JPH0828761A - Fire-preventive partition seal material, and fire-prevention method for fire-preventive partition penetration part using this seal material - Google Patents

Abstract

PURPOSE:To shorten the construction period, reduce the construction cost and facilitate the additional construction for wiring or piping. CONSTITUTION:A penetration part 2 for inserting a cable wire 7 and a pipe is provided on a floor wall 1 of a fire-preventive zone, and a fire-preventive cylinder frame 3 is installed. Next, seal material 8, 9, 10 comprising inorganic light aggregate, a swelling type layer of silicate, and water kneaded with each other is filled in a gap of a through-hole in a plate 4 of calcium silicate through which the cable line 7 is inserted.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a penetration portion of a fireproof compartment opened in a building such as a wall, floor, or ceiling of a building, or after wiring / piping the penetration portion of the fireproof compartment, a penetration portion and a wire / pipe. The present invention relates to a sealant for a fireproof section for fireproofing a void between the two and a fireproofing method using the sealant.

[0002]

2. Description of the Related Art Calcium silicate boards, rock wool, and
There are non-combustible putties made of aluminum hydroxide, kaolin (clay), etc. When using these, the measure method is
A calcium silicate plate, a non-combustible putty, rock wool, a calcium silicate plate, and a non-combustible putty are sequentially installed on the penetrating portion. This conventional method has the problems that the cost is high and the material is heavy due to the use of two calcium silicate plates and non-combustible putty, and the workability is poor. Further, even when additional work such as piping is performed in the same fire protection compartment penetration part, it is necessary to remove the filled sealing material and then perform the work again. The rock wool used as a raw material tends to be rejected as industrial waste, and there has been a strong demand for a substitute product.

[0003]

The problem to be solved by the present invention is to develop a new sealing material for a fireproof compartment, which is lightweight and has a high fireproof property. To provide a sealant for a fireproof section of a penetration part of a fireproof section and a fireproofing method using the sealant, which can solve the problems, reduce the construction time, reduce the construction cost, and facilitate additional construction. is there.

[0004]

DISCLOSURE OF THE INVENTION The present inventors have added an inorganic lightweight aggregate with a swellable layered silicate and water,
It is lightweight and has a large heat insulation effect.In addition, the hardness and finish can be adjusted by changing the type and mixing ratio of raw materials and adding cement if necessary, and removal and additional work can be done quickly. We have developed an epoch-making sealant material for fireproof compartments, and have come to solve the problem.

The composition of the present invention which has solved the problem is as follows: 1) A lightweight inorganic aggregate, a swelling layered silicate, and a water-kneading sealant for fireproof compartments 2) 100 parts by weight of the inorganic lightweight aggregate , 1 to 300 parts by weight of the swellable layered silicate and 50 to 500 parts by weight of water, 3) a sealant for a fireproof compartment according to 1), 3) the inorganic lightweight aggregate is perlite, vermiculite,
Wollastonite, pumice, volcanic debris, silas balloon,
Among the artificial lightweight aggregates, 1 or 2 or more types are the sealing materials for fireproof compartments according to 1) or 2) 4) The swellable layered silicate is obtained by an intercalation method using talc as a main raw material. The sealant for fireproof compartment according to 1) or 2) above, which is a swellable synthetic layered silicate. 5) The sealant for fireproof compartment according to 1) to 4), which is mixed with cement. 6) The amount of cement mixed is 400 parts by weight or less with respect to 100 parts by weight of the inorganic lightweight aggregate, 7) the sealant for a fireproof compartment according to the above 5), 7) the above-mentioned in the void of the fireproof compartment penetration portion of the building frame, 1) ~
6) A method of fire prevention measures for a penetration portion of a fire protection compartment, which is characterized by being filled with a sealant for a fire protection compartment described in 8). 6) The sealant for a fireproof compartment described above is filled and closed, and after being closed, the sealant for a fireproof compartment described in 1) to 4) is filled into the inside of the fireproof cylinder frame, and after the filled sealant A method for preventing fire in a penetration part of a fireproof compartment, characterized by filling the sealant for fireproof compartment according to the above 5) or 6). Further, the constitution of the present invention includes: 9) the sealant for a fireproof compartment according to the above 1) or 2), wherein the swellable layered silicate is a swellable mica and / or smectite; In the void, the above 9)
A fireproofing method for a penetration portion of a fireproof compartment, characterized in that the sealant for a fireproof compartment described above is filled.

That is, the present invention relates to an inorganic lightweight aggregate, a swelling layered silicate, and a water-kneading sealant for a fireproof compartment, and a method for fireproofing a penetration portion of the fireproof compartment using the same. Furthermore, the present invention relates to the above-mentioned sealant for a fireproof compartment, in which cement is mixed, and a fireproofing method for a penetration portion of the fireproof compartment using the sealant.

The sealant for a fireproof compartment of the present invention will be described in detail below.

The inorganic lightweight aggregate is not particularly limited as long as it is lightweight and its strength is not significantly reduced by mixing. For example, perlite, permiculite, wollastonite, pumice, volcanic gravel, shirasu balloon, And artificial lightweight aggregates can be used.

The perlite is preferably that described in JIS-A5007, and examples thereof include pearlite perlite obtained by firing pearlite and obsidian perlite obtained by firing obsidian.

Vermiculite is JIS-A5009.
Those described in 1) are preferable, and examples thereof include vermiculite obtained by burning leeches.

The wollastonite preferably has a small unit volume mass.

Examples of the artificial lightweight aggregate include those described in JIS-A5002, and examples thereof include expanded shale, expanded clay, expanded slate, and calcined fly ash.

The inorganic lightweight aggregate is perlite described above,
It is preferable to use one or more of vermiculite, wollastonite, pumice, volcanic rubble, shirasu balloon, and artificial aggregate. Since this inorganic lightweight aggregate serves as an aggregate and a heat insulating material, and has different properties depending on the particle size and the like, it is necessary to use this in consideration of this point.

The inorganic lightweight aggregate has an average particle size of 0.3.
Perlite less than mm, or the perlite and average particle size 0.3
It is preferable to use it in combination with an inorganic lightweight aggregate of mm or more. This is because pearlite has excellent heat insulating properties, and by using aggregates with different particle sizes, strength and
This is to improve air tightness. Specifically, the average particle size is 0.
It is preferable to use perlite having a diameter of less than 3 mm and perlite having an average particle diameter of 0.3 mm or more, vermiculite and wollastonite in combination.

The swellable layered silicate swells when added to water, has a viscous, sol or gelation action,
It is a layered silicate having a cation exchange ability and exhibiting unique properties, and examples thereof include swelling mica and smectite. Further, a swelling synthetic layered silicate obtained by an intercalation method using talc as a main raw material is also applicable.

This swellable layered silicate is a clay mineral different from the kaolin mineral used for noncombustible putty and the like.

The swelling mica is a swelling mica which is naturally or chemically synthesized, such as Li-type fluorine teniolite, Na-type fluorine teniolite, Na-type tetrasilicon fluorine-mica, Li-type tetrasilicon-fluorine mica, etc. And Na
Examples thereof include swellable mica having an ion, a substitution product or derivative thereof, or a mixture thereof. As a commercially available product, synthetic swelling mica: ME (Corp Chemical Co., Ltd.)
Manufactured), Dimonite: DP-DM and the like.

Examples of the swellable synthetic layered silicate obtained by the intercalation method using talc as the main raw material used in the present invention include those described in the general formula (1). X0.1-1.2 Y2.0-3.5 Z3.5-4.5 O9.5-10.5 F1.5-2.5 Formula (1) (In the formula, X represents Na and / or Li, and Y represents Mg or (Mg
And a mixture of Al and Z is Si or a mixture of Si and Al or a mixture of Si and Mg or a mixture of Si and Al.
And a mixture of Mg). ) In the formula (1), X is an atom that enters an interlayer position of the swelling layered silicate, Y is an atom that enters an octahedral position,
Z is an atom that enters the tetrahedral position.

The swellable synthetic layered silicate can be obtained, for example, by adding a mixture of talc and sodium silicofluoride or lithium silicofluoride to sodium fluorite, as described in JP-B-6-27002. , Lithium fluoride, aluminum oxide, etc.
It is obtained by heat treatment at 00 to 1200 ° C.

The swellable synthetic layered silicate is a 2: 1 type layered silicate and includes a compound that falls into the category of mica and a compound that falls into the category of vermiculite according to the classification of minerals. The swelling synthetic layered silicate obtained by this intercalation method is particularly excellent in swelling property. In water, the thickness is 0.1 μm or less, and the size in the plane direction is several μm to several tens μm on one side. It has the feature that it becomes fine flaky fine particles and is dispersed. Specific examples thereof include synthetic swelling mica: ME (manufactured by Corp Chemical).

Examples of smectites include natural or chemically synthesized substances such as hectorite, saponite, stevensite, beidellite, montmorillonite and nontronite, and their substitution products, derivatives and mixtures thereof. As commercial products, Lucentite,
Veegum, Kunipia, Lavonite and the like can be mentioned. As the smectite, a synthetic smectite is more preferable, and a particularly preferable one is to synthesize a silicon-magnesium complex by reacting an alkaline solution with a homogeneous mixed solution of silicic acid and magnesium salt by the method described in Japanese Patent Publication No. 61-12848. Then, after removing the by-produced electrolyte, lithium ions and, if necessary, sodium ions and / or fluorine ions are added to the complex, which is hydrothermally reacted at 100 ° C. to 350 ° C. and then dried. The synthetic smectite of the general formula (2) can be used. Na0.1-1.0 Mg2.4-2.9 Li0.1-0.6 Si3.5-4.5 O9.5-10.5 (OH and / or F) 1.5-2.5 (2) As a specific example, Lucentite: SW (Corp Chemical) (Manufactured by Co., Ltd.).

The swellable layered silicate raises the viscosity and generates a binding force, but if the content is too large, it becomes difficult to handle as a filler, and if it is insufficient, an appropriate viscosity cannot be obtained and the binding force is also increased. Run short. Therefore, the practical range of the swellable layered silicate of each sealant for fireproof compartments is determined in view of the viscosity, bonding force, and correlation with other components required for each sealant for fireproof compartments.

The cement is preferably Portland cement.

When cement is used, it is mixed in a large amount if the durability, strength and hardness of the bonding force are required, but if it is too small, the bonding force, strength and hardness are insufficient, and if it is too large. Since it becomes too hard, a preferred range is selected.

Since the sealant for a fireproof compartment of the present invention is obtained by combining raw materials having different characteristics, the hardness and the finished state can be adjusted by the kind and mixing ratio of the raw materials used. There are features. When only inorganic lightweight aggregate, swellable layered silicate and water are used as raw materials, it is possible to create a blunt-shaped seal material for fireproof compartments, and adding cement to this will increase hardness, but It is possible to create products with slightly different physical properties by changing the type and blending ratio. In addition, the sealant for a fireproof compartment of the present invention,
It does not matter if an inorganic filler such as aluminum hydroxide or a flame retardant such as antimony trioxide is added. These sealing materials for fireproof compartments may be used alone or in combination of two or more having different properties.

The preferred mixing ratio of the sealant for fireproof compartment of the present invention is 1 to 300 parts by weight of the swellable layered silicate and 50 to 500 parts by weight of water with respect to 100 parts by weight of the inorganic lightweight aggregate. . Furthermore, when the cement is mixed in the raw material, the preferable mixing ratio is 400 parts by weight or less of the cement with respect to 100 parts by weight of the inorganic lightweight aggregate.

Specific examples of the three types of sealing materials for fireproof compartments (hereinafter referred to as sealing materials) will be shown below. The sealing material of the present invention includes the following three types of sealing materials (seal material A, seal material). It is not limited to the material B and the seal material C.).

The sealing material A is composed of pearlite having an average particle size of less than 0.3 mm, swellable layered silicate, cement and water. The preferred composition is 30 to 250 parts by weight of the swellable layered silicate, 150 to 250 parts by weight of cement, and 350 to 500 parts by weight of water with respect to 100 parts by weight of perlite having an average particle size of less than 0.3 mm. is there. More preferably, the pearlite is pearlite pearlite having an average particle size of 0.15 to 0.3 mm, and the cement is Portland cement. The swelling layered silicate may have a composition of 30 to 200 parts by weight when the swelling synthetic layered silicate obtained by the intercalation method using synthetic swelling mica or talc as a main raw material is used. preferable.

Here, pearlite having an average particle size of 0.3 mm or more and less than 2.5 mm and one or a mixture of two or more of vermiculite and wollastonite are used as aggregate A, and the average particle size of 2.5 mm or more is used. Perlite, vermiculite,
The aggregate B is one kind of wollastonite or a mixture of two or more kinds thereof.

The sealing material B is composed of pearlite having an average particle size of less than 0.3 mm, aggregate A, aggregate B, swellable layered silicate, and water, and no cement is used. A preferable composition is 100 to 200 parts by weight of aggregate A and 300 to 400 parts of aggregate B with respect to 100 parts by weight of pearlite of less than 0.3 mm.
By weight, the swellable layered silicate is 30 to 200 parts by weight, and water is 450 to 1000 parts by weight. As perlite having an average particle size of less than 0.3 mm, pearlite perlite having an average particle size of 0.15 to 0.3 mm is preferable. Further, the aggregate A is preferably pearlite perlite having an average particle size of 0.4 mm to less than 2.5 mm, and the aggregate B is an average particle size of 2.5 mm.
More preferably, obsidian perlite, vermiculite, wollastonite and a mixture thereof having a size of 5.0 mm or less and less than 5.0 mm are preferable. As the swellable layered silicate, when the swellable synthetic layered silicate obtained by the intercalation method using synthetic swellable mica or talc as a main raw material is used, 50 to 200 parts by weight of synthetic smectite is used. It is more preferable that the composition is 30 to 150 parts by weight.

The sealing material C is composed of pearlite having an average particle size of less than 0.3 mm, aggregate A, swellable layered silicate, cement, and water. The preferred composition is 300 to 400 parts by weight of aggregate A and 10 parts by weight of swellable layered silicate to 100 parts by weight of perlite having an average particle size of less than 0.3 mm.
~ 150 parts by weight of cement, 800 to 1500 parts by weight of cement and 1000 to 2000 parts by weight of water. In addition,
Perlite with an average particle size of less than 0.3 mm has an average particle size of 0.1
The pearlite perlite having a diameter of 5 to 0.3 mm is preferable, and the aggregate A is preferably obsidian perlite having an average particle diameter of 1.2 to 2.0 mm, verculite, wollastonite and a mixture thereof. . Further, the cement is preferably Portland cement. Further, the swelling layered silicate is 15 to 150 parts by weight when the swelling synthetic layered silicate obtained by the intercalation method using synthetic swelling mica or talc as a main material is used.
When using synthetic smectite, the composition is preferably 10 to 100 parts by weight.

The fire prevention method for the penetration portion of the fire prevention compartment of the present invention will be described in detail below.

The fireproofing method of the penetration portion of the fireproof compartment of the present invention is characterized in that the above-mentioned sealing material for the fireproof compartment is filled in the void of the penetration portion of the fireproof compartment of the building frame.

The method of fire prevention of the penetration portion of the fireproof compartment of the building frame that penetrates the cable / pipe is as follows: the voids of the penetration portion of the fireproof compartment are filled with the above-mentioned fireproof compartment sealant mixed with cement. Closing, and after filling the inside of the fire-prevention cylinder, the above-mentioned sealant for fire-prevention compartment that does not contain cement is filled, and further filled with the sealant for fire-prevention compartment that has been mixed with cement after the filled sealant. Preferably.

Next, a specific fire protection method using the above-mentioned three kinds of sealing materials (sealing material A, sealing material B, sealing material C) will be described. It is not limited to the case of using the sealing material.

When taking measures for the penetration part of the fireproof compartment,
The three kinds of sealing materials described above are used alone or in combination. When used alone, it is desirable to use the sealing material B. When using two kinds of sealing materials, it is preferable to use the sealing material B and the sealing material A, or the sealing material B and the sealing material C. Further, the sealing material of the present invention can be used in combination with the conventional method.
In particular, the sealing material B is also useful as a substitute for rock wool in combination with the conventional method.

When using three kinds of sealing materials, it is most preferable to use the sealing material A as the sealing material which is first applied to the void of the penetration portion of the fire protection compartment. Also, the sealing material B
Is most preferably used as a sealing material to be filled in the fireproof cylinder frame, and the sealing material C is most preferably used as a sealing material with a relatively high water content applied from above the sealing material B.

Specifically, only one calcium silicate plate is used, and one opening of the fireproof cylinder is closed, and then the above-mentioned sealing material A is lined with the inner surface of the through hole of the calcium silicate plate. The gap between the outer circumference of the tube and the outer circumference of the tube is applied to close the tube in an airtight manner. After that, the above-mentioned sealing material B is filled in the fireproof cylinder frame, and after filling, the above-mentioned sealing material C is replaced with the sealing material B.
Apply from above to complete the sticker.

In addition, wiring and wire are connected to the fire prevention part of this penetration part.
When additional work is to be done on the pipe, first, the insertion space for the wire / pipe is drilled in the action area, but since the sealing material is relatively soft, the sealing material in the insertion space area can be easily removed. After wiring and piping in this insertion space, the sealing material is replenished in the space around the wire / pipe to complete the process. Especially, the sealing material B is
Since cement is not used as a raw material, it becomes soft again just by adding water, so it can be backfilled and can be reused, so additional work can be done quickly and easily.

[0040]

The sealing material of the present invention is composed of an inorganic lightweight aggregate, a swelling layered silicate and water. Further, by changing the kind and mixing ratio of the raw materials, and by adding cement if necessary. It is a sealing material that can control properties such as viscosity and hardness, greatly reduce the construction time, improve the finished state, and can be reused.
It is considered that the swelling layered silicate that disperses in water and exhibits thixotropic properties plays a large role in improving the properties.

The sealing material A is a sealing material containing cement and having a low water content, and is filled in the gap between the cable and the fireproof plate to prevent smoke or fire from entering. The sealing material B is a sealing material that does not contain cement or the like and is composed of an inorganic lightweight aggregate, a swelling layered silicate, and water, and has a rugged shape, and functions as a filler. The seal material C is a seal material containing cement and having a relatively large amount of water, and is poured onto the seal material B and finished by pressing with a trowel, and functions as a cosmetic sheet material. These sealing materials A, B, C
Workability is significantly improved by performing the steps in sequence.

[0042]

【Example】

Example 1 [Manufacture of sealing material] The components shown in Tables 1 to 8 were blended to prepare sealing materials A1 to C3.
Was manufactured.

[Table 1]

[Table 2]

[Table 3]

[Table 4]

[Table 5]

[Table 6]

[Table 7]

[Table 8] Since the sealing material A1 is mixed with synthetic swelling mica (Somasif: ME manufactured by Coop Chemical Co., Ltd.), the sealing material A1 has an appropriate viscosity, and it is easy to apply it to close the voids. Also, after curing, with Portland cement,
The required hardness occurs. The sealing material A2 is mixed with synthetic smectite (Lucentite SW manufactured by Coop Chemical Co., Ltd.) and exhibits the same performance as the sealing material A1. Since the sealing materials B1, B2, B3 also contain synthetic swelling mica or synthetic smectite, they are both viscous, easy to fill, and form a noncombustible fireproof wall. The sealing materials B1, B2, B3 can obtain a proper binding force after drying without mixing cement. Moreover, when water is added again, it returns to the state before drying, becomes soft and easy to remove. Each of the sealing materials C1, C2, and C3 contains a large amount of Portland cement, and the surface thereof is in a state close to that of cement and, after drying, has a high hardness and a binding force.

Example 2 [Construction of fire protection structure A] A production example of a fire protection partition structure A using the sealing material of the present invention will be described below with reference to the drawings. In the figure, 1 is a floor wall of a fireproof section of a building frame, 2 is a penetration part of the floor wall 1, 3 is a penetration part 2
A steel fireproof cylinder frame that can be divided and is attached to the inner surface of 4 is a fireproof plate that is attached to one opening 6 of the fireproof cylinder frame. Cable of the same calcium silicate board
A through hole for passing a pipe, 7 is a cable wire, 8 is a sealing material A1 having the components shown in Table 1 below, 9 is a sealing material B1 having the components shown in Table 3 below, and 10 is a sealing material C1 shown in Table 6 below. Is. First, a cable wire 7 and a penetrating portion 2 for passing a pipe are provided on a floor wall 1 of a fireproof compartment. Wiring and piping are performed on this penetrating portion 2, and a fireproof cylinder frame 3 that is assembled by being divided is attached. Next, a disk-shaped calcium silicate plate 4 is placed in the lower opening of the fire protection cylinder frame 3 (see FIG. 1 (a)). Next, the sealing material A1 (8 in the figure) is applied to the space of the through hole 5 of the calcium silicate plate 4 through which the cable wire 7 passes (FIG. 1 (b)).
reference). The sealing material A1 prevents smoke and flame from entering through the through hole 5 and functions as a non-combustible seal. After the seal material A1, the fire preventive barrel 3 is filled with the seal material B1 (9 in the figure) (see FIG. 1C). After filling the sealing material B1 (9 in the figure), the sealing material C1 (10 in the figure) is provided on the surface thereof.
Pour in and finish with iron presser, then fire-proof compartment structure A
Get. (See FIG. 1 (d) and FIG. 2).

Example 3 [Construction of fireproof compartment structure B] Sealing materials A1, B1 and C1 were replaced with sealing materials A2, B2 and C2.
A fireproof partitioned structure B was obtained in the same manner as in Example 2 except that the above was changed to.

Example 4 [Construction of fireproof partition structure C] A fireproof partition structure C was obtained in the same manner as in Example 2 except that the seal materials B1 and C1 were replaced with seal materials B3 and C3. Comparative Example [Construction of a comparative fireproof compartment structure by a conventional method] A cable wire 7 similar to that of Example 2 is passed through a fireproof compartment similar to that of Example 2, and a lower plate cutting process and a lower plate seal filling are performed according to a conventional method. Rock wool filling, cutting upper plate, fixing upper plate,
Seal filling and molding were performed to obtain a comparative fireproof compartment structure.

Example 5 [Time required for obtaining fireproof compartment structures] Table 9 shows the time required for obtaining fireproof compartment structures A, B, C and comparative fireproof compartment structures.

[Table 9] As described above, by using the sealing material of the present invention, only one calcium silicate plate is required, and the work of filling the sealing agent having an appropriate viscosity is sufficient. Therefore, the construction time is about 1/3 of that of the conventional method. Can be shortened to.

Example 6 [Additional work] Fireproof compartment structures A and B, through which two cables are passed.
A hole having a diameter of 40 mm was drilled with a drill in the center of C and the comparative fire protection compartment structure. After that, additional work was done to pass the cable. The hole was not broken and the hole was opened and additional work could be done to pass the cable through .-------- The hole did not work well and the cable was disassembled and additional work was done to pass through the cable. The results are shown in Table 10 as x.

[Table 10] Since the sealing material of the present invention can be perforated, it is possible to easily carry out additional expansion work for cables and the like without disassembling.

[0048]

The sealing material of the present invention is composed of an inorganic lightweight aggregate, a swellable layered silicate, water and, if necessary, cement, and is lightweight, and the type and mixing ratio of raw materials used can be changed. As a result, properties such as viscosity and hardness can be controlled. Therefore, it is possible to easily adjust the sealing material of the fireproof compartment to meet various requirements, and it is possible to widely deal with it. In particular, the sealing material obtained without adding cement is characterized in that it can be easily hollowed out after construction, and can be reused by adding water to the hollowed-out sealing material for reuse.
The fire prevention method for the penetration of the fire prevention compartment of the present invention using the above-described sealing material enables the simplification of the fire prevention process as compared with the conventional method, which greatly reduces the construction time and also the construction cost. Can be cheaper. In addition, there is a great merit that the work can be easily reworked, changed, and dismantled.

[Brief description of drawings]

FIG. 1 is a process chart showing an embodiment of the present invention.

FIG. 2 is a cross-sectional view showing a fire protection structure of a penetration portion of a fire protection compartment of the embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Floor wall 2 Penetration part 3 Fire prevention cylinder frame 4 Calcium silicate board 5 Through hole 6 Opening part 7 Cable line 8 Seal material A1 9 Seal material B1 10 Seal material C1

Claims (8)

[Claims] 1. A sealant for a fireproof compartment, which is obtained by kneading an inorganic lightweight aggregate, a swelling layered silicate and water. 2. The swellable layered silicate is 1 to 300 parts by weight and the water is 50 to 50 with respect to 100 parts by weight of the inorganic lightweight aggregate.
The sealant for a fireproof compartment according to claim 1, which is 0 part by weight. 3. The fire protection according to claim 1 or 2, wherein the inorganic lightweight aggregate is one or more of perlite, vermiculite, wollastonite, pumice, volcanic rubble, shirasu balloon and artificial lightweight aggregate. Sealing material for compartments. 4. The sealant for a fireproof compartment according to claim 1, wherein the swellable layered silicate is a swellable synthetic layered silicate obtained by an intercalation method using talc as a main raw material. 5. The sealant for a fireproof compartment according to claim 1, wherein cement is mixed. 6. An inorganic lightweight aggregate 10 containing a large amount of cement.
The sealing material for a fireproof compartment according to claim 5, which is 400 parts by weight or less with respect to 0 parts by weight. 7. A space in a fire protection compartment penetration portion of a building frame,
A method for fire protection of a penetrating portion of a fire protection compartment, comprising filling the sealing material for a fire protection compartment according to any one of claims 1 to 6. 8. The inside of the fire-prevention cylinder after filling and closing the gap in the penetration portion of the fire-prevention compartment of the building body penetrating the cable / pipe with the sealant for fire-prevention compartment according to claim 5 or 6. Is filled with the sealant for a fireproof compartment according to claim 1,
A method for fire protection of a penetration part of a fireproof compartment, characterized in that the sealant for fireproof compartment according to claim 5 or 6 is further filled after the filled sealant.