KR102623564B1 - Appratus for fireproofing inner wall of tunnel - Google Patents

Abstract

A tunnel comprising a structural frame formed in a shape corresponding to the inner shape of the tunnel and located on the inner wall of the tunnel to effectively protect the inner wall of the tunnel from fire, and a fireproof panel installed on the structural frame and covering the inner wall of the tunnel to protect it from flames. Provides an inner wall fireproof device.

Description

{APPRATUS FOR FIREPROOFING INNER WALL OF TUNNEL}

The present disclosure relates to a tunnel inner wall fireproofing device.

In general, a tunnel is a passage made through the ground, under the sea, or through a mountain to allow vehicles to pass through. As the number of roads increases due to economic development, tunnel construction is also increasing. Recently, the length of tunnels has been gradually increasing due to the straightening of roads due to reduction in logistics costs and the development of construction technology. As a result, damage caused by accidents and fires in tunnels is emerging as a major social problem.

Due to its structure, the tunnel is a semi-enclosed space with the inside blocked except for the entrance, making fire extinguishing and rescue efforts difficult in the event of a fire. In addition, as the concrete poured on the inner wall of the tunnel is damaged by flames, greater damage may occur, maximizing damage to property and people. If the inner wall of a tunnel is made of reinforced concrete, the inner wall may be damaged by flame and collapse immediately, and if the inner wall is made of plain concrete, it may easily collapse later due to reduced durability. Therefore, in the event of a fire, it is necessary to protect the inside of the tunnel from flames until the fire is extinguished.

Typically, in a tunnel, a fire extinguishing system may be provided that automatically sprays water to extinguish the fire when a fire occurs. However, the conventional fire extinguishing system in the tunnel is structured to extinguish the fire by simply spraying water into the area where the fire occurs, and does not effectively protect the inner wall of the tunnel from flames.

This project is to provide a tunnel inner wall fireproof device that can effectively protect the tunnel inner wall from fire.

This project is to provide a fireproof device for the inner wall of a tunnel that can protect structures from high heat caused by flames.

This project is to provide a tunnel inner wall fireproof device that can be more easily installed in existing tunnels.

The fireproof device of this embodiment may include a structural frame formed in a shape corresponding to the inner shape of the tunnel and located on the inner wall of the tunnel, and a fireproof panel installed on the structural frame and covering the inner wall of the tunnel to protect it from flame.

The fireproof device may further include a cooling unit installed along the structural frame and disposed behind the fireproof panel to cool the structural frame and the fireproof panel.

The cooling unit includes a water tank installed in the structural frame to store cooling water to be supplied to a truss-structured pipe to increase the rigidity of the structural frame, a supply line connecting the water tank and the pipe, and a water tank installed in the supply line. It may have a structure that cools the structural frame by supplying water through the inside of the pipes, which are hollow and connected to each other, including a pump that supplies cooling water to the pipes.

The cooling unit may further include a heat sensor for detecting a flame, and a control unit that calculates a detection signal from the heat sensor to control the operation of the pump.

It may further include rails installed on the bottom of both sides in the width direction of the tunnel and extending along the tunnel, and moving wheels installed at the bottom of both sides of the structural frame and rolling along the rails.

According to this embodiment, the inner wall of the tunnel is surrounded by a fireproof wall to block flames, thereby preventing the inner wall of the tunnel from being deteriorated or damaged by high temperature due to direct contact with the flame.

In addition, by supplying coolant to the inside of the frame forming the frame to cool the frame, it is possible to prevent the frame from being damaged even if it is exposed to flame and high heat for a long time.

The device can be easily installed in a tunnel by moving it along the rail. Accordingly, it can be more easily assembled and constructed not only in newly created tunnels but also in existing tunnels.

1 is a schematic diagram showing a tunnel inner wall fireproofing device installed inside a tunnel according to this embodiment.
Figure 2 is a schematic cross-sectional view showing the configuration of the tunnel inner wall fireproofing device according to this embodiment in the AA direction of Figure 1.
FIG. 3 is a diagram illustrating part B of FIG. 1 in detail.
FIG. 4 is a diagram illustrating part C of FIG. 1 in detail.

Hereinafter, embodiments of the present invention will be described in detail. However, this is presented as an example, and the present invention is not limited thereby, and the present invention is only defined by the scope of the claims to be described later. The embodiments described below may be modified into various forms without departing from the concept and scope of the present invention. As much as possible, identical or similar parts are indicated using the same reference numerals in the drawings.

The terminology used below is only for referring to specific embodiments and is not intended to limit the invention. As used herein, singular forms include plural forms unless phrases clearly indicate the contrary. As used in the specification, the meaning of "comprising" is to specify a specific characteristic, area, integer, step, operation, element and/or component, and to specify another specific property, area, integer, step, operation, element, component and/or group. It does not exclude the existence or addition of .

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. However, the following example is only a preferred example of the present invention and the present invention is not limited to the following example.

Figure 1 shows a tunnel inner wall fireproof device installed inside a tunnel according to this embodiment, and Figure 2 shows the configuration of a tunnel inner wall fireproof device according to this embodiment. Additionally, Figures 3 and 4 are diagrams showing some configurations of this embodiment in detail.

As shown, the fireproof device 10 of this embodiment includes a fireproof panel 20 that protects the inner wall of the tunnel 100 by blocking flames, a structural frame 30 that supports the fireproof panel 20, and a structural frame ( 30) and a cooling unit 40 for cooling the high heat applied to the fireproof panel 20.

Accordingly, the fireproof panel 20 is disposed along the inner wall of the tunnel 100 to protect the inner wall of the tunnel 100 from flames in the event of a fire.

The fireproof device 10 of this embodiment may be formed to have a predetermined length and may be arranged in plural pieces along the longitudinal direction of the tunnel 100. The longitudinal direction of the tunnel 100 can be understood as the direction passing from the entrance to the exit of the tunnel 100. For example, the structural frame 30 of the fireproofing device 10 is formed to be approximately 10 m long and can be installed continuously or at regular intervals along the longitudinal direction of the tunnel 100.

The structural frame 30 forms the framework of the device 10. For example, the structural frame 30 may be a truss structure in which straight pipes are arranged in a triangular shape and connected at the nodes. The shape of the structural frame 30 may vary depending on the tunnel 100.

The structural frame 30 is formed in a shape corresponding to the cross-sectional shape of the inside of the tunnel 100 and can be positioned at a predetermined distance from the inner wall of the tunnel 100. For example, in response to the tunnel 100 formed in a hemispherical cross-sectional shape, the structural frame 30 may be formed in a hemispherical shape and installed on the inner wall of the tunnel 100.

The structural frame 30 may be formed to extend a predetermined length along the longitudinal direction of the tunnel 100. As mentioned above, the structural frame 30 can be formed to be 10 m long.

The fireproof panel 20 is a plate structure that can withstand high temperatures. In this embodiment, the fireproof panel 20 has a square plate structure of a predetermined size and can be fixedly installed on the structural frame 30.

The fireproof panel 20 may be attached and installed on the front of the structural frame 30, that is, on the side facing the inside of the tunnel 100. Accordingly, the flame generated inside the tunnel 100 is blocked by the fireproof panel 20, and the structural frame 30 disposed on the rear side of the fireproof panel 20 and the inner wall of the tunnel 100 can be protected from flame. The rear may refer to the side facing the inner wall of the tunnel 100.

The size or shape of the fireproof panel 20 may be modified in various ways. A plurality of fireproof panels 20 may be tightly arranged without gaps and fixedly installed on the structural frame 30.

As shown in FIG. 2, the square-shaped fireproof panel 20 can be fixed to the structural frame 30 using clips 22, etc., which secure the corners of neighboring fireproof panels 20. Accordingly, four neighboring fireproof panels 20 can be fixed at once simply using the clips 22.

A cooling portion 40 may be provided between the structural frame 30 and the fireproof panel 20.

The cooling unit 40 is installed along the structural frame 30 and is disposed on the rear of the fireproof panel 20 to cool the structural frame 30 and the fireproof panel 20. Accordingly, the structural frame 30 and the fireproof panel 20 can be prevented from being deteriorated or damaged by high heat.

The cooling unit 40 of this embodiment may have a structure that distributes coolant using pipes 32 forming the truss structure of the structural frame 30. Accordingly, it is possible to cool the rear side of the fireproof panel 20 simply and more effectively.

For this purpose, the cooling unit 40 includes a water tank 44 that stores cooling water supplied to a truss-structured pipe 32 to increase the rigidity of the structural frame 30, the water tank 44, and the pipe 32. It may include a supply line 42 connecting the two, and a pump 46 installed on the supply line 42 to supply coolant of the water tank 44 to the pipe 32.

In addition, the cooling unit 40 may further include a heat detection sensor 52 for detecting a flame, and a control unit 50 that calculates the detection signal of the heat detection sensor 52 to control the operation of the pump 46. You can.

The heat detection sensor 52 may be installed on one side of the deterioration panel 20. The heat detection sensor 52 can be applied to any structure that can detect heat or flame. The control unit 50 drives the pump 46 when a flame is detected by the heat sensor 52. As the pump 46 is driven, the cooling water stored in the water tank 44 is supplied to the pipe 32 of the structural frame 30 through the supply line 42.

The pipe 32 is a hollow structure with an empty interior, and is installed so that the insides communicate with each other at the bend points where they are connected to each other. Accordingly, when cooling water is supplied into one pipe 32, the cooling water flows through the pipes 32 of the entire truss and flows throughout the structural frame 30.

Accordingly, the rear side of the structural frame 30 and the fireproof panel 20 is cooled by the cooling water, thereby protecting the fireproof panel 20 and the structural frame 30 from heat. In addition, even if the fireproof panel 20 does not function properly, the temperature of the structural frame 30 can be secondarily lowered to prevent the structural frame 30 or the inner wall of the tunnel 100 from being damaged by flame and high heat.

The supply line 42 may be selectively and detachably connected to the pipe 32 on one side of the structural frame 30. For example, male and female connectors 48 may be installed on the pipe 32 and the supply line 42 of the structural frame 30 and connected to each other.

Accordingly, this device 10 assembles the structural frame 30 and the fireproof panel 20 to form one unit, and separately from this unit, a supply line 42 for supplying coolant, a pump 46, and a water tank. (44) can be configured as another unit and connected using the male and female connectors (48) within the tunnel (100). Therefore, only the assembly of the fireproof panel 20 and the structural frame 30, excluding the cooling unit 40, can be easily moved and installed inside the tunnel 100.

This device 10 may further include a rail 60 and a moving wheel 62 so that the structural frame 30 on which the fireproof panel 20 is installed can be easily moved and installed within the tunnel 100.

The rails 60 may be installed on the bottom of both sides in the width direction of the tunnel 100 and extend along the longitudinal direction of the tunnel 100. The moving wheel 62 is installed at the bottom of both sides of the structural frame 30 and is seated on the rail 60.

Accordingly, the structural frame 30 can be easily moved inside the tunnel 100 as the moving wheel 62 rolls along the rail 60. Therefore, the device 10, which is a large structure, can be easily installed inside the tunnel 100. When the structural frame 30 moves inside the tunnel 100 and is fixed in place, the device 10 can be simply installed by connecting the supply line 42 of the separately provided cooling unit 40 to the structural frame 30. It can be installed inside the tunnel 100.

Additionally, the device 10 can be moved along the rail 60 by the moving wheel 62 within the tunnel 100. For this purpose, the device may be further equipped with a driving part that is connected to the moving wheel 62 and applies driving force. The driving unit may include, for example, a driving motor that applies rotational force to the moving wheel 62. The driving unit may be provided on the structural frame 30 or may be provided separately and connected to the moving wheel 62. The driving unit can be controlled according to the output signal of the control unit 50 to move the device. The control unit 50 can detect the location of a fire by calculating the detection signal of the heat sensor 52, and control the driving unit to move the necessary structural frame 30 to the location of the fire.

As the moving wheel rotates according to the operation of the driving part, the structural frame moves along the rail. Accordingly, when necessary, the structural frame can be moved to the location of the fire along the rail to protect the inner wall of the tunnel.

In the case of this structure, since there is no need to install a structural frame throughout the tunnel, a smaller number of structural frames can be arranged and installed within the tunnel. Therefore, the cost required to construct this device within the tunnel can be minimized.

Although exemplary embodiments of the present invention have been shown and described as described above, various modifications and other embodiments will occur to those skilled in the art. These modifications and other embodiments are to be considered and included in the appended claims without departing from the true spirit and scope of the present invention.

10: Fireproof device 20: Fireproof panel
22: Clip 30: Structural frame
32: pipe 40: cooling unit
42: supply line 44: water tank
46: pump 48: connector
50: Control unit 52: Heat sensor
60: rail 62: moving wheel

Claims (3)

It includes a structural frame formed in a shape corresponding to the inner shape of the tunnel and located on the inner wall of the tunnel, and a fireproof panel installed on the structural frame and covering the inner wall of the tunnel to protect it from flames,
It further includes a cooling unit installed along the structural frame and disposed behind the fireproof panel to cool the structural frame and the fireproof panel,
The structural frame is made of truss-structured pipes arranged in a triangular shape to increase rigidity, and the pipes are hollow structures with an empty interior, and the insides communicate with each other at bending points where they are connected to each other,
The cooling unit includes a water tank storing cooling water to be supplied to the pipe, a supply line connecting the water tank and the pipe, and a pump installed in the supply line to supply cooling water from the water tank to the pipe,
A fireproof device for the inner wall of a tunnel with a structure that cools the structural frame and the fireproof panel by supplying cooling water into the pipes of the truss structure forming the structural frame, distributing the cooling water along pipes that communicate with each other, and allowing it to flow throughout the structural frame. delete According to claim 1,
A tunnel inner wall fireproof device further comprising rails installed on the bottom of both sides in the width direction of the tunnel and extending along the tunnel, and moving wheels installed at lower ends of both sides of the structural frame and rolling along the rails.

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