WO2011151937A1 - Fireproof construction for ships, method of constructing fireproof construction, and method of adding/removing/exchanging cable to/from/in temporary fireproof construction - Google Patents

Abstract

Provided is a fireproof construction that is especially suited for ships in which rolling/pitching and vibration are to be generated, and wherein a possibility of falling off thereof is nonexistent, the weight thereof is light, workability thereof is excellent, changes in the design thereof can be easily accommodated, and adding of cables thereto is easy. The fireproof construction (1) is comprised of a fire wall (3) that is a partitioning section mainly for partitioning the rooms; an opening (5) formed on the fire wall (3); a plurality of cables (7) wired through the opening (5); and sealing members (11) and a fire prevention filler (13) formed so as to fill the gap between the inner face of the opening (5) and the cables (7). The plurality of cables (7) are inserted through the opening (5). The block-formed fire prevention filler (13) is filled into the gaps between the opening (5) and the cables (7), in the vicinity at approximately the center of the opening (5) in the inserting direction of the cables. The fire prevention filler (13) has a ceramic fiber blanket (17) that is noninflammable material formed therein, and the outer circumference thereof is covered with cover material (15).

Description

Fire prevention structure of ship, construction method of fire prevention structure and addition / removal / replacement method of cable to temporary fire prevention structure

The present invention relates to a fire prevention structure of a ship in which a cable penetrates a fire prevention wall of a ship or a fire prevention section of a floor.

There are cases where cables such as electric wires and communication lines are arranged from the electrical room of the ship to each facility and each room. In this case, since the cable is usually covered with a flammable sheath, once a fire occurs, the fire travels along the cable and spreads throughout the ship, possibly causing serious damage. Therefore, the ship is partitioned by a fire wall and a floor at regular intervals, and the cable is laid so as to penetrate the fire wall.

The cable penetrates the opening provided in the fire wall, and the gap between the cable and the opening is backfilled with a refractory material. At this time, since a refractory material may fall off due to long-time shaking or vibration in a ship, a curable refractory material is used for the fireproof structure of the ship.

As such a fireproof structure using a curable fireproof material, for example, a filler receiving device provided on a fire wall is filled with a nonflammable solidified seal and the cable is fixed by solidifying the seal. There is a prevention structure (Patent Document 1).

In addition, there is an insertion device in which a concave block made of flame-retardant rubber having a cable through hole in the center is arranged on a gripping frame installed on a fire wall of a ship, and the cable is wired in the block so as to sandwich the cable ( Patent Document 2).

Japanese Patent Laid-Open No. 11-308736 JP 2005-513981 gazette

However, in the fire spread prevention structure of Patent Document 1, it is necessary to destroy and remove the solidified sealing material for replacement or addition of the cable penetrating the fire wall. Therefore, man-hours are required, the existing cable may be damaged when the seal material is destroyed and refilled, and it takes time to destroy the seal material. There is a fear.

In addition, since the insertion device described in Patent Document 2 uses a concave block made of rubber, at the time of re-connection, it may be disassembled by disassembling it, but in order to cope with various outer diameters of cables. The workability is poor because the inner wall of the rubber block must be finely peeled off.

In addition, since it is necessary to work by loosening the gripping frame, it is necessary to retighten the entire cable. Furthermore, since the cable is fixed to the block by the frame, one cable is required for one block. There is a problem that only the cable can be routed, and a space for the cable is required.

The present invention has been made in view of such problems, and is particularly suitable for ships that generate shaking and vibration. There is no fear of dropping off, and it is lightweight, has excellent workability, and can easily cope with design changes. An object of the present invention is to provide a fire prevention structure in which a cable can be easily added.

In order to achieve the above-described object, a first invention is a fire prevention structure for a ship, wherein a cable is passed through an opening formed in a partition, and an inner surface of the opening and the cable are connected to each other. The gap is filled with a plurality of fireproof fillers, and at least one of the fireproof fillers is covered with a curable putty-like sealing member, and the fireproof filler is made of a resin nonwoven fabric or a natural fiber woven fabric or a synthetic fabric. A fire prevention structure for a ship, characterized by being composed of an inorganic fiber covered with a fiber woven fabric. The curable seal member includes at least one selected from the group consisting of a hydrated metal compound, clay, talc, aluminum hydroxide and calcium carbonate, and further, as a thermal expansion material, thermal expansion graphite, pearlite, vermiculite and A ceramic fiber blanket may be used as the inorganic fiber including at least one selected from the group consisting of borax. The shape of the cross-section of the fireproof filler is not particularly limited as long as it can be packed in the opening without any gap, but is not limited to a rectangle, a square, a trapezoid, a circle, an ellipse, an n-gon (N = In view of filling of the opening, it is preferable that at least any one shape or two or more shapes having good objectivity of 3 to 6) are provided.

The partition part is a floor part, a support fitting is provided from above the floor part, the fireproof filler is supported by the support fitting, and the seal is provided so as to cover the fireproof filler from above the fireproof filler. A member may be provided.

The partition part may be a wall part, the fireproof filler may be provided at substantially the center of the opening, and the seal member may be provided so as to cover the fireproof filler from both sides of the fireproof filler.

According to the first invention, since the fireproof filler is used, the gap between the cable and the opening can be easily filled, and the temporary fireproof structure can be easily configured. Note that the temporary fire prevention structure refers to a structure that fires a section of a ship in a stage before complete completion in a construction period of a ship that performs cable wiring work. The fireproof filler is composed of inorganic fibers such as ceramic fiber blankets covered with resin nonwoven fabrics, natural fiber woven fabrics, or synthetic fiber woven fabrics. Even so, the weight is about 1/10, and the workability is excellent. Also, no curing time is required. Moreover, since the fireproof filler is easily deformed and is in close contact with the outer surface of the cable and the inner surface of the opening, it is possible to prevent the spread of fire.

In addition, since the outer periphery of the fireproof filler is covered with a non-woven fabric, the inorganic fiber inside does not scatter during handling, and when the fireproof filler is installed and removed, the fireproof filler is slippery and works. Excellent in properties. Moreover, since the cross-sectional shape of the fireproof filler is at least one of a rectangle, a square, a trapezoid, a circle, an ellipse, and an n-gon (N = 3 to 6), it is substantially uniform with respect to the opening. Filled.

Also, since a putty-like curable sealing member is provided outside the fireproof filler, it does not fall off due to vibration or shaking.

Moreover, since the fireproof filler can be easily removed in a state before the curable seal member is provided, it is possible to easily cope with a case where the number of cables is changed. At this time, there is no risk of damaging other cables.

In addition, when the partition part is a floor, a support fitting is installed from above, the fireproof filler is supported by the support fitting, and a curable seal member is provided from above, so that the work can be performed only from above the floor. It can be carried out. Moreover, when a partition part is a wall part, by providing a sclerosing | hardenable sealing member from both sides, a fire spread can be prevented reliably and falling-off of a fire prevention structure can be prevented.

2nd invention is the construction method of the fire prevention structure of a ship, Comprising: The process which passes a cable through the opening part formed in the division part, A some fireproof filler in the clearance gap between the inner surface of the said opening part, and the said cable And a step of providing a curable seal member on the opening side of the opening so as to cover the fireproof filler, the fireproof filler being made of resin nonwoven fabric or natural fiber weave. It is a construction method of a fireproof structure characterized by comprising an inorganic fiber covered with a cloth or a synthetic fiber woven fabric.

When using fireproof fillers of a plurality of sizes, a thin (thin) fireproof filler can be used in a narrow portion around the cable as compared to the opening other than around the cable. By doing in this way, a fireproof filler can be closely filled also into the narrow part around a cable. In addition, as the fireproof filler, a plurality of sizes of fireproof fillers that are substantially constant in width and thickness and differ only in length may be used. By doing in this way, it can divide into the space where an opening part is narrow, and a wide space, and can use the fireproof filler with which width | variety, thickness, or a shape differs.

According to the second invention, since the fireproof filler is lightweight, it is excellent in workability, and since the fireproof filler can be easily removed and filled, it can be adapted to the arrangement of the cable and the size of the opening. It is possible to cope with various aspects. In particular, if the fireproof filler has a plurality of sizes, it is possible to select and combine fireproof fillers to be used according to the installation mode, and by changing the length and thickness with a constant width, Depending on the size, fireproof fillers of different lengths can be selected. Even in this case, the thickness of the fire prevention structure formed in the opening (corresponding to the width of the fire prevention structure) can be made constant.

A third invention is a method for adding, removing, and replacing a cable with respect to a temporary fire prevention structure of a ship, wherein the cable is passed through an opening formed in a partition, and a resin nonwoven fabric or a natural fiber woven fabric, Part of the fireproof filler with respect to a temporary fireproof structure in which a plurality of fireproof fillers composed of inorganic fibers covered with a synthetic fiber woven fabric are filled in the gap between the inner surface of the opening and the cable Or a step of removing all, a step of adding a cable to the opening, or a step of removing a cable from the opening or replacing the cable, and a plurality of gaps between the inner surface of the opening and the cable. Adding a cable to the temporary fire prevention structure comprising: a step of refilling the fireproof filler, and a step of providing a curable sealing member on the opening side of the opening so as to cover the fireproof filler. It is a Sa exchange method.

According to the third aspect of the present invention, it is possible to easily add, remove, and replace cables with respect to the temporary fire prevention structure.

According to the present invention, a fire prevention structure that is particularly suitable for ships that generate vibrations and vibrations, has no fear of dropping off, is lightweight, has excellent workability, can easily cope with design changes, and can easily add cables. Can be provided.

The perspective view which shows the fire prevention structure 1. FIG. The front view of the fire prevention structure 1. FIG. It is sectional drawing of the fire prevention structure 1, and is the sectional view on the AA line of FIG. It is a figure which shows the fire prevention filler 13, (a) is a perspective view, (b) is the BB sectional drawing of (a). Sectional drawing which shows the process of constructing the fire prevention structure. Sectional drawing which shows the process of constructing the fire prevention structure. The front view which shows the temporary fire prevention structure 20. FIG. Sectional drawing which shows the process of adding a cable to the temporary fire prevention structure 20 Sectional drawing which shows the process of refilling the fireproof filler to the temporary fireproof structure 20 to a cable. The front view which shows the temporary fire prevention structure 20a. (A) is sectional drawing which shows the temporary fire prevention structure 30, (b) is sectional drawing which shows the fire prevention structure 40.

Hereinafter, embodiments of the present invention will be described in detail. 1 is a perspective view showing a fire prevention structure 1 according to the present invention, FIG. 2 is a front view of the fire prevention structure 1, and FIG. 3 is a cross-sectional view taken along line AA of FIG.

The fire prevention structure 1 mainly includes a fire wall 3 that is a partition part that divides a room, an opening 5 formed in the fire wall 3, a plurality of cables 7 installed in the opening 5, and an opening 5 It is comprised from the sealing member 11 and the fireproof filler 13 (FIG. 3) provided so that the clearance gap between an inner surface and the cable 7 might be plugged up.

The fire wall 3 is formed of a steel plate in the case of a ship. A heat insulating material 9 is provided on at least one side surface of the fire wall 3. The opening 5 is formed in a through hole provided in the fire wall 3 by forming a steel plate into a cylindrical shape (in the example shown in the figure, a cylindrical shape having a substantially rectangular cross section). The periphery of the opening 5 is joined to the fire wall 3 by welding, for example. Further, a heat insulating material 9 is provided on at least one end edge of the opening 5.

A plurality of (a plurality of types of) cables 7 are passed through the opening 5. It is desirable that the cross-sectional size of the opening 5 is set larger than the necessary insertion area of all cables 7. That is, it is desirable that there is still a space in the opening 5 with the cable 7 being inserted through the opening 5 in order. This is because the construction of a ship has a long period of time, and in the meantime, it may be necessary to add a cable to a design change, construction mistake, or member failure. Instead of the cable 7, a long pipe can be provided.

As shown in FIG. 3, a block-shaped fire-proof filler 13 is provided in the gap between the opening 5 and the cable 7 in the vicinity of the center of the opening 5 in the cable insertion direction. Therefore, the gap between the inner surface of the opening 5 and the cable 7 is closed by the fireproof filler 13. Details of the fireproof filler 13 will be described later.

Seal members 11 are provided from both opening sides of the opening 5 so as to fill the cable 7 and the fireproof filler 13 installed in the opening 5. That is, the fireproof filler 13 is covered with the seal member 11. The seal member 11 is a flame-resistant or non-flammable curable putty-like seal member. The seal member 11 has an indefinite shape at the time of construction, but covers the fireproof filler 13 and is installed so as to fill the gap between the cable 7 and the opening 5 and then hardens by drying and reaction, like cement. It becomes hard.

As the seal member 11, for example, Portland cement using a Ca-based binder can be used. More preferably, an inorganic filler as a filler is kneaded with an alkali silicate aqueous solution (for example, water glass) as a binder and dried. A cured product can be used. In this case, a hydrated metal compound such as aluminum hydroxide or magnesium hydroxide can be blended as the filler to impart flame retardancy and heat absorption.

In addition, clay, talc, zeolite, carbonates such as calcium carbonate and magnesium carbonate, kaolinite or calcined kaolin obtained by heat treatment thereof, aluminum hydroxide, metal oxides such as aluminum oxide and titanium oxide, pulverized coal combustion boiler ash, Addition of fillers such as pressurized fluidized bed ash, activated clay, bentonite, calcium silicate and crystalline calcium silicate hydrate (zonorite or tobermorite), silica sand, diatomaceous earth or zeiolite to improve processability and shape retention It can also be adjusted.

The clay is a clay mainly composed of silica, magnesium, iron, potassium and sodium, which can be taken from the clay layer. Further, talc is an inorganic powder obtained by finely pulverizing ore called talc. Chemical name is hydrous magnesium silicate _{(3MgO · 4SiO 2 · H 2} O), is a substance that is widely used in paints as raw materials or inorganic fillers for industrial use. Zeolite is a general term for aluminosilicate having pores in crystals mainly composed of alumina and silica, and is used as an inorganic filler.

In addition to the above-described components, the sealing member 11 may be further provided with an appropriate amount of expanded graphite, pearlite, vermiculite, borax, etc. to impart thermal expansion properties, such as anti-aging agents, fiber chips, pigments. Alternatively, an appropriate amount of foamed styrene beads, polypropylene beads, polyurethane beads, etc. for weight reduction may be blended. When the thermal expansibility is imparted to the seal member 11, when the temperature rises due to a fire, the seal member 11 expands and the gap with the cable 7 can be filled.

Further, as the seal member 11, a geopolymer weight obtained by reaction hardening using an active filler typified by kaolinite (Kaolinite) Al ₂ Si ₂ O ₅ (OH) ₄ using an aqueous alkali silicate monomer as a monomer source. Coalescence etc. can also be used. The geopolymer is a cured product obtained by inorganic polymerization by adding a powder called a filler to an alkali silicate aqueous solution (mainly water glass or the like). The general reaction mechanism is that a metal ion eluted from a filler comes into contact with water containing an aqueous alkali silicate solution, thereby cross-linking and polymerizing the silicate complex. A filler from which such metal ions are easily eluted is called an active filler.

In this case, the active filler is not limited as long as the geopolymer reaction is advanced, and kaolin-based fillers (such as dehydrated kaolin, ie, metakaolin) that gradually elute aluminum ions, fine powders that elute aluminum hydroxide and calcium ions, and the like. Charcoal-fired boiler ash or pressurized fluidized bed ash can be used. Since these are usually powders, they can be kneaded and used in the same manner as other inorganic fillers to adjust processability and shape retention. By utilizing the geopolymer reaction, curing can be promoted by heat curing, so that it can be easily manufactured as a molded product in a factory, and in some cases curing curing can be promoted even at a construction site, so that workability is excellent. Furthermore, since the polymerized one has excellent water resistance of the cured seal member, compared to the case where an inert filler of talc, which is not so, is added as an inorganic filler and dried and cured, especially for ships used at sea. Is preferred.

Of these active fillers, in particular, when the inventors choose an aluminum hydroxide hydrate, it is possible to obtain a polymerization reaction by elution of aluminum ions, and it is difficult as a hydrated metal compound. It was able to impart flammability and endotherm, and was suitable in terms of production, cost, workability of the kneaded material, and curing time.

Next, details of the fireproof filler 13 will be described. FIG. 4 is a view showing the fireproof filler 13, FIG. 4 (a) is a perspective view, and FIG. 4 (b) is a cross-sectional view taken along the line BB of FIG. 4 (a).

The fireproof filler 13 is provided with a ceramic fiber blanket 17, which is an inorganic fiber of a noncombustible material, and the outer periphery is covered with a covering material 15. The ceramic fiber blanket 17 has at least one of a length L, a width W, and a height (thickness) H whose cross-sectional shape is a rectangle, a square, a trapezoid, a circle, an ellipse, or an n-gon (N = 3 to 6). Or two or more. The ceramic fiber blanket 17 is mainly composed of SiO ₂ and Al ₂ O ₃ , has many air layers therein, and can be easily deformed.

In addition to the ceramic fiber blanket 17, the fireproof filler 13 may further be provided with a soft thermal expansion fireproof sheet. For example, a base resin of butyl rubber may be mixed with an amount of thermal expansion material such as graphite to form a putty, which may be formed into a sheet and laminated on a ceramic blanket. Furthermore, in order to improve fireproof performance, the ceramic fiber blanket 17 may contain 5 to 15 wt% of Fe ₂ O ₃ . When the fireproof filler 13 is a ceramic fiber, the packing density of the fireproof filler 13 to be filled in the opening is required to be at least 60 kg / m ³ , and if it is less than this, fire resistance is insufficient. . More preferably, it is 90 kg / m ³ or more.

The covering material 15 can be made of non-woven fabric made of polyester, polypropylene, or other resin. After covering the ceramic fiber blanket 17 with the covering material 15, the end portions may be bonded together with an adhesive or stitching. In addition to the resin nonwoven fabric, natural fiber woven fabric such as hemp or synthetic fiber woven fabric can be used.

Various sizes can be used as the size of the fireproof filler 13, for example, 60 mmW × 25 mmH × 50 mm to 300 mmL can be used. Here, W is made constant because it is cut out from a predetermined long ceramic fiber blanket. When changing the thickness, a plurality of sheets may be overlaid. Note that the width W of the fireproof filler 13 corresponds to the thickness direction of the firewall 3 (the horizontal direction in FIG. 3 and the insertion direction of the cable 7) when installed in the opening 5. The required filling thickness of the fireproof filler 13 (hereinafter, the filling length of the fireproof filler in the thickness direction of the firewall 3 is referred to as the filling thickness) is substantially constant regardless of the size of the opening 5. If at least the width W is constant, the installation position of the fireproof filler 13 with respect to the opening 5 can be easily grasped, and can be installed at the approximate center of the opening 5.

On the other hand, the length L (and thickness H) of the fireproof filler 13 may be properly used according to the size of the gap between the inner surface of the opening 5 and the cable 7 and the insertion position of the cable 7. That is, by using a plurality of types (sizes) of fireproof fillers 13 having different lengths L (and thickness H), a fireproof structure can be efficiently constructed. Here, since the fireproof filler 13 is composed of inorganic fibers such as an inorganic ceramic fiber blanket, it has a weight of about 1/10 compared to a conventionally used curable sealant. Since the material is easily deformed and is in close contact with the outer surface of the cable and the inner surface of the opening, it is possible to prevent the spread of fire. In addition, since the seal member 11 is provided outside the fireproof filler 13, there is no dropout due to vibration or shaking, and when a large ship is formed, the structure of such a fireproof section is configured to prevent fire. Construction is easy at the same time that performance and weight reduction are achieved.

Next, the construction method of the fire prevention structure 1 will be described. First, as shown in FIG. 5, the opening 5 is joined to the through hole provided in the fire wall 3. The opening 5 is a cylindrical member that penetrates the fire wall 3. A plurality of cables 7 are inserted into the opening 5.

Next, as shown in FIG. 6, the gap between the cable 7 and the opening 5 is filled with a fireproof filler 13 to close the gap between the opening 5 and the cable 7. At this time, since the fireproof filler 13 is easily deformed, the fireproof filler 13 is compressed in the thickness direction or deformed along the shape of the cable 7 to close the opening 5. Further, as described above, the fire filler 13 is installed in the vicinity of the central portion of the opening 5 in the thickness direction so that the width W of the fire filler 13 is in the thickness direction of the fire wall 3. Therefore, the fireproof filler 13 is installed at a predetermined filling thickness in the thickness direction of the opening 5.

FIG. 6B is a diagram showing a state in which the fireproof filler 13 is provided and the gap on the inner surface of the opening 5 is closed. Here, a state in which the gap inside the opening 5 is closed by the fireproof filler 13 is referred to as a temporary fireproof structure. The provisional fire prevention structure 20 is intended to prevent fire during construction when the cable 7 is inserted (ship construction work).

That is, the construction of the ship may take a period of several years. At this time, it is necessary to fire-proof each section, but when a fire-proof structure is completely constructed only by the seal member 11 as in the past, As described above, when the cable is added, removed, or replaced, the seal member 11 needs to be destroyed, so that workability is poor and the cable may be damaged. For this reason, the temporary fire prevention structure performs fire prevention of the fire wall 3 in the temporary state of the cable 7. Therefore, the filling thickness of the fireproof filler (the width W of the fireproof filler 13) is a thickness for obtaining a minimum fireproof performance at the time of ship construction.

FIG. 7 is a front view of the temporary fire prevention structure 20. As described above, the fireproof filler 13 is filled by combining a plurality of sizes (length and thickness). Note that a fireproof filler 13 is always provided on the inner peripheral surface of the opening 5 so that the inner surface of the opening 5 and the cable 7 do not come into contact with each other.

8 and 9 are diagrams showing a process of adding a cable to the provisional fire prevention structure 20. First, as shown to Fig.8 (a), in order to ensure the space which adds a cable, a part or all of the fireproof filler 13 is removed. Next, as shown in FIG. 8B, a cable 7a is added to the formed space.

Next, as shown in FIG. 9A, the fireproof filler 13 is refilled so as to close the gap inside the opening 5 again. At this time, the used fireproof filler 13 can be reused. As described above, the temporary fire prevention structure 20a is constructed as shown in FIG. 9B and FIG. Note that the same process can be performed when an existing cable is removed or replaced.

When the provisional fire prevention structure has been constructed, the insertion of all the cables is completed, and when the construction of the ship is completed, the seal member covers the fire prevention structure 13 from the openings on both sides of the opening 5. 11 is provided. That is, the fireproof filler 13 is left inside the opening 5 and covered with the seal member 11. As described above, the fire prevention structure 1 is constructed. By the seal member 11, the fireproof filler 13 does not fall off against the shaking of the ship, and the fireproof function can be surely exhibited.

As described above, according to the fire prevention structure 1 according to the present invention, since the fire prevention filler 13 is used, the provisional fire prevention structure 20 that is a fire prevention structure before completion can be easily constructed, and a cable can be added / Removal and replacement can be performed easily. Moreover, since the fireproof filler 13 is lighter than the seal member 11, for example, it is excellent in handling. Actually, when the working time is compared between the case where the fireproof filler 13 is used and the case where the fireproof structure is constructed with only the seal members, the case where the fireproof filler is used is 1/2 to 1 / The construction was completed in 3 hours.

In addition, since the fireproof filler 13 is composed of the ceramic fiber blanket 7, it can be easily deformed, and the thickness does not deviate from part to part, and can be installed substantially uniformly inside the opening. . Moreover, since the outer periphery is covered with the covering member 15, the ceramic fiber is not scattered, and since the sliding between the fireproof fillers 13 is good, installation / removal is easy.

Further, by using a plurality of sizes of the fireproof filler 13 having a constant width, an appropriate size can be selected according to the size of the gap, and the thickness of the fireproof filler can be made uniform. it can. For this reason, the filling position of the fireproof filler in the opening 5 is measured by measuring the length from one end of the opening 5 to the end of the fireproof filler 13 at the time of filling the fireproof filler in the opening 5. Can be grasped. For example, when the seal member 11 is provided, it can be easily determined whether the fireproof filler 13 is shifted to one side. Therefore, for example, if the filling position of the fireproof filler is marked on the inner surface of the opening 5, by confirming that the end of the fireproof filler 13 and the mark are located, the fireproof filler It can be easily confirmed that the installation position is located substantially at the center of the opening 5.

In addition, by providing the seal member 11 from both sides of the fireproof filler 13 and making the fireproof structure 1 have a double structure (three-layer structure), the fireproof filler 13 may drop off even when the ship shakes. There is no. As described above, by constructing the temporary fire prevention structure using the fireproof filler, the workability is excellent and the operation cost can be suppressed.

Next, a second embodiment will be described. FIG. 11A shows the temporary fire prevention structure 30, and FIG. 11B shows the fire prevention structure 40. In addition, in the following embodiment, the structure which show | plays the same function as the fire prevention structure 1 attaches | subjects the same code | symbol as FIG. 1, and the overlapping description is abbreviate | omitted. The temporary fire prevention structure 30 has substantially the same configuration as that of the temporary fire prevention structure 20, but is different in that the partition portion is not a fire barrier but a floor portion (fire prevention floor 31).

The fire floor 31 is formed of a steel plate. A heat insulating material 9 is provided on at least one side surface of the fire floor 31. An opening 5 is formed in the through hole provided in the fire floor 31. A cable 7 is passed through the opening 5 in a substantially vertical direction.

A support fitting 33 is provided inside the opening 5. The support fitting 33 is formed of a metal wire, for example, and is for supporting the fireproof filler 13 without interfering with the cable 7. That is, the support fitting 33 is formed with a hole through which a plurality of cables can be inserted in the lower part (however, a hole having a size that prevents the fireproof filler from dropping off) and a hook that can be fixed to the opening 5 at the upper part.

Inside the opening 5, a fireproof filler 13 is provided from above. The width W of the fireproof filler 13 corresponds to the vertical direction (cable insertion direction) in FIG. The fireproof filler 13 is supported by a support fitting 33. Since the lower part of the support fitting 33 substantially coincides with the lower end of the opening 5, the fireproof filler 13 is provided from the lower end of the opening 5 with a predetermined filling thickness.

When the cable is further added to, removed from, or replaced with the temporary fire prevention structure 30, the same procedure as that of the temporary fire prevention structure 20 can be performed. That is, after the fireproof filler 13 is temporarily removed and a cable is added, the fireproof filler 13 may be filled again.

When all construction work is completed, the sealing member 11 is provided from the upper side of the opening 5 to cover the fireproof filler 13. Thus, the fire prevention structure 40 is constructed. Since the lower part of the fire prevention structure 13 is supported by the support fitting 33, there is no fear of dropping off. Moreover, since the upper part is closed by the sealing member 11 and has a two-layer structure, the fireproof filler 13 is not removed from the upper part.

According to the second embodiment, an effect similar to that of the first embodiment can be obtained. Moreover, since the fire prevention structure 40 can perform work only from above the fire prevention floor 31, it is excellent in workability.

The embodiment of the present invention has been described above with reference to the accompanying drawings, but the technical scope of the present invention is not affected by the above-described embodiment. It is obvious for those skilled in the art that various modifications or modifications can be conceived within the scope of the technical idea described in the claims, and these are naturally within the technical scope of the present invention. It is understood that it belongs.

1, 40... Fire prevention structure 3... Fire barrier 5... Opening 7 and 7 a ....... Cable 9. ... Coating material 17 ... Ceramic fiber blanket 20, 20a, 30 ... Temporary fireproof structure 31 ... Fireproof floor 33 ... Support metal fittings

Claims (7)

1. A ship fire prevention structure,
   The cable is connected to the opening formed in the compartment,
   A plurality of fireproof fillers are filled in the gap between the inner surface of the opening and the cable,
   At least one of the fireproof filler is covered with a curable seal member,
   A fireproof structure for a ship, wherein the fireproof filler is composed of a resin nonwoven fabric, a natural fiber woven fabric, or an inorganic fiber covered with a synthetic fiber woven fabric.
2. The sealing member is at least one selected from the group consisting of hydrated metal compounds, clay, talc, aluminum hydroxide and calcium carbonate, and further, as a thermal expansion material, from thermal expansion graphite, pearlite, vermiculite and borax. And at least one selected from the group consisting of
   The fireproof structure for a ship according to claim 1, wherein a ceramic fiber blanket is used as the inorganic fiber.
3. The partition is a floor;
   A support fitting is provided from above the floor,
   The fireproof filler is supported by the support bracket,
   The ship fire prevention structure according to claim 1 or 2, wherein the seal member is provided so as to cover the fire prevention filler from above the fire prevention filler.
4. The partition is a wall;
   The said fire prevention filler is provided in the approximate center of the said opening part, and the said sealing member is provided so that the said fire prevention filler may be covered from the both sides of the said fire prevention filler. The fire prevention structure of the described ship.
5. A construction method for a ship fire prevention structure,
   Passing the cable through the opening formed in the partition,
   Filling the gap between the inner surface of the opening and the cable with a plurality of fireproof fillers;
   Providing a curable sealing member on the opening side of the opening so as to cover the fireproof filler;
   Comprising
   The fireproof filler is composed of an inorganic fiber covered with a resin nonwoven fabric, a natural fiber woven fabric, or a synthetic fiber woven fabric.
6. The construction method for a fireproof structure according to claim 5, wherein the fireproof fillers of a plurality of sizes having different thicknesses, lengths or shapes are used.
7. A method for adding / removing / replacing a cable to / from a temporary fire prevention structure of a ship,
   A plurality of fire-proof fillers composed of inorganic fibers covered with a resin nonwoven fabric, natural fiber woven fabric, or synthetic fiber woven fabric are passed through the opening formed in the partition portion, and the openings For the temporary fire prevention structure filled in the gap between the inner surface of the part and the cable,
   Removing part or all of the fireproof filler;
   Adding a cable to the opening, or removing the cable from the opening, or replacing the cable;
   Refilling a plurality of fireproof fillers into the gap between the inner surface of the opening and the cable;
   Providing a curable sealing member on the opening side of the opening so as to cover the fireproof filler;
   How to add / remove / replace cables to / from temporary fire protection structures.
   

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