the aluminum foil 210, peeled off from the front surface of the inorganic insulating material sheet (100) The lower back surface area is bonded to the adhesive surface 101 of the lower front area of the inorganic insulating material sheet 100, and the predetermined lower thickness, predetermined width, and piping are wrapped around the lower front area of the aluminum foil 210. The lower foaming agent 220, which is a rectangular foamable refractory filler having a predetermined length, is adhered to the front upper region, and has a predetermined width spaced portion 240 from an upper end of the lower foaming agent 220 to an upper portion, and has a predetermined thickness, A plurality of isosceles triangle-shaped upper foaming agent 230 having a predetermined width and a predetermined height are bonded side by side, characterized in that configured as a whole as a whole.

The vertical pipe through-hole refractory filling structure for preventing the spread of fire between floors of the present invention configured as described above is applicable to a wide and narrow space between the through-hole and the vertical pipe of the building, regardless of the thickness and thickness of the floor structure of the building, It can be applied to the vertical pipe side, the through hole side, or the upper side or the lower side, and is exposed when the vertical pipe of the synthetic resin is burned or dropped by sealing the through hole through the foaming of the refractory filler provided in the through hole. In the case of preventing the spread of fire through the through-hole or the metal pipe is provided with a vertical pipe through-fire refractory filling structure for preventing the spread of fire between the layers to prevent the fire from spreading to the other layer from the metal pipe heated to a high temperature flame.

1 is an explanatory view of an inorganic insulating material sheet of a vertical pipe through fire-resistant structure for preventing the spread of fire between the present inventors.
Figure 2 is a schematic view of the refractory filler sheet of the vertical pipe through the refractory filling structure for preventing fire spreading between the inventors.
Figure 3 is a perspective view of a vertical pipe through-fire refractory filling structure for preventing the spread of fire between the layers of the present invention configured by combining the Figure 1 and Figure 2.
4B is an explanatory diagram for explaining a state where FIG. 3 is applied to the vertical pipe.
5 is an explanatory view for explaining a state in which a vertical pipe is inserted into and fixed to a through hole of a building slab layer, and a vertical pipe through hole fireproof filling structure for preventing interlayer fire spreading according to the present invention is formed in a gap therebetween.
6 is an explanatory view of the construction state of FIG.
Figure 7 (b) is an explanatory diagram for explaining a state in which the upper filler in the upper portion of the vertical pipe through the fire-resistant filling structure to prevent the spread of fire between the floors of the present invention when the fire breaks down and closed.
8 is an explanatory view of a state in which the upper filler in FIG. 7 closes the vertical pipe through hole.
FIG. 9 is an explanatory diagram for explaining the fixing of a rectangular refractory filler having a predetermined width to wrap the outer surface of the inorganic insulating material sheet with a synthetic resin film containing inorganic fibers or AL foil, and to have a length to wrap the pipe on the outer surface thereof. .
10 is an explanatory diagram for explaining a refractory filler in pieces of FIG.
11 is an explanatory diagram for explaining a state in which the refractory filler is fixed to the inner upper and lower portions of the inorganic insulating material sheet.
12 is an explanatory view for explaining a state in which the refractory filler is fixed to the outer upper and lower portions of the inorganic insulating material sheet.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration, operation and effects of the vertical pipe through-fire refractory filling structure (1) for preventing the spread of fire between the present inventors.

Prior to this, terms or words used in the present specification and claims should not be construed as being limited to the common or dictionary meanings, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that it can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described herein are only the most preferred embodiments of the present invention and do not represent all of the technical idea of the present invention, and various equivalents and modifications that may be substituted for them at the time of filing of the present invention. It should be understood that there may be examples. In describing the present invention, when it is determined that a detailed description of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, in adding reference numerals to each component, it should be noted that the same components are denoted by the same reference numerals and the same names as much as possible even if they are shown in different drawings.

1 is an explanatory view of the inorganic insulating material sheet of the vertical pipe through-fire refractory filling structure for preventing the inter-layer fire spreading, the present invention, Figure 2 is a fireproof filler sheet of the vertical pipe through-fire refractory filling structure for the prevention of inter-layer fire spreading of the present invention. 3 is a perspective view of a vertical pipe through-hole refractory filling structure for preventing the spreading of fires between layers of the present invention configured by combining FIGS. 1 and 2, and FIG. 4 (b) is a vertical pipe of FIG. 5 is an explanatory diagram for explaining a state implemented in Figure 5, the vertical pipe is inserted into the through-hole of the building slab layer is fixed and the vertical pipe through-hole refractory filling structure for preventing the spread of fire between floors of the present invention in the gap construction Figure 6 is an explanatory view for explaining the state, Figure 6 is a view illustrating the construction state of Figure 5, Figure 7 (b), the upper portion of the vertical pipe through the refractory filling structure for preventing the spread of fire between the layer of the present invention in the event of a fire An illustration for explaining a state that the flat upper filler pyegu Fig, 8 is an upper portion of the filler 7 is a state described close up the vertical pipe through hole.

As shown in Figures 1 to 8, the vertical pipe through the fire-resistant filling structure (1) for preventing the inter-layer fire spreading of the present invention, the front lower region is a predetermined width, the adhesive surface 101 is formed by applying an adhesive, Refractory filler on the front surface of the aluminum foil 210 is a rectangular inorganic insulating material sheet 100 having a predetermined thickness and a predetermined length that can wrap the pipe, and the lower area is bonded to the lower surface of the front surface of the inorganic heat insulating material sheet 100 Phosphorus upper foaming agent 230 and the lower foaming agent 220 is formed integrally, including the refractory filler sheet 200 is formed, the upper region of the rear surface of the aluminum foil 210, the inorganic insulating material sheet 100 Peeled from the front surface of the, the lower back surface area is bonded to the adhesive surface 101 of the front lower area of the inorganic insulating material sheet 100, and further, the front lower area of the aluminum foil 210, a predetermined thickness, predetermined width and Plumbing The lower foaming agent 220, which is a rectangular foamable refractory filler having a predetermined length that can be wrapped, is bonded, and the front upper region has a predetermined width spaced portion 240 from an upper end of the lower foaming agent 220 to an upper portion thereof. A plurality of isosceles triangle-shaped upper foaming agent 230 having a thickness, a predetermined width, and a predetermined height are bonded side by side, and are configured as a whole as a whole.

This will be described in more detail below.

As shown in FIG. 1, a rectangular inorganic insulating material sheet 100 having a predetermined length to form a pressure-sensitive adhesive surface 101 coated with a pressure-sensitive adhesive on the front half lower region and to cover a predetermined width, a predetermined thickness, and a pipe; Refractory filler sheet formed by attaching the upper foaming agent 230 and the lower foaming agent 220, which is a refractory filler, on the front surface of the aluminum foil 210 to which the lower surface is bonded to the front lower region of the inorganic insulating material sheet 100 ( It is made integrally, including 200).

The inorganic insulating material sheet 100 is formed of any one of ceramic wool, rock wool, mineral wool, and glass wool, and has heat insulating and thermal insulation performance, respectively.

The thickness of the inorganic insulating material sheet 100 may be formed in any thickness and may be arbitrarily selected in the range of 5 to 60 mm thick depending on the construction site.

The length of the inorganic insulating material sheet 100 is preferably formed to a length that can wrap the vertical pipe (10).

The left and right sides of the inorganic heat insulating material sheet 100 is the inorganic heat insulating material sheet 100. 4 to 6, when the vertical pipe 10 is wrapped, it is preferable to form the inclined portion 103 at a predetermined angle so that the left and right sides of the inorganic insulating material sheet 100 can be bonded to each other. Do.

Reference numeral 102 without reference to FIG. 2 means a peeling surface 102 that is peeled off from the aluminum foil.

In addition, the aluminum foil 210, the length of the horizontal, vertical is formed in the same manner corresponding to that of the inorganic insulating material sheet (100).

As shown in FIG. 2, the lower foaming agent 220, which is a fireproof filler of a predetermined size, is bonded to the front 1/2 lower region of the aluminum foil 210, and a fireproof filler of a predetermined size is attached to the upper 1/2 upper region. The upper foaming agent 230 is spaced a predetermined distance from the upper side of the lower foaming agent 220 to the upper side is attached a plurality of side by side.

The upper foaming agent 230 and the lower foaming agent 220, which are the refractory fillers, are manufactured by mixing oil and inorganic synthetic resins using foamed graphite in powder form as a main material, and have been exposed to high temperature flames during handling or fire. When the mixture is prepared so as not to scatter when the bonding force is maintained, it is foamed by a high-temperature flame in the event of a fire is produced to increase the volume to more than five times the initial volume. In addition, depending on the expansion environment, such as expansion temperature, expansion direction and expansion pressure may be manufactured to have an expansion characteristic of 10 to 30 times.

The lower foaming agent 220, as the main blowing agent, is attached to the lower area of the front half of the aluminum foil.

As a rule of thumb, the thickness of the lower foaming agent 220 was found to be the most suitable 5mm thickness when using a vertical pipe of 100mm diameter.

Since the theoretical effective expansion ratio assumed in this embodiment is 10 times, the thickness of the lower foam body 220 provided in the through hole in the case of a 100 mm diameter vertical pipe is "diameter of the vertical pipe ÷ effective expansion ratio ÷ both pores of the through hole" (100 ÷ 10 ÷ 2), so that the proper thickness of the lower foaming agent 220 will be 5mm thick.

The lower foaming agent 220 is triggered by the foaming of the upper foaming agent 230, thereby blocking the through hole 20 by foaming.

The left and right sides of the lower foaming agent 220 is preferably formed to be inclined at a predetermined angle so that the left and right sides of the lower foaming agent 220 can be bonded to each other when the lower foaming agent 220 wraps the vertical pipe. Do.

On the other hand, the upper foaming agent 230 is attached to the upper area of the front surface of the aluminum foil 210 with a spaced apart portion 240 of a predetermined width from the lower foaming agent 220.

The upper foaming agent 230 has a predetermined width spaced portion 240 from an upper end of the lower foaming agent 220 to the upper side, and is formed in a plurality of isosceles triangle shapes having a predetermined thickness, a predetermined width, and a predetermined height to the side. Glued side by side.

However, the shape of the upper foaming agent 230 may be implemented in various shapes, but is not limited thereto.

The upper foaming agent 230 is preferably attached to be spaced apart from the upper end of the lower foaming agent 220 within a thickness of 5mm, the upper foaming agent 230.

That is, the width of the spacer 240 is preferably formed to a width within the thickness of the upper foaming agent (230).

This is to allow the upper foaming agent 230 to fall forward and to be supported by the upper end of the lower foaming agent 220.

The vertical height of the upper foaming agent 230 is preferably formed to be smaller than the length of the radius of the vertical pipe (10).

Preferably, the length is formed by subtracting the interval of the spacer 240 from the radius of the vertical pipe (10).

This is to allow the upper foaming agent 230 to be entangled with each other and cover the opening of the through hole 20 as shown in FIGS. 7B and 8 when the upper foaming agent 230 falls forward by its own weight.

The number of the upper foaming agent 230 will not be limited, but in accordance with the rule of thumb formed four to eight at equal intervals there was no bunch.

In the present embodiment, eight isosceles triangles were formed and there was no problem.

The upper 1/2 rear region of the aluminum foil 210 of the refractory filler sheet 200 configured as described above is separated from the inorganic insulation sheet 100 and the lower half 1/2 region of the aluminum foil 210. By attaching to the adhesive surface 101 of the front half lower area of the inorganic insulating material sheet 100, the configuration of the vertical pipe through-fire refractory filling structure (1) for preventing the interlayer fire diffusion of the present invention is completed.

On the other hand, it is also preferable to wrap the outer surface of the inorganic insulating material sheet 100 with a synthetic resin film containing an inorganic fiber, or AL foil so as to improve the workability.

FIG. 9 is an explanatory diagram for explaining the fixing of a rectangular refractory filler having a predetermined width, the outer surface of the inorganic insulating material sheet being sealed and wrapped with a synthetic resin film containing inorganic fibers or AL foil to a length that can wrap the pipe on the outer surface thereof. FIG. 10 is an explanatory diagram for explaining a refractory filler in pieces of FIG. 9, FIG. 11 is an explanatory diagram for explaining a state in which the refractory filler is fixed to the upper and lower portions of an inorganic insulating material sheet, and FIG. It is explanatory drawing for demonstrating the state in which the filler was fixed to the upper and lower sides of the outer side of the inorganic insulating material sheet.

As shown in Figures 9 to 12, at this time, the inorganic insulating material sheet 100 is sealed and wrapped with a synthetic resin film containing an inorganic fiber, or AL foil without applying a pressure-sensitive adhesive and then on the outer surface, Figure 9 As shown, the rectangular refractory filler 200 ′ having a predetermined width to wrap the pipe is fixed.

The refractory filler 200 ′ may be arranged in a row to fix the refractory filler 200 ′ in pieces, as shown in FIG. 10, within a length range in which the pipe may be wrapped.

The fixing means 300 of the refractory filler 200 ′ may be fixed using an adhesive, a tape, a wire, and a pin.

However, since the inorganic insulating material sheet 100 and the refractory filler 200 'are different from each other in curvature, as shown in FIG. 9, the center portion of the refractory filler 200' may be bonded to the inorganic insulating material sheet 100. By means of adhesive fixation, the other portion is preferably bonded to the inorganic insulating material sheet 100 to form a tunnel in the center so that the refractory filler 200 'can be flexibly fixed.

In the case of fixing using the other fixing means 300, it is also preferable to fix in the same manner.

Since the inorganic insulating material sheet 100 is provided in various sizes for each provider, the thickness of the inorganic insulating material sheet 100 may be thicker than the space between the inner surface of the through hole 20 and the outer surface of the vertical pipe 10 of the construction part. It may be thin, and its height may be higher or lower than the thickness of the floor structure to be constructed.

Therefore, the position of the refractory filler 200 ′ fixed to the inorganic insulating material sheet 100 is an inner side of the inorganic insulating material sheet 100 inserted into a space between the inner surface of the through hole 20 and the outer surface of the vertical pipe 10. If it is fixed to any of the upper or lower, the outer upper or lower, there is no problem in performance as long as the length can wrap the pipe.

Therefore, the refractory filler 200 'fixed to the inorganic insulation sheet 100 inserted into the space between the inner surface of the through hole 20 and the outer surface of the vertical pipe 10 is as shown in FIG. It is also possible to be fixed to the inner upper portion of the inorganic insulating material sheet (100).

In addition, the refractory filler 200 ′ fixed to the inorganic insulating material sheet 100 inserted into a space between the inner surface of the through hole 20 and the outer surface of the vertical pipe 10 is as shown in FIG. 11. It is also possible to be fixed to the inner lower portion of the inorganic insulating material sheet (100).

In addition, the fireproof filler 200 ′ fixed to the inorganic insulating material sheet 100 inserted into a space between the inner surface of the through hole 20 and the outer surface of the vertical pipe 10 is as shown in FIG. 12. It is also possible to be fixed to the outer upper portion of the insulation sheet (100).

In addition, the fireproof filler 200 ′ fixed to the inorganic insulating material sheet 100 inserted into a space between the inner surface of the through hole 20 and the outer surface of the vertical pipe 10 is as shown in FIG. 12. It is also possible to be fixed to the lower outer side of the heat insulating material sheet (100).

As described above, by installing a refractory filler (200 ') that is foamed when heated between the inorganic insulating material sheet 100 and the vertical pipe 10 or between the inorganic insulating material sheet 100 and the through hole 20 to prevent fire diffusion performance. It will be possible to achieve uniform topical diffusion prevention performance regardless of the construction environment.

Next will be described in detail the action of the refractory filling structure (1) through the vertical pipe for preventing the spread of fire between the inventors.

First, a rectangular inorganic insulating material sheet 100 having a predetermined length corresponding to the length of the outer circumference of the vertical pipe 10 to wrap the outer circumference is prepared, and the adhesive surface 101 is applied by applying an adhesive to the lower half of the front surface. ).

Next, to prepare the aluminum foil 210 of the same size corresponding to the size of the inorganic insulating material sheet 100.

Next, the lower foaming agent 220, which is a refractory foam filler, is attached to the lower half of the front surface of the aluminum foil 210.

Next, a spaced portion 240 spaced apart from the upper end of the lower foaming agent 220 in the upper half of the front surface of the aluminum foil 210, a plurality of upper foaming agent 230, which is a refractory foam filler, side by side Side by side attached to complete the configuration of the refractory filler sheet 200.

The refractory filler sheet 200 configured as described above, the upper half of the back surface of the aluminum foil 210 is separated from the inorganic insulation sheet 100, and the lower half of the back surface of the aluminum foil 210. By adhering to the adhesive surface 101 of the lower half of the front surface of the inorganic insulating material sheet 100, to complete the configuration of the vertical pipe through the refractory filling structure (1) for preventing the fire spread between the layers.

Next, the vertical pipe 10 is inserted into and fixed to the vertical pipe through-hole 20 of the building slab 50, and as shown in FIGS. 5 to 7, between the through-hole 20 and the vertical pipe 10. Insert the vertical pipe through the refractory filling structure (1) for preventing the spread of fire between the layers of the present invention in the air gap and caulking with a sealant at the bottom to complete the construction.

Reference numeral 60 without reference to FIGS. 5 and 7 denotes a sleeve 60 installed in the building slab layer, and reference numeral 70 denotes a fixture for fixing the vertical pipe 10 inserted into the through hole 20 ( 70). In addition, the reference numeral 30 denotes the air gap 30 between the vertical pipe 10 and the through hole 20, but is not shown in the drawings.

In the event of a fire, in the initial stage of the flame by the vertical pipe through the fire-resistant filling structure (1) for preventing the spread of the interlayer fire of the present invention constructed in the air gap 30 between the through-hole 20 and the vertical pipe 10 The spreading between layers is prevented and the fire resistance of the predetermined time is exerted (2 hours notice by the Ministry of Land, Transport and Maritime Affairs).

When the fire is not suppressed prematurely suppressed and spread, the high temperature flame is burned or melted down the plastic vertical pipe 10 to fall through the through hole 20 is exposed can be rapidly spread through the through hole.

In addition, in the case of metal pipes, the fire can spread from the metal pipes heated to the high flame to the other layer.

At this time, the upper foaming agent 230 of the vertical pipe through-hole refractory filling structure (1) for preventing the spread of fire between the layers provided in the through-hole 20 when the through-hole temporarily closed while falling down the upper foaming agent 230 ) Is directly received a high-temperature flame is foamed and is triggered by the lower foaming agent 220 is foamed and the entire through-hole 20 is sealed to exhibit a fire resistance of a predetermined time to prevent the spread of flame between layers and inflow of toxic gas It will play an important role in preventing occupants' time to evacuate the building and preventing the collapse of buildings due to fire.

Although the present invention has been described in detail with reference to the preferred embodiment of the vertical pipe through-fire refractory filling structure (1) for preventing the spread of fire between the present inventors, the present invention is not limited thereto, and the claims and the detailed description of the invention and the accompanying drawings. It is possible to carry out various modifications within the scope of the present invention, which will also be obvious to belong to the scope of the present invention.

Fireproof filling structure for vertical pipe through to prevent fire spread between floors
10 Vertical line 20 Through hole 30 Air gap 40 Vertical line fixture 50 Slab
60 Sleeve 70 Fixture
100 Insulation sheet 101 Adhesive side 102 Peeling side 103 Inclined part
200 Fireproof Filler Sheet 200 'Fireproof Filler 210 Aluminum Foil 220 Lower Foaming Agent 230 Upper Foaming Agent
240 spacing
300 fixing means

Claims (12)

A rectangular inorganic insulating material sheet 100 having a predetermined width, a predetermined thickness, and a predetermined length capable of covering a pipe having a pressure-sensitive adhesive applied to the lower surface of the front surface, and a lower portion of the front surface of the inorganic insulating material sheet 100. The refractory filler sheet 200 formed by attaching the upper foaming agent 230 and the lower foaming agent 220, which is a refractory filler, is formed on the front surface of the aluminum foil 210 to which the lower area is bonded to the area. The upper area of the back surface of the aluminum foil 210 is peeled off from the front surface of the inorganic insulating material sheet 100, and the lower area of the back surface is bonded to the adhesive surface 101 of the lower surface area of the front surface of the inorganic insulating material sheet 100. The lower foaming agent 220, which is a rectangular foamable refractory filler having a predetermined thickness, a predetermined width, and a predetermined length to cover a pipe, is bonded to the lower area of the front surface of the aluminum foil 210, and the lower area of the aluminum foil 210 is attached to the lower area of the front surface. With a predetermined width spaced portion 240 from the upper end of the sub-foaming agent 220, a plurality of isosceles triangle-shaped upper foaming agent 230 of a predetermined thickness, predetermined width and predetermined height are bonded side by side, In the vertical pipe through-hole refractory filling structure for preventing inter-layer fire spreading as a whole, the left and right sides of the inorganic insulating material sheet 100, the inorganic insulating material sheet 100 wrapped the vertical pipe (10). When the left and right sides of the inorganic insulation material sheet 100 when forming the inclined portion 103 of a predetermined angle to form a junction with each other, characterized in that the vertical pipe through-fire refractory filling structure for preventing the spread of fire between layers. delete According to claim 1, wherein the upper foaming agent 230, the distance within the thickness of the upper foaming agent 230 from the upper end of the lower foaming agent 220 so as to be supported on the upper end of the lower foaming agent 220 when falling forward Vertical pipes through the fire-resistant filling structure for preventing the spread of fire between the layers, characterized in that attached to spaced apart. According to claim 1, wherein the upper and lower heights of the upper foaming agent 230, the upper foaming agent 230 is intertwined with each other when the front foaming agent 230 by its own weight to cover the opening of the through-hole 20 of the vertical pipe 10 The vertical pipe through the refractory filling structure for preventing the spread of fire between layers, characterized in that the length is formed by subtracting the interval of the spaced portion 240 from the radius. According to claim 1, the left and right sides of the lower foaming agent 220, the left and right sides of the lower foaming agent 220 when the lower foaming agent 220 is wrapped around the vertical pipe, the predetermined angle so as to form a junction with each other Vertical pipes through the refractory filling structure for preventing the spread of fire between the layers, characterized in that the inclined form. delete delete delete delete delete delete delete

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