JP5656665B2 - Tunnel fire-extinguishing piping structure, tunnel fire-extinguishing pipe branching structure, tunnel fire-extinguishing pipe heat insulation structure, and prevention method for strength reduction of tunnel fire-extinguishing pipe - Google Patents

Description

  The present invention relates to a tunnel fire extinguishing pipe used for extinguishing a fire in a tunnel, a branch structure of the tunnel fire extinguishing pipe, and the like.

  Conventionally, a fire hydrant for initial fire fighting is installed inside the tunnel against a fire inside the tunnel. The fire extinguishing equipment in such a tunnel is constructed by connecting fire hydrant devices installed at predetermined intervals in the longitudinal direction of the tunnel by water pipes, so that a person who discovers a fire immediately sprinkles water into the fire site from a nearby fire hydrant. Thus, initial digestion is performed (for example, Patent Document 1 and Patent Document 2).

  A metal pipe such as a ductile cast iron pipe has been used as a tunnel water supply pipe used for such fire extinguishing. Such a metal tube has sufficient heat resistance against heat in a fire.

JP 2001-571 A JP 2008-55024 A

  Such a water supply pipe is installed in the tunnel longitudinal direction while connecting a metal pipe having a predetermined length. However, the metal pipe is heavy, and the operation of installing the water supply pipe over the entire length of the long tunnel requires many man-hours for the connection, and costs and a work period.

  On the other hand, a method of making the water supply pipe light and long and compatible with resin can be considered. By using a water pipe made of resin, a long pipe can be obtained as described above, so it is possible to greatly reduce the number of connection points in the longitudinal direction. Can be reduced. Moreover, since it is lightweight, it is excellent in handling property, and even when a force is applied to the water supply pipe due to ground change after installation, this can be absorbed by the deformability of the pipe itself. For this reason, a large force is not applied to the joint portion, and there is no fear of water leakage or corrosion at the joint portion, which becomes a problem when a metal pipe is used.

  However, since the water pipe made of resin does not have the heat resistance as that of the steel pipe, there is a risk that the water feed pipe may be broken by internal pressure due to a decrease in strength of the water feed pipe itself in a fire. In particular, in a closed space called a tunnel, the temperature inside the tunnel is high, so there is a risk that any position of the resin water pipe installed in the tunnel will be exposed to high temperatures. Since it is buried in the inside, it does not reach a high temperature, but the pipe connection part is exposed to a high temperature, so it is difficult to use both the water supply pipe and the pipe connection part as a resin pipe.

  The present invention has been made in view of such problems, and is a lightweight, excellent installation workability in a tunnel, and a tunnel fire extinguishing pipe structure that can be used by being connected to a water supply pipe for extinguishing a tunnel fire. The purpose is to provide.

  In order to achieve the above-mentioned object, a first invention is a tunnel fire-extinguishing pipe structure laid in a tunnel, and is arranged at a predetermined interval in a tunnel longitudinal direction, and a concrete handhole provided with a lid portion on the upper side. A heat insulating member provided on the back surface of the lid, a resin water supply pipe embedded in the earth and sand between the hand holes and connected to the hand hole, and formed inside the hand hole, the water supply pipe A branch part that is connected to branch to a fire hydrant provided above the hand hole, and the branch part is made of a resin-made branch pipe, and a reinforcing layer provided on an outer periphery of the branch pipe, A tunnel fire-extinguishing pipe structure comprising a heat insulating layer provided on an outer periphery of the reinforcing layer.

  A waterproof layer may be further formed on the outer periphery of the heat insulating layer.

  The branch pipe is a T-shaped pipe, and both ends of the branch pipe are connected to the water supply pipe inside the hand hole, and the branch end of the branch pipe is connected to a fire hydrant. Is connected to the inside of the hand hole, the pipe body is led out above the hand hole along the inner wall surface of the tunnel, and a heat insulating member is provided at a boundary between the inside of the tunnel from which the pipe body is led out and the inside of the hand hole. It may be provided. A heat insulating material may be provided on the outer periphery of the tubular body outside the hand hole.

  The reinforcing layer is formed of a tape made of super engineering plastic fiber such as polyarylate fiber having strength and heat resistance, and this polyarylate fiber compensates for a decrease in strength due to a temperature rise of the branch pipe body to ensure pressure resistance. However, the fibers used as the reinforcing layer include polyarylate fibers and aramid fibers. The heat insulation layer is for preventing the temperature rise of the polyarylate fiber and the branch pipe body, and any of ceramic fiber, rock wool, glass wool, cross-linked foamed polyethylene, foamed urethane, and calcium silicate can be used. Particularly considering the heat insulation and workability, crosslinked foamed polyethylene and urethane foam are desirable. In order to enhance the heat insulation, it is desirable that the foaming ratio is high, and in order to make the heat insulation layer waterproof, the bubbles inside the resin are preferably not closed cells but closed cells. In addition, when using fibers such as ceramic fiber, rock wool, glass wool, etc., since it is used in the form of a fibrous mat, it is necessary to provide a waterproof tape. In the case of using a waterproof tape, it is desirable to use a waterproof tape. However, since the waterproof property can be secured if the above-mentioned resin having closed cells is also used, it is not always necessary to use it.

  According to 1st invention, the branch part branched to the fire hydrant provided at predetermined intervals in the tunnel is installed in the concrete hand hole, and the branch part inside the hand hole is made of a resin branch pipe body. Since it is composed of a reinforcing layer and a heat insulating layer provided on the outer periphery of the branch pipe, heat from the fire inside the tunnel is not easily transmitted to the branch pipe, and the branch pipe is improved by the reinforcing layer on the outer periphery of the branch pipe. Is prevented from bursting.

  Even in this case, since the water supply pipe connecting the handholes is buried, it is blocked from the space in the tunnel, and the buried earth and sand plays a role of a heat insulating layer.

  Moreover, if a waterproof layer is further provided on the outer periphery of the heat insulating layer, it is possible to suppress a decrease in heat insulating performance due to water permeating into the heat insulating layer. The waterproof layer is particularly effective when the heat insulating layer is composed of a fiber-based heat insulating material.

  In addition, the branch pipe is T-shaped (three-way branch), and both sides are connected to the water supply pipe inside the concrete hand hole, so that it is possible to check leakage from the joint inside the hand hole. it can. Moreover, the pipe connected to the fire hydrant is connected to the branch end (the T-shaped branch not connected to the water supply pipe) inside the hand hole. By connecting the pipe body and the inside of the hand hole, the resin-made branch pipe body is not exposed to the outside of the hand hole.

  Further, if a heat insulating member is provided at the boundary between the inside of the tunnel from which the tube is led out and the inside of the hand hole, the heat insulating member does not allow heat to enter from the gap between the inside of the hand hole and the tunnel wall surface.

  In addition, if a heat insulating member is further provided on the back side of the lid, heat transfer from the tunnel side to the inside of the hand hole is suppressed, so that the temperature rise inside the hand hole is suppressed and the branch part is ruptured by heat. Can be prevented.

  A second aspect of the present invention is a branch structure of a tunnel fire extinguishing pipe laid in a tunnel, wherein the resin-made T-shaped branch pipe, a reinforcing layer provided on the outer periphery of the branch pipe, and the reinforcing layer A heat insulating layer provided on an outer periphery, and the branch structure is installed inside a concrete hand hole in a tunnel, and both ends of the branch pipe are connected to a water supply pipe inside the hand hole, A branch structure of a tunnel fire extinguishing pipe is characterized in that a branch end portion of the branch pipe body is connected to a pipe body connected to a fire hydrant inside the hand hole.

  According to the second invention, a branch structure having a resin branch pipe body, a reinforcing layer, and a heat insulation layer is provided inside the hand hole, and connected to the water supply pipe inside the concrete hand hole. Because it is connected inside the hand hole, the resin part will not be exposed above the hand hole (in the tunnel), and leakage from the connection with the water supply pipe will be confirmed inside the hand hole. Therefore, it is possible to obtain a fire extinguishing piping branch structure that is excellent in workability and simple in structure.

  The third invention is a branch structure of a tunnel fire extinguishing pipe laid in a tunnel, comprising at least a resin-made T-shaped branch pipe and a reinforcing layer provided on the outer periphery of the branch pipe, The branch structure is installed inside a concrete hand hole in a tunnel, both ends of the branch pipe are connected to a water supply pipe inside the hand hole, and a branch end of the branch pipe is connected to a fire hydrant. A tunnel fire extinguishing pipe branching structure, wherein a heat insulating material is provided at least on the outer periphery of the pipe body outside the handhole. Here, the heat insulating material used on the outer periphery of the tube provided outside the hand hole can be performed by various methods such as wrapping the heat insulating material, bonding, or forming the tube into a tubular shape and covering the tube. Further, the outer periphery may be fixed with a metal belt or the like.

  According to the third invention, a branch structure having a resin branch pipe body and a reinforcing layer is provided inside the hand hole, and is connected to the water supply pipe inside the concrete hand hole. Since it is connected inside the hole, the resin part is not exposed above the hand hole (inside the tunnel), and there is a heat insulating material on the outer periphery of the tube connected to the digestive plug exposed in the tunnel. Since it is provided, it is possible to prevent heat from being transferred to the pipe body in the event of a fire.

  4th invention is the heat insulation structure of the fire extinguishing piping laid in the tunnel, Comprising: The concrete handhole which has a cover part is installed in the tunnel longitudinal direction at predetermined intervals, and between the said handholes is earth and sand A tunnel in which a pipe connected to a fire hydrant provided above the hand hole and a branch portion for branching the water supply pipe are formed inside the hand hole, and connected by a resin water supply pipe embedded in With respect to the fire extinguishing pipe, a heat insulating member is provided on the back surface of the lid portion, the pipe body is led out above the hand hole along the inner wall surface of the tunnel, and the inside of the tunnel from which the pipe body is led out and the hand hole A heat insulating member is provided at the boundary with the inside of the pipe, and the branch portion is formed of a resin-made branch pipe, a heat-resistant reinforcing layer provided on the outer periphery of the branch pipe, and an outer periphery of the reinforcing layer. A heat insulating structure of a tunnel fire extinguishing pipe, characterized by comprising a heat-insulating layer eclipsed.

  According to the fourth invention, since the heat insulating member is provided on the back surface of the lid portion, the inside of the hand hole is insulated from the inside of the tunnel, and the temperature rise inside the hand hole can be suppressed. Furthermore, by providing a heat insulating member at the boundary between the inside of the tunnel and the inside of the hand hole, the inside of the hand hole can be insulated more reliably. In addition, a heat-resistant reinforcing layer is provided on the outer peripheral portion of the branch pipe body at the branch portion, and a heat insulating layer for insulating the branch pipe body and the reinforcing layer is provided on the outer periphery of the reinforcing layer. Is done. Accordingly, the two-stage heat insulating structure can reliably prevent damage due to a decrease in pressure resistance due to heat of the branch pipe body.

  A fifth invention is a method for preventing strength reduction of a tunnel fire extinguishing pipe laid in a tunnel, which is made of a resin embedded with concrete hand holes having lid portions at predetermined intervals in the tunnel longitudinal direction. The hand holes are connected to each other by a water supply pipe, and a branch part for branching the pipe connected to a fire hydrant provided above the hand hole and the water supply pipe is formed inside the hand hole. A heat insulating member is provided on the back surface, the tubular body is led out above the hand hole along the inner wall surface of the tunnel, and a heat insulating member is provided at a boundary between the inside of the tunnel from which the tubular body is led out and the inside of the hand hole, A heat-resistant tape made of super engineering plastic fibers is provided as a reinforcing layer on the outer periphery of a resin branch pipe constituting the branching portion, and a heat insulating layer is provided on the outer periphery of the reinforcing layer. That is a strength reduction method for preventing the tunnel extinguishing piping.

  According to the fifth invention, the inside of the handhole can be reliably insulated from the inside of the tunnel by the heat insulating member provided on the back surface of the lid portion and the heat insulating member at the boundary between the inside of the tunnel and the inside of the handhole. In addition, by providing a heat-resistant tape made of super engineering plastic fibers as a reinforcing layer on the outer peripheral part of the branch pipe body of the branch part, by providing a heat insulating layer for heat insulation of the branch pipe body and the reinforcing layer on the outer periphery of the reinforcing layer, The branch portion can be reliably insulated from the inside of the hand hole. Therefore, the two-stage heat insulating structure can surely prevent the strength reduction due to the heat of the branch pipe body.

  ADVANTAGE OF THE INVENTION According to this invention, the tunnel fire extinguishing piping structure etc. which are excellent in the installation workability | operativity in a tunnel and can be used as a water supply piping for fire extinguishing of a tunnel fire, etc. can be provided.

The perspective view which shows the tunnel fire extinguishing piping structure 1. FIG. Sectional drawing which shows the tunnel fire extinguishing piping structure 1. FIG. It is an enlarged view which shows the branch part 9, (a) is an elevation view, (b) is a top view. FIG. 4 is a perspective view illustrating a configuration of a tubular body in a branching portion 9 which is a portion A of FIG. FIG. 4 is a cross-sectional view illustrating a configuration of a tubular body at a branching portion 9 which is a portion A of FIG. It is an enlarged view which shows the branch part 9, (a) is an elevation view, (b) is a top view.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view showing a tunnel fire extinguishing piping structure 1, and FIG. 2 is a longitudinal sectional view. The tunnel fire-extinguishing pipe structure 1 includes a fire hydrant 13, a water supply pipe 5 that connects the fire hydrants 13 to each other, and can supply water to each fire hydrant 13.

  The fire hydrants 13 are installed at predetermined intervals inside the tunnel. The fire hydrants 13 are connected to each other by a water supply pipe 5 provided over the entire length of the tunnel from the outside of the tunnel. The water supply pipe 5 is made of resin, for example, made of polyethylene. Fire extinguishing water flowing through the water supply pipe 5 is branched at the branch portion 9 (FIG. 2) in the vicinity of the fire hydrant 13 and supplied to each fire hydrant 13.

  Inside the tunnel, an observer passage or the like is provided on the outside of the roadway through which vehicles and the like pass. In this part, the water supply pipe 5 is buried in the lower part, and after the water supply pipe 5 is buried with earth and sand such as river sand, concrete is provided above. The water supply pipe 5 has a water supply unit (not shown) connected to the outside of the tunnel, so that a predetermined amount of water can be supplied.

  The fire hydrant 13 is installed, for example, every 50 m in a tunnel. The fire hydrant 13 is connected to the water supply pipe 5 at the branch portion 9. The branch portion 9 is installed inside the concrete hand hole 7, and the branch portion 9 and the water supply pipe 5 are connected by a joint 11. Details of the branching unit 9 will be described later.

  Normally, when a fire occurs in the tunnel 3, the fire is extinguished by a fire extinguishing vehicle such as a fire engine within 40 minutes. The fire hydrant 13 is used for initial fire extinguishing until arrival of a fire engine or the like. Therefore, tap water or dedicated fire-fighting water is used, and the water discharge amount for about 40 minutes is secured as the fire-fighting water. That is, the tunnel fire-extinguishing piping structure 1 only needs to be able to perform a fire extinguishing activity before the initial fire extinguishing. For this reason, the fire hydrant 13 should just be operable for 40 minutes from the occurrence of a fire.

  The tunnel fire-extinguishing piping structure 1 is constructed as follows, for example. First, a groove is formed of concrete, for example, as an installation part of the water supply pipe 5 on the side of the tunnel. A hand hole is formed for each predetermined distance of the installation part of the water supply pipe 5. The hand hole 7 is installed at the installation interval of the fire hydrant 13 to be installed, for example. For example, the hand hole 7 is installed every 50 m. The hand hole 7 is made of concrete. The handhole 7 is surrounded by side walls on three sides, and is installed so that the opening side surface abuts against the inner wall surface side of the tunnel.

  Next, the water supply pipe 5 is installed in the tunnel longitudinal direction. In this case, for example, if the water supply pipe 5 has an inner diameter of 100 mmφ, a long pipe of about 150 m can be used. Therefore, the water supply pipe 5 may be installed in the longitudinal direction of the tunnel and cut at the handhole installation part. By doing in this way, since it is not necessary to connect water supply piping, the installation construction of the water supply piping 5 is easy, and a construction cost can be reduced.

  A branch portion 9 is installed inside the hand hole 7. The branch portion 9 is connected to the water supply pipe 5 and the joint 11 described above. As the joint 11, for example, a heat fusion joint is used. In addition, you may connect the water supply piping 5 and the branch part 9 by a flange etc. After the water supply pipe 5 and the branch part 9 are connected, the water supply pipe 5 is buried with river sand or the like. A reinforcing layer or the like to be described later is formed at the branch portion 9 inside the hand hole 7, and a tubular body such as a steel pipe is further connected thereto. A fire hydrant 13 is installed above the hand hole 7 and connected to the steel pipe. A lid made of concrete or the like is provided above the buried portion of the water supply pipe 5, and a lid made of iron or the like is provided above the handhole 7. As described above, the tunnel fire-extinguishing piping structure 1 is constructed.

Next, the branching unit 9 will be described. Here, in the vicinity of the actual fire site, there may be an extremely high temperature atmosphere of 800 to 1200 ° C. However, the ambient temperature outside the handhole is actually a work to perform fire extinguishing activities during a fire. Consider the temperature at which an employee can approach. This is because when the temperature near the handhole is exposed to a very high temperature, an operator (usually a general passerby) for performing an initial fire fighting activity cannot approach the fire hydrant in the first place. In addition, heat is applied so that the temperature of the branch portion inside the hand hole is suppressed to 80 ° C. or less until 40 minutes after the occurrence of the fire. This is because the tunnel fire extinguishing pipe and the branch part have long-term (1000 hours) pressure resistance characteristics at 80 ° C. In the first place, the tunnel fire extinguishing equipment is a fire extinguishing equipment using water, and if the temperature exceeds 100 ° C, the water in the pipe becomes steam and cannot be extinguished.
For example, the interior space of the hand hole is insulated by the heat insulating material of the lid, and the reinforcement layer and the branch pipe are protected by the heat insulation layer, so even in the event of a fire, the pressure resistance of the branch pipe is compensated. It becomes possible.

  FIG. 3A is an enlarged elevation view of the branch portion 9, and FIG. 3B is a plan view of the branch portion 9. In addition, in FIG.3 (b), it is a perspective view of the cover part 17. As shown in FIG. The branch portion 9 is T-shaped, and both ends thereof are connected inside the hand hole 7 with the water supply pipe 5 penetrating the side wall portion (side surface) of the hand hole 7. Therefore, the vicinity of both side ends of the branch portion 9 and the joint 11 are located inside the hand hole 7.

  On the other hand, as shown in FIG. 3 (b), the branch end portion of the branch portion 9 (T-shaped branch portion and disposed toward the tunnel wall surface) is formed between the steel pipe 15 and, for example, the flanges of each other. Connected. The steel pipe 15 connected to the branch portion 9 inside the hand hole 7 is arranged in the direction of the tunnel wall surface in the hand hole 7 and is bent upward along the tunnel wall surface 22 to the outside of the hand hole 7 (inside the tunnel). Derived. Note that the tunnel wall surface (inner wall surface) is slightly recessed at the hand hole 7 installation portion, and a space through which the steel pipe 15 can be led out is formed between the tunnel surface and the hand hole 7. The steel pipe 15 is connected to a fire hydrant (not shown) above the hand hole 7. In addition, since the steel pipe 15 is exposed above the handhole 7, heat may be transmitted through the steel pipe 15 in the event of a fire. For this reason, a heat-resistant packing or the like is applied to the connection portion between the steel pipe 15 and the branch portion 9.

  A gap is formed between the tunnel wall surface 22 and the hand hole 7 (lid portion 17). Necessary for the steel pipe 15 and the gap (that is, the gap between the steel pipe 15 and the tunnel wall surface 22 and the hand hole lid portion 17 and the boundary between the tunnel inner side and the hand hole inner side at the steel pipe 15 leading position). Insulation material 21 is provided accordingly. The heat insulating material 21 suppresses heat from the tunnel from being transferred to the inside of the handhole 7 through the boundary portion between the inside of the tunnel and the inside of the handhole. As the heat insulating material 21, fiber heat insulating materials such as ceramic fiber, rock wool, and glass wool, foam heat insulating materials such as cross-linked foamed polyethylene and urethane foam, and inorganic heat insulating materials such as calcium silicate can be used. Moreover, as the heat insulating material 21, a heat-expandable refractory material can be used. A heat-expandable refractory material is one that expands 12 to 20 times in volume when heated by heat at the time of a fire, and retains fire resistance in an expanded state, such as butyl rubber A known composition comprising a base resin, a thermally expandable material such as thermally expandable graphite, and a resin that generates a residue such as carbide by heating such as polycarbonate can be used. Commercially available products include Dunseal D (trade name) manufactured by Furukawa Techno Materials. In addition, Fomox (registered trademark) manufactured by Bayer in Germany and Fire Barrier (trade name) manufactured by 3M in the United States can be used.

  A heat insulating material 19 is provided on the lower surface of the lid portion 17 as necessary. Although the heat insulating material 19 can also select the same material as the heat insulating material 21, installation is easier if a plate-shaped heat insulating material is used.

  Next, the cross-sectional configuration of the branch portion 9 will be described. 4 is an enlarged view of a portion A in FIG. 3, and is a perspective view showing a sectional configuration of the portion A of the branching portion 9, and FIG. 5 is a sectional view showing the configuration of the branching portion 9 in the same manner. The branch part 9 includes a pipe body 25 that is a branch pipe body, a reinforcing layer 27, a heat insulating layer 29, a waterproof layer 31, and the like.

  The tube body 25 is a T-shaped resin tube material, and is made of, for example, polyethylene. A reinforcing layer 27 is formed on the outer periphery of the tube body 25. The reinforcing layer 27 is for improving (reinforcing) the internal pressure resistance of the tubular body 25. For example, a tape of polyarylate fiber is wound around the reinforcing layer 27. As the reinforcing layer 27, for example, Vectran (registered trademark) manufactured by Kuraray Co., Ltd., which is a super fiber tape, can be used. Vectran (registered trademark) is flame retardant, has excellent creep resistance, has a high thermal decomposition temperature of 450 ° C or higher, and has a pressure resistance of fire extinguishing pipes even when the temperature of the branch section is 80 ° C in the event of a fire. Sufficient strength (eg, about 1200 MPa). In addition, water does not normally enter the inside of the hand hole, but even if water enters from the gap of the lid of the hand hole, it is particularly problematic because it is protected by waterproof tape. In addition, Vectran (registered trademark) itself can be suitably used as a reinforcing tape because it has an excellent strength retention rate against a moist heat environment. The polyarylate fiber tape may be wound, for example, by wrapping ends in the tape width direction, or may be wound with a slight gap. Further, the reinforcing layer 27 may be formed by wrapping a polyarylate fiber tape a plurality of times, such as by wrapping the tape in the forward and reverse directions. The winding method of the polyarylate fiber tape is appropriately determined according to the strength of the polyarylate fiber tape and the required internal pressure resistance.

  When the reinforcing layer 27 (reinforcing tape) is wound around the T-shaped tube body 25, the vicinity of the branch portion (near the central portion) of the T-shaped tube is also a portion to which a force is applied, so that the reinforcing layer is surely provided. 27 must be formed.

  Near the branch part of the T-shaped tube, it covers both the pipe part in the tunnel axis direction (water supply piping laying direction) and the pipe part in the horizontal direction perpendicular to it (the tunnel wall direction in the hand hole). A reinforcing tape may be wound around the tape, or it may be wound like a pavement so as to cover both roots. Reinforcing tape may be wrapped around one tape so that each root is covered, or several tapes are wrapped separately (for example, a horizontal tube and a vertical tube separately) Also good. Further, it may be wound a plurality of times while slightly shifting the winding position. Here, if an adhesive is applied to one side of the tape used for the reinforcing layer 27, it is possible to prevent the tape from shifting due to the tension of the adhesive as well as the tension when the tape is wound.

  In addition, the reinforcement layer 27 (reinforcement tape) may be reinforced around the entire length at a long pitch to reinforce the vicinity of the branch site, and the tubular body is more reliably reinforced by wrapping a plurality of layers of reinforcement tape. be able to.

  As shown in FIGS. 4 and 5, a heat insulating layer 29 is formed on the outer periphery of the reinforcing layer 27. The heat insulation layer 29 can use the same member as the heat insulation material 19 described above. The heat insulating layer 29 is for suppressing the temperature rise of the tube body 25 when the temperature in the tunnel is transmitted into the hand hole 7.

  In addition, what is necessary is just to operate | move the tunnel fire-extinguishing piping structure in this invention without a problem for 40 minutes from a fire for a predetermined time as mentioned above, for example. The tube 25 has a long-term pressure resistance at 80 ° C. For this reason, it is necessary to insulate so that it may not exceed 80 degreeC for 40 minutes after a fire, and to reinforce so that the tubular body 25 may not burst. The reinforcing layer 27 and the heat insulating layer 29 are appropriately designed based on such criteria. The heat insulating layer 29 only needs to be provided inside the hand hole 7, and the pipe body 25 only needs to be directly embedded in the sand at a portion protruding from the hand hole 7, so that the embedded sand provides a sufficient heat insulating effect. Is obtained. That is, the reinforcing layer 27 and the heat insulating layer 29 are similarly formed in the water supply pipe 5 and the connection part (joint 11) between the water supply pipe 5 and the branch part 9 located in the hand hole 7.

  A waterproof layer 31 is provided on the outer periphery of the heat insulating layer 29 as necessary. The waterproof layer 31 prevents external water from entering the heat insulating layer 29. As the waterproof layer 31, a heat-resistant polyimide, a tape made of fluororesin, a heat-shrinkable tube of crosslinked polyethylene, or the like can be used.

  In particular, when a fiber-based heat insulating material is used as the heat-insulating layer 29, water easily infiltrates into the heat-insulating layer, thereby significantly reducing the heat insulating performance. Therefore, when a fiber-based heat insulating material is used, the waterproof layer 31 is used. It is desirable to provide

  As described above, according to the tunnel fire-extinguishing pipe structure 1 of the present embodiment, the resin-made water supply pipe 5 and the branch part 9 (branch pipe body) are used. Since the number of joints can be reduced, it is advantageous in terms of cost. Moreover, since the water supply pipe 5 outside the handhole 7 is buried with sand, the sand serves as a heat insulating layer, and the water supply pipe 5 does not reach 80 ° C. or more by 40 minutes after the occurrence of the fire. 5 does not burst.

  On the other hand, since the inside of the hand hole 7 is a space, the heat of a fire is easily transmitted to the inside of the hand hole, but since the heat insulating layer is provided in the branch part 9 installed inside the hand hole, the inside of the hand hole 7 is inside the tunnel. Is insulated from. Further, since the branching portion 9 is provided with the heat-resistant reinforcing layer 27 and the heat insulating layer 29, the tube body 25 does not become 80 ° C. or higher in the initial fire extinguishing period from the occurrence of a fire. In addition, the reinforcing layer 27 on the outer periphery of the tube body 25 can ensure a sufficient internal pressure resistance against the strength decrease accompanying the temperature increase of the tube body 25.

  Further, by providing the waterproof layer 31 on the outer periphery of the heat insulating layer 29, the heat insulating properties of the heat insulating layer 29 are not deteriorated by water.

  Moreover, since the joint part 11 of the branch part 9 and the water supply pipe 5 is located inside the hand hole, water leakage from the joint part 11 can be confirmed by the hand hole 7, and the joint part 11 is similarly reinforced. In addition, since heat insulation is performed, it is possible to reliably prevent damage to the branch portion due to heat. Furthermore, by making the connection part with the steel pipe 15 inside the hand hole 7, a part of the branch part is not exposed above the hand hole 7, and the influence of heat received from inside the tunnel due to fire or the like is suppressed. Can do. In addition, you may form a heat insulation layer also with respect to the steel pipe 15 located in the hand hole 7. FIG. This is because the heat transmitted through the steel pipe from the outside of the hand hole is radiated into the hand hole 7 to suppress the temperature rise inside the hand hole.

  Further, by providing the heat insulating material 21 in the gap between the tunnel wall surface on which the steel pipe 15 is disposed and the lid portion 17, heat does not enter the hand hole through the gap, and the lid portion 17 By providing the heat insulating material 19 on the back surface, heat conduction from the tunnel to the inside of the handhole 7 can be suppressed. That is, in the present invention, the resin pipe body is reliably tunneled by the heat insulation by the heat insulating material 19 of the lid portion 17 and the heat insulation by the heat resistant reinforcing layer and the pipe body and the heat insulating layer 29 in the branching portion 9. Insulating from the inside, it is possible to prevent the strength of the resin tube from being lowered.

  As mentioned above, although embodiment of this invention was described referring an accompanying drawing, the technical scope of this invention is not influenced by embodiment mentioned above. 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. It is understood that it belongs.

  For example, as shown in FIG. 6, the heat insulating material 33 may be provided also in the tube body 15. FIG. 6A is an enlarged elevation view in the vicinity of the branch portion 9, and FIG. 6B is a plan view of the branch portion 9. In addition, in FIG.6 (b), it is a perspective view of the cover part 17. As shown in FIG. When a fire occurs in the tunnel, the tube body 15 becomes hot due to heat in the tunnel. As described above, since the pipe body 15 is usually a steel pipe, when the steel pipe 15 outside the hand hole 7 (inside the tunnel) is heated, heat is transferred to the inside of the hand hole 7 due to heat conduction of the steel pipe 15. Therefore, the temperature inside the handhole 7 is raised, and the branch pipe body is damaged at the connection portion with the branch portion 9.

  As the heat insulating material 33, for example, fiber heat insulating materials such as ceramic fiber, rock wool, and glass wool, foam heat insulating materials such as crosslinked foamed polyethylene and foamed urethane, and inorganic heat insulating materials such as calcium silicate can be used. Further, when a fiber-based heat insulating material is used as the heat insulating material 33, water is likely to permeate into the heat insulating layer, which may significantly reduce the heat insulating performance. For this reason, when a fiber type heat insulating material is used as the heat insulating material 33, it is desirable to further provide a waterproof layer on the outer periphery of the heat insulating material 33.

  Moreover, each heat insulating material can also be provided separately, respectively. For example, only the heat insulating material 33 described above may be provided, and the heat insulating materials 19 and 21 and the heat insulating layer 29 may not be formed. In this case, heat insulation from the temperature rise inside the hand hole cannot be performed, but at least the temperature rise of the tube body 15 outside the hand hole 7 can be suppressed. As a result, the temperature rise inside the hand hole 7 can be suppressed. Is possible. Thus, according to the heat resistance etc. which are requested | required, the heat insulating material and heat insulating layer which were mentioned above may each be used independently, and may be used in arbitrary combinations.

  Further, a branch portion other than the T-shaped branch portion may be provided inside the hand hole 7, or a straight pipe body (water supply pipe) is simply provided to reinforce the water supply pipe located inside the hand hole. A layer, a heat insulating layer, and the like may be provided. Moreover, you may add structures other than a reinforcement layer etc. to the branch part 9 suitably as needed.

1 ......... Tunnel fire extinguishing pipe structure 3 ......... Tunnel 5 ......... Water pipe 7 ......... Hand hole 9 ...... Branching part 11 ......... Fitting 13 ......... Fire hydrant 15 ......... Steel pipe 17 ......... Lid 19 ......... Insulating material 21 ......... Insulating material 22 ......... Tunnel wall 23 ......... Sand 25 ......... Tube body 27 ......... Reinforcing layer 29 ......... Insulating layer 31 ......... Waterproof layer 33 ……… Insulation

Claims (9)

Tunnel fire extinguishing piping structure laid in the tunnel,
A concrete hand hole that is arranged at predetermined intervals in the tunnel longitudinal direction, and has a lid provided above;
A heat insulating member provided on the back surface of the lid,
A water pipe made of resin that is buried in earth and sand between the hand holes and connected to the hand holes,
A branch part formed inside the hand hole, connected to the water supply pipe, and branched to a fire hydrant provided above the hand hole;
Have
The branch portion is
A tunnel fire-extinguishing pipe structure comprising: a resin branch pipe, a reinforcing layer provided on an outer periphery of the branch pipe, and a heat insulating layer provided on an outer periphery of the reinforcing layer.   The tunnel fire-fighting piping structure according to claim 1, wherein a waterproof layer is further formed on an outer peripheral portion of the heat insulating layer. The branch pipe is a T-shaped pipe, and both ends of the branch pipe are connected to the water supply pipe inside the hand hole,
A branch end of the branch pipe is connected to a pipe connected to a fire hydrant inside the hand hole, and the pipe is led out of the hand hole along a tunnel inner wall surface,
The tunnel fire-extinguishing piping structure according to claim 1 or 2, wherein a heat insulating member is provided at a boundary between the inside of the tunnel from which the pipe body is led out and the inside of the hand hole.   The tunnel fire-fighting piping structure according to claim 3, wherein a heat insulating material is provided on an outer periphery of the pipe body outside the hand hole. The reinforcing layer is formed of polyarylate fibers;
The tunnel heat-extinguishing pipe structure according to any one of claims 1 to 4, wherein the heat insulating layer is any one of ceramic fiber, rock wool, glass wool, cross-linked foamed polyethylene, foamed urethane, and calcium silicate. . A branch structure of a fire extinguishing pipe laid in the tunnel,
A resin-made T-shaped branch pipe, a reinforcing layer provided on the outer periphery of the branch pipe, and a heat insulating layer provided on the outer periphery of the reinforcing layer,
The branch structure is installed inside a concrete hand hole in a tunnel, and both ends of the branch pipe are connected to a water supply pipe inside the hand hole, and a branch end of the branch pipe is connected to a fire hydrant. A tunnel fire extinguishing pipe branching structure characterized in that the pipe is connected to the inside of the handhole. A branch structure of a fire extinguishing pipe laid in the tunnel,
A resin T-shaped branch pipe and at least a reinforcing layer provided on the outer periphery of the branch pipe;
The branch structure is installed inside a concrete hand hole in a tunnel, and both ends of the branch pipe are connected to a water supply pipe inside the hand hole, and a branch end of the branch pipe is connected to a fire hydrant. Connected to the inside of the hand hole
A branch structure of a tunnel fire-extinguishing pipe, wherein a heat insulating material is provided at least on the outer periphery of the pipe body outside the hand hole. It is a heat insulation structure of a tunnel fire extinguishing pipe laid in the tunnel,
Concrete hand holes having lids are installed at predetermined intervals in the longitudinal direction of the tunnel, and the hand holes are connected by resin water supply pipes embedded in earth and sand. For the tunnel fire extinguishing pipe formed with a branch part for branching the pipe connected to the fire hydrant provided above the hall and the water supply pipe,
A heat insulating member is provided on the back surface of the lid,
The pipe body is led out above the hand hole along the inner wall surface of the tunnel, and a heat insulating member is provided at a boundary between the inside of the tunnel from which the pipe body is led out and the inside of the hand hole,
The above-mentioned branch part comprises a resin-made branch pipe, a heat-resistant reinforcing layer provided on the outer periphery of the branch pipe, and a heat-insulating layer provided on the outer periphery of the reinforcing layer. Insulation structure of piping. A method for preventing strength reduction of a tunnel fire-extinguishing pipe laid in a tunnel,
A concrete hand hole having lids at predetermined intervals in the longitudinal direction of the tunnel is installed, and the hand holes are connected to each other by a water pipe made of resin embedded in earth and sand,
Forming a branching portion for branching a pipe connected to a fire hydrant provided above the handhole and the water supply pipe inside the handhole;
A heat insulating member is provided on the back surface of the lid,
The pipe body is led out above the hand hole along the inner wall surface of the tunnel, and a heat insulating member is provided at the boundary between the inside of the tunnel from which the pipe body is led out and the inside of the hand hole,
Strength of a tunnel fire-extinguishing pipe, characterized in that a heat-resistant tape made of super engineering plastic fibers is provided as a reinforcing layer on the outer periphery of a resin branch pipe body constituting the branch portion, and a heat insulating layer is provided on the outer periphery of the reinforcing layer Deterioration prevention method.

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