JP5391134B2 - Fire prevention compartment penetration structure and construction method thereof - Google Patents

Description

  TECHNICAL FIELD The present invention relates to a fire-blocking section penetration structure provided in a partition section of a structure such as a building or a ship structure and a construction method thereof, and more specifically, in a horizontal section such as a floor or a ceiling among the partition sections of the structure. The present invention relates to a fire prevention compartment penetration structure and its construction method.

Even when a fire occurs on one side of a partition part of a structure such as a building, a partition is usually provided on the partition part of the building or the like in order to prevent flames and smoke from spreading to the other side.
When piping is installed inside the building, it is necessary to provide a hole penetrating this section and to insert the piping through the through hole.
However, simply inserting the pipes through the holes causes a problem that flames, smoke, etc. diffuse from one of the compartments to the other through the through holes when a fire or the like occurs.

  Various structures have been proposed to cope with this problem. In order to prevent flames, smoke, etc. from diffusing through the through-hole, an opening through which the piping can be passed is provided for a structure in which a plurality of piping is inserted into the through-hole provided in the section. A structure in which the through hole is covered by covering the through hole with a galvanized steel sheet has been proposed (Non-patent Document 1).

FIG. 15 is a schematic perspective view for explaining a conventional first fireproof compartment penetration structure.
A plurality of pipes 500 are inserted through through holes formed in a partition provided in a partition such as a building. After disposing the galvanized steel plate 510 so as to cover the through-hole, a joint closing member 520 is adhered, and the periphery of the galvanized steel plate 510 is fixed by a fixing means such as a screw and a bolt 530. A fireproof compartment penetration structure can be obtained.
The galvanized steel sheet is laminated with a metal wire net and a thermally expandable fireproof sheet (not shown).
With the structure described in FIG. 15, even when a fire or the like occurs on one side of a section, it is possible to prevent flames and smoke from spreading to the other side of the section.

However, in order to construct the conventional first fireproof compartment penetration structure shown in FIG. 15, it is necessary to provide an opening through which the piping 500 can pass through the galvanized steel sheet 510 in advance. is there. If it is found at the construction site that the position of the opening provided in the galvanized steel plate 510 is different from the actual position of the piping 500 in the through-hole, there is a problem that the construction is delayed, etc. A plurality of different galvanized steel sheets must be prepared for each construction site without making a mistake, and there is a problem that preparation for construction is complicated.
In addition, if the galvanized steel plate 510 is handled with care, there is a possibility that the sharp end portion such as a metal wire net may cause injury during the operation, and the construction is not easy.

On the other hand, as a fire prevention compartment penetration structure that can be easily constructed, a columnar thermally expandable sponge material having a cylindrical air core in a through hole formed in a partition provided in a partition such as a building is provided. An inserted fireproof compartment penetration structure has been proposed (Patent Document 1).
FIG. 16: is a schematic cross section for demonstrating the 2nd conventional fireproof division penetration part structure.
As shown in FIG. 16, the partition 600 is provided with a through hole, and a pipe 610 passes through the through hole.
A cylindrical heat-expandable sponge material 620 having a cylindrical air core is inserted so as to wrap the pipe 610. A rubber molded body 630 is joined to the thermally expandable sponge material 620 to close a gap between the pipe 610 and the through hole.
If it is this structure, since the heat | fever expansible sponge material 620 with which the rubber molded object 630 was joined can be easily attached to the clearance gap between the piping 610 and a through-hole, it is considered that it is excellent in workability.

  However, in the case of the heat-expandable sponge material 620 to which the rubber molded body 630 is joined, since the entire shape is determined by the rubber molded body 630, the pipe 610 through which the through hole of the partition is located at the center of the through hole Can be mounted with a thermally expandable sponge material 620 having a rubber molded body 630 bonded to the gap between the pipe 610 and the through-hole without any problem, but when the pipe 610 is at a position deviating from the center of the through-hole. Has a problem that it is difficult to attach the thermally expandable sponge material 620 in which the rubber molded body 630 is joined to the gap between the pipe 610 and the through hole.

When the compartment is a horizontal compartment such as a floor or a ceiling, the heat-expandable sponge material 620 to which the rubber molded body is bonded is directly exposed to a flame such as a downstairs fire. Since the heat-expandable sponge material 620 to which the rubber molded body mounted in the hole is bonded melts before expansion, there is a possibility that the fire resistance performance cannot be sufficiently exhibited.
Although it is conceivable to increase the content of thermally expandable graphite or the like in order to prevent the thermally expandable sponge material 620 to which the rubber molded body is bonded from the through hole of the horizontal compartment from being melted by heat such as a fire. Since the weight of the heat-expandable sponge material 620 to which the rubber molded body is joined increases and falls easily or the flexibility is impaired, it is not easy to achieve both fire resistance and workability.

JP 2007-205472 A

US 3M Technical Document “CS-195 + Composite Sheet” Document No. 98-0400-2360-2 1997

  An object of the present invention is to provide a fireproof section through-part structure that can be easily constructed without depending on the position of a pipe passing through a horizontal section such as a floor or a ceiling with respect to a through hole, and is excellent in airtightness and fire resistance. There is.

  As a result of intensive studies by the present inventors in order to solve the above problems, a thermally expandable refractory sheet is inserted into a heat insulating material installed around pipes in a through hole of a horizontal section, and the outer periphery of the heat insulating material It is found that the heat-expandable fireproof tape installed in the fireproof section through-hole structure installed on the outer periphery of the heat insulating material at least below the insertion position of the heat-expandable fireproof sheet and the manufacturing method thereof meet the object of the present invention. The present invention has been completed.

That is, the present invention
[1] Pipings inserted through the through holes of the horizontal section provided in the partition of the structure;
A heat insulating material installed around the piping;
A thermally expandable fireproof sheet installed inside the heat insulating material;
A thermally expandable fireproof tape installed on the outer periphery of the heat insulating material;
A sealing material filled without a gap between the heat insulating material and the through hole;
A fire compartment penetrating structure having
The heat insulating material installed around the pipes in the through hole has a separation surface,
The thermally expandable refractory sheet is inserted inside the separation surface of the heat insulating material installed around the piping,
Thermally expandable fireproof tape installed on the outer periphery of the heat insulating material is inserted into at least the inside of the separation surface among the outer periphery of the heat insulating material installed around the piping in the through hole. The present invention provides a fireproof compartment penetration structure characterized in that it is installed on the outer periphery of a heat insulating material below a fireproof sheet.

The present invention also provides
[2] The outer periphery of the thermally expandable refractory sheet inserted inside the separation surface of the heat insulating material installed around the piping fits inside the heat insulating material installed around the piping,
The insertion position of the thermally expandable refractory sheet with respect to the heat insulating material installed around the piping is set to 0 at the lower end of the through hole of the horizontal section with respect to the vertical direction of the horizontal section, and penetrates the horizontal section. The fireproof compartment penetration structure according to the above [1], which is in a range of 25 to 75% of the through holes of the horizontal compartment when the position of the upper end of the hole is 100%, is provided.

The present invention also provides
[3] The thermally expansible fireproof tape installed on the outer periphery of the heat insulating material has an outer peripheral portion of the heat insulating material in a range of 10 mm or more from the lower end of the through hole of the horizontal section and below the separation surface of the heat insulating material. The fireproof section penetrating part structure according to the above [1] or [2] is provided.

The present invention also provides
[4] A construction method of a structure in which pipes having a heat insulating material installed around are inserted into through holes in a horizontal section provided in a partition portion of the structure,
(1) installing a thermally expandable fireproof tape on the outer periphery of the heat insulating material;
(2) forming a separation surface on the heat insulating material;
(3) inserting a thermally expandable fireproof sheet inside the separation surface of the heat insulating material;
(4) With respect to the vertical direction of the horizontal section, when the position of the lower end of the through hole of the horizontal section is 0, and the position of the upper end of the through hole of the horizontal section is 100%, the inside of the separation surface of the heat insulating material While adjusting the insertion position of the thermally expandable fireproof sheet to any position within the range of 25 to 75% of the through hole of the horizontal section,
Thermally expandable fireproof tape in the through hole so that the thermally expandable fireproof tape installed on the outer periphery of the heat insulating material covers at least the bottom of the separation surface in the outer periphery of the heat insulating material in the through hole. Adjusting the position of
(5) a step of filling a sealing material without a gap between the piping and the through hole;
The construction method of the fire prevention division penetration part structure which has at least is provided.

The fireproof compartment penetration structure of the present invention has a heat-expandable fireproof sheet inserted in the separation surface of the heat insulating material installed around the pipes, and a heat-expandable fireproof tape installed on the outer periphery of the heat insulating material. Therefore, when a fire flame enters the through hole of the horizontal section from the lower part of the horizontal section, the thermally expandable fireproof sheet and the thermally expandable fireproof so as to wrap the through hole from the side of the through hole and the inside of the through hole. The tape expands, and the through holes generated after the heat retaining material is melted and burned off by these expansion residues are closed and sealed.
Thereby, even if a fire occurs on the lower floor of the horizontal section, it is possible to prevent smoke generated by the fire from being diffused or spread to the upper floor through the through hole.

Conversely, when a fire occurs on the upper floor of a horizontal section, heat is transmitted through the piping and the piping is heated. The heat-expandable refractory sheet and the heat-expandable refractory tape expand so as to wrap the inside, and the through holes generated after the heat insulating material is melted and burned off by these expansion residues are closed and sealed.
Thereby, even if a fire occurs on the upper floor of the horizontal section, it is possible to prevent smoke generated by the fire from being diffused or spread to the upper floor through the through hole.

Further, the fireproof compartment through-hole structure of the present invention has a thermal expansion that is inserted into at least the inside of the separation surface among the outer periphery of the heat insulating material installed around the pipes in which the heat-expandable fireproof tape is in the through-hole. It is installed on the outer periphery of the heat insulating material below the refractory fireproof sheet.
For this reason, when a fire has occurred on the lower floor of the horizontal section, the thermally expandable refractory tape expands in the horizontal direction with respect to the horizontal section within the through hole.
Even if the thermally expandable refractory tape does not completely close the inside of the through-hole, an expansion residue generated by expansion of the thermally expandable refractory tape is above the expansion residue, and a separation surface of the heat retention material Supports a heat-expandable fireproof sheet inserted inside.
This prevents the heat-expandable fireproof sheet inserted inside the separation surface of the heat insulating material from falling to the lower floor before the heat insulating material melts and falls to the lower floor before it expands. it can.

The thermally expandable refractory sheet used in the present invention has a position near the center of the through hole in the horizontal section, that is, the position of the lower end of the through hole in the horizontal section is 0, and the position of the upper end of the through hole in the horizontal section is 100%. Are installed in any of 25 to 75% of the through holes of the horizontal section.
For this reason, since the inside of the said through-hole can be efficiently obstruct | occluded with the expansion | swelling residue of the thermally expansible fireproof sheet in a through-hole, it can prevent that a flame and smoke of a fire move through a through-hole.

  Furthermore, since the through hole of the horizontal compartment is closed in the fire compartment penetrating structure of the present invention, even if the fire compartment penetrating structure of the present invention is not directly exposed to a flame such as a fire, the floor or floor of the horizontal compartment When smoke such as fire is generated above, it is possible to prevent the smoke and toxic gas from diffusing from one side of the horizontal section to the other.

  Moreover, since the fire prevention compartment penetration part structure of this invention can be constructed even when piping is displaced from the center of the through hole, it is excellent in workability.

Furthermore, since the construction method of the fireproof compartment penetration part structure of this invention can be implemented by simple operation, it is excellent in productivity per short time.
In addition, the fireproof compartment penetration structure of the present invention does not require the work of installing heavy objects such as galvanized steel sheets to the through holes, so there is no accident that causes heavy objects to fall to the lower floor during construction. Excellent safety.

It is a schematic cross section for demonstrating the fire prevention division penetration part structure of Example 1 of this invention. It is a model perspective view for demonstrating the construction method of the fire prevention division penetration part structure of this invention. It is a model perspective view for demonstrating the process of forming a separation surface in the heat insulating material installed around piping. It is a schematic plan view for demonstrating the process of forming the thermally expansible fireproof sheet used for this invention. It is a schematic plan view for demonstrating the process of inserting a thermally expansible fireproof sheet in the separation surface of a heat insulating material. It is a schematic cross section for demonstrating the structure where the thermally expansible fireproof sheet was inserted in the separation surface of the heat insulating material. It is a schematic cross section for demonstrating the process of adjusting the position of the said heat-expandable fireproof sheet and heat-expandable fireproof tape in the through-hole of a horizontal division. It is a schematic cross section which shows the fire prevention division penetration part structure of Example 1. FIG. It is a schematic cross section for demonstrating the process of forming a separation surface in the heat insulating material installed around the piping in Example 2. FIG. It is a schematic cross section which shows the fire prevention division penetration part structure of Example 3. It is a schematic cross section which shows the fire prevention division penetration part structure of Example 4. It is a schematic plan view for demonstrating the shape of the thermally expansible fireproof sheet used for Example 5. FIG. It is the model top view which illustrated the modification of the shape of a thermally expansible fireproof sheet. It is the model top view which illustrated the modification of the shape of a thermally expansible fireproof sheet. It is a model perspective view for demonstrating the conventional 1st fire prevention division penetration part structure. It is a model perspective view for demonstrating the conventional 2nd fire prevention division penetration part structure.

Although this invention is related to a fire prevention compartment penetration part structure, the piping used for this invention first is demonstrated.
The piping is inserted through a through hole of a horizontal section provided in a partition part of a structure such as a building or a ship structure.
Examples of the piping include liquid pipes such as refrigerant pipes, heat medium pipes, water pipes, sewage pipes, pouring / draining pipes, fuel transfer pipes, hydraulic pipes, gas pipes, heating / cooling medium transfer pipes, communication pipes, and the like. Gas transfer pipes such as trachea, cables such as electric cables, optical fiber cables, marine cables, etc., and sleeves for inserting these liquid transfer pipes, gas transfer pipes, cables, etc. Etc.
Among these, from the viewpoint of workability, liquid transfer pipes such as a refrigerant pipe, a heat transfer pipe, a water pipe, a sewage pipe, a pouring / drainage pipe, a fuel transfer pipe, and a hydraulic pipe are preferable. Further preferred.

  As the pipes, one or more of liquid transfer pipes, gas transfer pipes, cables, sleeves and the like can be used.

  There is no particular limitation on the shape of the piping, for example, the cross-sectional shape perpendicular to the major axis direction of the piping is a triangle, a polygon such as a quadrangle, a shape such that the sides are different in length, such as a rectangle Examples thereof include shapes such as parallelograms having different internal angles, ellipses, and circles. Among these, those having a cross-sectional shape of a circle, a quadrangle, etc. are preferable because of excellent workability.

  The size of the cross-sectional shape of the piping is usually in the range of 1 to 1000 mm, preferably 5 based on the length of the side having the longest distance from the center of gravity of the cross-sectional shape to the outline of the cross-sectional shape. It is in the range of ˜750 mm.

When the pipes are liquid transfer pipes, gas transfer pipes, cables, etc., the range is usually 0.5 mm to 10 cm, preferably 1 mm to 5 cm.
When the piping is a sleeve, it is usually in the range of 10 to 1000 mm, preferably in the range of 50 to 750 mm.

Although there is no limitation in particular about the raw material of said piping, For example, what consists of 1 type, or 2 or more types, such as a metal material, an inorganic material, and an organic material, can be mentioned.
Examples of the metal material include iron, steel, stainless steel, copper, and an alloy including two or more metals.

Examples of the inorganic material include glass and ceramic.
Examples of the organic material include synthetic resins such as vinyl chloride resin, ABS resin, vinylidene fluoride resin, polyethylene resin, and polypropylene resin.
The said raw material can use 1 type, or 2 or more types.

The piping used in the present invention is one or more of the metal material pipe, the inorganic material pipe, the organic material pipe, etc., but two or more of the metal material pipe, the inorganic material pipe, the organic material pipe, etc. It can also be used as a laminated tube used for the outer cylinder.
The pipes are preferably metal material pipes, organic material pipes and the like from the viewpoint of handleability, and more specifically steel pipes, copper pipes, synthetic resin pipes and the like.

The pipes used in the present invention are those that pass through the through holes of the horizontal section provided in the partition of the structure. Examples of the sections include fire floors and ship cabins such as floors and ceilings of buildings. And steel plates such as floors and ceilings provided on the ceiling.
By providing through holes in these horizontal sections, the pipes can be inserted through the through holes.

  Specific examples of the horizontal section used in the present invention include concrete slabs such as floors and ceilings, heat resistant panels, and the like.

As the heat-resistant panel, for example, a cement panel, an inorganic ceramic panel, or the like is used.
Examples of the cement-based panel include hard wood piece cement boards, inorganic fiber-containing slate boards, lightweight cellular concrete boards, mortar boards, and precast concrete boards.
Examples of the inorganic ceramic panel include a gypsum board, a calcium silicate board, a calcium carbonate board, a mineral wool board, and a ceramic board.

  Here, as the gypsum board, specifically, a lightweight material such as saw dust or pearlite is mixed into calcined gypsum, and cardboard is formed on both sides. For example, ordinary gypsum board (JIS A6901 compliant: GB-R) is used. ), Decorative gypsum board (JIS A6911 compliant: GB-D), waterproof gypsum board (JIS A6912 compliant: GB-S), reinforced gypsum board (JIS A6913 compliant: GB-F), sound-absorbing gypsum board (JIS A6301 compliant: GB) -P) and the like.

  The heat-resistant panel can be used alone or in combination of two or more.

Next, the heat insulating material used in the present invention will be described.
Examples of the heat insulating material used in the present invention include, for example, polyethylene foam, polypropylene foam, polystyrene foam, polyurethane foam, polyvinyl chloride foam, EPDM foam, NBR foam, synthetic resin foam, and organic material obtained by molding synthetic resin. And inorganic materials such as glass wool, ceramic wool, and mineral wool.
The said heat insulating material can use 1 type, or 2 or more types.

Next, the thermally expandable fireproof sheet used in the present invention will be described.
The heat-expandable fireproof sheet used in the present invention is a sheet-like heat-expandable resin composition containing a resin component such as an epoxy resin or rubber, a phosphorus compound, neutralized heat-expandable graphite, and an inorganic filler. It is formed by molding.
The heat-expandable fireproof sheet used in the present invention may be a laminate of one or more of inorganic fiber sheets such as glass cloth, metal foils such as aluminum foil and copper foil.

Examples of the inorganic fiber used in the inorganic fiber sheet include glass wool, rock wool, ceramic wool, gypsum fiber, carbon fiber, stainless steel fiber, slag fiber, silica alumina fiber, alumina fiber, silica fiber, and zirconia fiber. .
The inorganic fiber layer preferably uses an inorganic fiber cloth using the inorganic fiber.
Moreover, it is preferable to use what laminated the metal foil for the inorganic fiber used for the said inorganic fiber sheet.
As specific examples of the metal foil laminated inorganic fiber, for example, aluminum foil laminated glass cloth, copper foil laminated glass cloth and the like are more preferable.

  The heat-expandable fireproof sheet used in the present invention can be obtained, for example, by laminating a metal foil layer, a heat-expandable resin layer, an inorganic fiber layer, and the like. In addition to melt coextrusion, hot pressing, etc., these layers may include means for attaching each layer with an adhesive. The thermally expandable refractory sheet used in the present invention preferably has a metal foil layer on the outermost surface.

  Commercially available products can be used as the thermally expandable refractory sheet used in the present invention, for example, Sekisui Chemical Co., Ltd. Fibrok (trade name. Epoxy resin or rubber as a resin component, phosphorus compound, thermally expandable graphite and It is possible to obtain and use a sheet-like molded product of a thermally expandable resin composition containing an inorganic filler or the like.

Moreover, the thermally expansible fireproof tape used for this invention can use what cut | disconnected the said thermally expansible fireproof sheet in tape shape. The heat-expandable fireproof tape is obtained by applying an adhesive to the sticking surface, or by adding an adhesive component to the heat-expandable resin composition constituting the heat-expandable fireproof tape. It is possible to use a material which is made sticky.
The heat-expandable fireproof tape used in the present invention is preferably one obtained by laminating a metal foil layer, a heat-expandable resin layer, an inorganic fiber layer, and the like.

  Moreover, as a sealing material used for this invention, the sealing material for buildings prescribed | regulated by JISA5758, the injection | pouring epoxy resin sealing material for construction repair prescribed | regulated by JISA6024, the gypsum board prescribed | regulated by JISA6914, for example Examples include joint treatment materials, mortar, putty, caulking and the like. The sealing material 4 is preferably a putty, caulking, or the like obtained by blending a filler, a flame retardant, or the like with rubber such as chloroprene rubber or silicone from the viewpoint of workability.

  EXAMPLES Next, although this invention is demonstrated in detail based on drawing based on an Example, this invention is not limited at all by these Examples.

FIG. 1 is a schematic cross-sectional view for explaining a structure for penetrating a fire prevention compartment according to a first embodiment of the present invention.
In Example 1, the concrete wall 1 of a building is used as a horizontal division provided in the partition part of the structure.
The concrete wall 1 used in Example 1 has a thickness of 120 mm.
The thickness of the horizontal section used in the present invention is preferably in the range of 80 to 1000 mm, more preferably in the range of 100 to 500 mm, and even more preferably in the range of 110 to 300 mm.
A circular through hole 2 is formed in the concrete wall 1 in a direction perpendicular to the horizontal section.
In Example 1, the diameter of the circular through hole 2 is 300 mm. The diameter of the through hole is usually in the range of 80 to 500 mm, preferably in the range of 100 to 400 mm.
Further, the cross-sectional shape of the through-hole 2 is not limited to a circular shape, and construction can be performed even in a polygonal shape such as a quadrangle, or a shape other than a circle such as an elliptical shape.

Further, piping 3 which is a refrigerant pipe is inserted through the through hole 2.
A heat insulating material 4 is provided on the outer periphery of the piping 3. The heat insulating material 4 is made of polyethylene foam, and plays a role of keeping the temperature of the refrigerant inside the piping 3 used as a refrigerant pipe constant and blocking heat from the outside.
The material of the heat insulating material 4 used for this invention is not limited to the said polyethylene foam, It can change and use suitably.
The distance between the inner peripheral surface of the through hole 2 and the heat insulating material is preferably in the range of 25 to 120 mm on the basis of a straight line parallel to a horizontal section passing through the center of the piping 3.

FIG. 2 is a schematic perspective view for explaining the construction method of the fireproof compartment penetration part structure of the present invention.
The heat insulating material 4 provided on the outer periphery of the piping 3 is formed of a flexible material having a cylindrical shape, and the heat insulating material 4 is freely moved up and down along the piping 3. Can do.
Since the diameter of the cylindrical inner cylinder of the heat insulating material 4 is set slightly smaller than the outer periphery of the piping 3, the heat insulating material 4 can be freely moved up and down along the piping 3. On the other hand, even if the heat insulating material 4 is not held, the heat insulating material 4 does not fall downward and can be held at the moved position.
For convenience of explanation, in the drawings, only a part of the piping 3 and the heat insulating material 4 are schematically illustrated, and the required functions of the piping 3 and the heat insulating material 4 It goes without saying that each length can be extended according to the application.

First, a heat-expandable fireproof tape 5 (trade name Fiblock ST30, manufactured by Sekisui Chemical Co., Ltd.) having a width of 30 to 50 mm is attached to the outer periphery of the heat insulating material 4.
Since the adhesive layer is formed on the sticking surface of the thermally expandable fireproof tape 5, the thermal expandable fireproof tape 5 is wound on the outer periphery of the heat insulating material 4 by winding the heat expandable fire resistant tape 5 along the outer periphery of the heat insulating material 4. A heat-expandable fireproof tape 5 can be attached.

FIG. 3 is a schematic perspective view for explaining a process of forming a separation surface on a heat insulating material installed around pipes.
The said heat insulating material 4 is cut | disconnected in parallel with a horizontal division using cutting tools, such as a knife, and the said heat insulating material 4 is isolate | separated into the upper heat insulating material 4a and the lower heat insulating material 4b.
In this way, the separation surface 6 can be formed on the lower surface of the upper heat insulating material 4a and the upper surface of the lower heat insulating material 4b.
In the case of Example 1, the separation surface 6 is formed by cutting the heat insulating material 4, but the separation surface 6 shown in FIG. 3 is also formed by using, for example, two separate cylindrical heat insulating materials. be able to.

FIG. 4 is a schematic plan view for explaining a process of forming the thermally expandable fireproof sheet 7 used in the present invention.
A planar product name Fibrok DS20 (reference numeral 8) manufactured by Sekisui Chemical Co., Ltd. was cut into an annular shape to obtain thermally expandable fireproof sheet pieces 7a and 7b.
By combining these thermally expandable fireproof sheet pieces 7a and 7b, an annular thermally expandable fireproof sheet 7 can be obtained.
The diameter of the inner periphery of the annular heat-expandable fireproof sheet 7 is equal to or larger than the diameter of the piping 3, and the outer periphery of the annular heat-expandable fireproof sheet 7 is the outer periphery of the heat insulating material 4. The size fits inside.
The outer periphery of the heat-expandable fireproof sheet used in the present invention extends from the outer periphery of the heat insulating material 4 to 20 mm inward in parallel with the separation surface along a straight line passing through the outer periphery of the heat insulating material 4 and the pipes 3. It is preferable that it exists in the range.

FIG. 5 is a schematic plan view for explaining a process of inserting the thermally expandable fireproof sheet 7 into the separation surface of the heat insulating material 3. FIG. 6 is a schematic plan view of the heat expandable fireproof sheet 7 inserted into the separation surface of the heat insulating material 4. It is a schematic cross section for demonstrating the made structure.
Thermally expandable fireproof sheet pieces 7a and 7b are inserted from both sides into the separation surface 6 of the heat insulating material 4 obtained by the process described with reference to FIG.
Thereafter, the upper heat insulating material 4a and the lower heat insulating material 4b are moved along the vertical direction of the pipes 3 and the heat expandable fireproof sheet pieces 7a and 7b are combined. The sheet 7 is brought into close contact with the sheet 7.
Further, the periphery of the separation surface 6 between the upper heat insulating material 4 a and the lower heat insulating material 4 b is adhered with a heat-resistant tape 10. The heat-resistant tape 10 is indicated by a broken line in FIG.
As the heat-resistant tape 10, a commercially available product can be appropriately selected and used. Moreover, the thermally expansible fireproof tape 5 demonstrated previously can also be used.

FIG. 7 is a schematic cross-sectional view for explaining a process of adjusting the positions of the thermally expandable fireproof sheet and the thermally expandable fireproof tape inside the through hole of the horizontal section.
7 indicates the horizontal section, that is, the position of the lower end of the through hole 2 provided in the concrete wall 1, and the dashed line bb indicates the upper end of the through hole 2 provided in the concrete wall 1. It shows the position.
The separation surface of the heat insulating material 4 when the position of the lower end of the through hole 2 of the horizontal section is 0 and the position of the upper end of the through hole 2 of the horizontal section is 100% with respect to the vertical direction of the horizontal section 6 It is preferable to adjust the insertion position of the heat-expandable fireproof sheet 7 to the inside to any position within a range of 25 to 75% of the through hole 2 of the horizontal section.
When the insertion position of the heat-expandable fireproof sheet 7 is lower than 25% of the through-hole 2 in the horizontal section, the heat-expandable fireproof sheet 7 may fall from the through-hole 2 due to fire heat or the like. . Moreover, when it is higher than 75% of the through hole 2 of the horizontal section, the through hole 2 may not be sufficiently blocked.
The range is more preferably 30 to 70%, and further preferably 45 to 60%.
The insertion position of the thermally expandable refractory sheet 7 is preferably 60 mm or more from the lower end of the through hole 2.

In the present invention, the thermally expandable fireproof tape 5 installed on the outer periphery of the heat insulating material 4 is at least the outer periphery of the heat insulating material 4 installed around the piping 3 in the through hole 2. It is necessary to be installed on the outer periphery of the heat insulating material 4 below the thermally expandable fireproof sheet 7 inserted into the separation surface 6.
When the fireproof compartment penetration structure of the present invention is exposed to heat such as fire, the thermally expandable fireproof tape expands in the horizontal direction with respect to the horizontal compartment inside the through hole.
The expansion residue generated by the expansion of the thermally expandable refractory tape supports the heat insulating material above the expansion residue and the thermally expandable refractory sheet inserted into the separation surface of the heat insulating material.
Thereby, it is possible to prevent the heat insulating material from melting and falling to the lower floor before the thermally expandable refractory sheet inserted inside the separation surface of the heat insulating material expands.

A dashed line cc in FIG. 7 shows the lower surface of the thermally expandable fireproof sheet 7 in the through hole 2.
The heat-expandable refractory tape 5 used in the present invention needs to be in any position between the dashed line aa and the dashed line cc.
Here, being in any position between the one-dot broken line aa and the one-dot broken line c-c may be all the positions between the one-dot broken line a-a and the one-dot broken line cc, or one-dot broken line a-c. It means that it may be a part of the position from −a to the dashed line cc.
In addition, if the thermally expansible fireproof tape 5 used for this invention exists in one of the positions below the one-dot broken line aa and the one-dot broken line cc, a part of the said heat-expandable fireproof tape 5 is the one-dot broken line c--. It can be above c.
Moreover, if the thermally expansible fireproof tape 5 used for this invention is in the position which covers the outer peripheral part of the said heat insulating material in the range below 10 mm or more from the lower end of the through-hole of the said horizontal division and below the separation surface of the said heat insulating material. More preferred.

FIG. 8 is a schematic cross-sectional view illustrating a fireproof compartment penetrating portion structure of the first embodiment.
By filling the sealing material 11 with no gap between the heat insulating material 4 and the through-hole 2, the fireproof compartment penetration structure of the first embodiment can be obtained.
In Example 1, mortar is used as the sealing material 11. As described above, in the case of the present invention, regardless of the position of the piping 3 through which the through hole 2 is inserted, the sealing material 11 is filled between the heat insulating material 4 and the through hole 2 without any gap, thereby penetrating the fire prevention section. Excellent workability due to partial structure.
Moreover, in the case of Example 1, since the through-hole 2 is closed without a gap, even when smoke or toxic gas is generated on the upper floor or lower floor of the horizontal section, these diffusions can be prevented.
Furthermore, when the fireproof compartment penetration structure of Example 1 is exposed to heat such as a fire flame, the heat-expandable fireproof sheet 7 and the thermal expansion so as to wrap the through-hole 2 from the side surface of the through-hole 2 and the inside of the through-hole 2. The refractory tape 5 expands, and these expansion residues close and seal the through hole after the heat insulating material 4 has been melted and burned off.
Thereby, even when a fire occurs on the lower floor or the like of the horizontal section, it is possible to prevent smoke generated by the fire from being diffused or spread to the upper floor through the through hole.
Further, since the heat-expandable fireproof tape 5 expands in the same horizontal direction as the horizontal section, the heat-expandable fireproof sheet 7 falls to the lower floor when the heat insulating material 4 is melted by heat generated by a fire or the like. Can be prevented.

FIG. 9 is a schematic cross-sectional view for explaining a process of forming a separation surface on the heat insulating material installed around the piping in the second embodiment.
In the case of the fireproof compartment penetration structure of Example 1, the heat insulating material 4 was cut in parallel with the horizontal compartment to separate the heat insulating material 4 into the upper heat insulating material 4a and the lower heat insulating material 4b. In this case, the heat insulating material 4 is cut from the outside leaving the central portion in parallel with the horizontal section.
The rest is the same as in the first embodiment.
As shown in Example 2, when the separation surface is formed on the heat insulating material 4, it is possible to form the heat insulating material 4 without separating it into two.

FIG. 10 is a schematic cross-sectional view illustrating a fireproof compartment penetrating portion structure of Example 3.
In the case of the fireproof compartment penetration part structure of Example 1, one sheet of the heat-expandable fireproof sheet 7 is inserted into the separation surface 6 of the heat insulating material 4, but in the case of Example 3, two sheets of thermal expansion are used. The point which is inserted in the isolation | separation surface 6 and 6 'of the heat insulating material 4 (it is not shown in figure because it overlaps with the position of the thermally expansible fireproof sheets 7 and 7') differs.
The rest is the same as in the first embodiment.
When two or more heat-expandable fireproof sheets are used, it is preferable that a heat-expandable fireproof tape is installed on the outer periphery of the heat insulating material below the heat-expandable fireproof sheet installed at the bottom.
Further, the insertion position of the thermally expandable fireproof sheets 7 and 7 ′ inside the separation surfaces 6 and 6 ′ of the heat insulating material 4 is the same as in the case of Example 1 when two or more thermally expandable fireproof sheets are used. It is the same.
For this reason, the insertion position of the two or more thermally expandable fireproof sheets with respect to the inside of the separation surface 6 of the heat insulating material 4 can be adjusted to any position within the range of 25 to 75% of the through hole 2 of the horizontal section. preferable.
In the present invention, the heat-expandable fireproof tape 5 installed on the outer periphery of the heat insulating material 4 is not less than 10 mm from the lower end of the through hole of the horizontal section, and the heat insulating material in a range below the separation surface of the heat insulating material 4. 4 is preferably covered.
Here, the separation surface of the heat insulating material 4 means the separation surface at the lowest level. For this reason, when a plurality of separation surfaces exist in the heat insulating material 4, it is preferable to cover the outer peripheral portion of the heat insulating material 4 in any range below the lowermost separation surface.

FIG. 11 is a schematic cross-sectional view illustrating a fireproof compartment penetrating portion structure of Example 4.
In the case of Example 1, a separation surface 6 is formed on the heat insulating material 4 in parallel with the horizontal section, and the thermally expandable fireproof sheet 7 is inserted on the separation surface 6 in parallel with the horizontal section. In this case, a separation surface 6 is formed obliquely with respect to the horizontal section on the heat insulating material 4, and the thermally expandable fireproof sheet 7 is inserted into the separation surface 6 obliquely with respect to the horizontal section.
In this case, it is preferable that the entire heat-expandable fireproof sheet 7 fits in any position within a range of 25 to 75% of the through hole 2 of the horizontal section.
In addition, when the heat-expandable fireproof sheet is used obliquely with respect to the horizontal compartment, a heat-expandable fireproof tape must be installed on the outer periphery of the heat insulating material below the lowermost heat-expandable fireproof sheet. Is preferred.

12 is a schematic plan view for explaining the shape of the thermally expandable fireproof sheet used in Example 5. FIG.
In the case of Example 1, the product name Fiblock DS20 (reference numeral 8) manufactured by Sekisui Chemical Co., Ltd. in a flat shape was cut into an annular shape to obtain thermally expandable fireproof sheet pieces 7a and 7b (see FIG. 4). In the case of Example 5, the point which provided the cutting part 20 of one place in the thermally expansible fireproof sheet 70 cut off cyclically | annularly differs.
The cut portion 20 can be widened and inserted into the separation surface 6 of the heat insulating material 4.
Others are the same as those in the first embodiment.
Moreover, the modification of the shape of a thermally expansible fireproof sheet is shown to FIGS.
In the present invention, it is not limited to the circular annular shape as in the case of Examples 1 and 5. For example, as illustrated in FIG. 13, a polygonal annular thermal expansion fireproof sheet 71, as shown in FIG. As illustrated, a thermally expandable refractory sheet 72 or the like that can be formed into a polygonal annular shape by combining two or more may be used.

DESCRIPTION OF SYMBOLS 1 Concrete wall 2 Through-hole 3 Piping 4 Thermal insulation material 4a Upper thermal insulation material 4b Lower thermal insulation material 5 Thermal expansion fireproof tape 6 Separation surface 7, 7 ', 70, 71, 72 Thermal expansion fireproof sheet 7a, 7b Thermal expansion Refractory sheet pieces 8 Fiblock DS20
DESCRIPTION OF SYMBOLS 10 Heat-resistant tape 11 Sealing material 20 Cutting part 500 Pipings 510 Galvanized steel plate 520 Joint block member 530 Bolt 600 Compartment 610 Piping 620 Thermal expansion sponge material 630 Rubber molding

Claims (4)

Piping inserted through the through hole of the horizontal section provided in the partition of the structure;
A heat insulating material installed around the piping;
A thermally expandable fireproof sheet installed inside the heat insulating material;
A thermally expandable fireproof tape installed on the outer periphery of the heat insulating material;
A sealing material filled without a gap between the heat insulating material and the through hole;
A fire compartment penetrating structure having
The heat insulating material installed around the pipes in the through hole has a separation surface,
The thermally expandable refractory sheet is inserted inside the separation surface of the heat insulating material installed around the piping,
Thermally expandable fireproof tape installed on the outer periphery of the heat insulating material is inserted into at least the inside of the separation surface among the outer periphery of the heat insulating material installed around the piping in the through hole. A fireproof compartment penetration structure, characterized in that it is installed on the outer periphery of a heat insulating material below the fireproof sheet. The outer periphery of the thermally expandable refractory sheet inserted inside the separation surface of the heat insulating material installed around the piping fits inside the heat insulating material installed around the piping,
The insertion position of the thermally expandable refractory sheet with respect to the heat insulating material installed around the piping is set to 0 at the lower end of the through hole of the horizontal section with respect to the vertical direction of the horizontal section, and penetrates the horizontal section. The fire-blocking section penetrating portion structure according to claim 1, wherein when the position of the upper end of the hole is 100%, the structure is in a range of 25 to 75% of the through-hole of the horizontal section.   A heat-expandable fireproof tape installed on the outer periphery of the heat insulating material covers the outer peripheral portion of the heat insulating material in a range of 10 mm or more from the lower end of the through hole of the horizontal section and below the separation surface of the heat insulating material. Item 3. The fire prevention compartment penetration structure according to Item 1 or 2. The construction method of the structure in which the piping in which the heat insulating material is installed around is inserted into the through hole of the horizontal section provided in the partition part of the structure,
(1) installing a thermally expandable fireproof tape on the outer periphery of the heat insulating material;
(2) forming a separation surface on the heat insulating material;
(3) inserting a thermally expandable fireproof sheet inside the separation surface of the heat insulating material;
(4) With respect to the vertical direction of the horizontal section, when the position of the lower end of the through hole of the horizontal section is 0, and the position of the upper end of the through hole of the horizontal section is 100%, the inside of the separation surface of the heat insulating material While adjusting the insertion position of the thermally expandable fireproof sheet to any position within the range of 25 to 75% of the through hole of the horizontal section,
Thermally expandable fireproof tape installed on the outer periphery of the heat insulating material is inserted into at least the inside of the separation surface among the outer periphery of the heat insulating material installed around the piping in the through hole. Adjusting the position of the thermally expandable refractory tape in the through hole so as to cover the outer periphery of the heat insulating material below the refractory sheet;
(5) a step of filling a sealing material without a gap between the heat insulating material and the through hole;
The construction method of the fire prevention division penetration part structure which has at least.