KR20110137930A - Structure of spreading fireproof material continuously for improving fireproof function of connection of variable undersea structure - Google Patents

Abstract

PURPOSE: A continuous spreading structure of a fireproof material for improvement of the fireproof performance of junction in a variable undersea structure is provided to prevent damage to rubber sealant in the event of a fire by continuously spreading a fireproof material to junction. CONSTITUTION: A continuous spreading structure of a fireproof material comprises a first fireproof layer(110), a plate member(120), and a second fireproof layer(130). The first fireproof layer is inserted to the sides and bottom of a cavity(12) formed between segments(11). The plate member is fixed to both ends of the bottom of the cavity in order to separate the first fireproof layer from the cavity. The second fireproof layer is spread on the bottom surface of the plate member and the interior surface of the segments.

Description

Refractory continuous coating structure for improving the fire resistance of joints of variable subsea structures

The present invention relates to a refractory continuous coating structure for improving the fire resistance performance of the joint portion of the variable seabed structure, in detail, the variable seabed to continuously apply the refractory material to allow the deformation of the joint portion when maintaining the fire resistance performance while applying the refractory material to the joint portion It relates to a refractory continuous coating structure for improving the joint fire resistance performance of the structure.

The submerged tunnel, one of the submarine tunnels, is a kind of underwater tunnel that is manufactured by continuously installing the submerged enclosures in the form of a box structure. The submerged method has a low apparent specific gravity because buoyancy acts on the tunnel and does not require much support of the ground. Suitable for In addition, since the construction can be safely carried out at a deep water depth, and the construction efficiency is good, the advantages of short construction period and fewer restrictions on the ship's route are recognized.

These immersion tunnels are made of concrete on land, and then immersed in the water using buoyancy to transport the immersion enclosures to the installation site using the towing box and then sink and install at the installation site. The method is to construct a chamber between a new ship, which is a newly installed ship, which is a newly installed ship, and a hydraulic pressure difference is generated between the chamber and the outside of the new ship. Hydraulic bonding is used to bring the ship and the new ship into close contact.

To describe the immersion tunnel in more detail, the immersion tunnel is usually installed in the seabed section of several to several tens of kilometers (km), and the various immersion enclosures are connected to each other. Submerged enclosures used in these submerged tunnels are manufactured on land with a length of more than 100m and a width and height of more than a few tens of meters. At this time, the immersion enclosure is made so that the hollow portion is formed inside and both sides are open.

In order to maintain stability during transport and sedimentation, the immersion enclosure is composed of several tens of m-segments in succession, and the PS steel wires are arranged in the longitudinal direction on the floor and the ceiling slab, respectively. Posttensioning is performed to grab the segment.

And a joint part, ie, a segment joint, is needed in the construction joint part of a segment. On the other hand, in the case of submerged tunnels as well as submerged enclosures, segment joints are applied because they allow deformation of joints between segments.

1 is a cross-sectional view showing a segment joint configuration of a general immersion tunnel.

Referring to FIG. 1, the segment joint 10 installs a rubber waterstop 13, which is a primary water stop material, in the space of a joint 12 for watering between the segments 11 when pouring concrete. .

After the rubber tube shock absorber 14 is installed, the omega seal 15, which is the secondary water stopper, is fixed to the lower end of the rubber tube shock absorber 14 by using the anchor bolt 16 and the anchor plate 17 provided in advance. .

However, such a conventional joint may be damaged when a fire is generated in the subsea tunnel structure, so that high-pressure seawater may be introduced into the subsea tunnel to cause enormous damage.

The present invention is to solve the above problems, by applying a refractory material in the joint to allow the deformation of the joint while maintaining the refractory performance by continuously applying the refractory to the variable seabed to prevent damage to the rubber index material in the event of fire It is an object of the present invention to provide a refractory continuous coating structure for improving the joint fire resistance performance of the structure.

In addition, the present invention is to install the plates so that mutual flow in the overlapped state at the joints of the segments so that the cracks on the surface of the refractory material is not generated by the flow of the segment when applying the refractory material, the segment displacement by overlapping the refractory material on the plate Another object of the present invention is to provide a refractory continuous coating structure for improving the fire resistance performance of a joint of a variable subsea structure to prevent cracking of a refractory material even when it occurs.

In addition, another object of the present invention is to provide a refractory continuous coating structure for improving the fire resistance performance of the junction portion of the variable subsea structure to be separated from each other by providing a separation membrane in the cum part of the refractory material.

Features of the present invention for achieving the above object,

The joint portion consisting of a rubber index member provided in the space of the "iron" shape formed between the segment and the segment, and an omega seal provided by the anchor bolt and the anchor plate on one side of the rubber tube buffer member and the rubber tube buffer member A variable subsea tunnel structure comprising: a first refractory layer having a plate shape inserted into both sides and a bottom of the space part; A plate member fixed to both ends of a bottom surface of the space part to separate the space part of the first fireproof layer; And a second fireproof layer applied to the bottom surface of the plate member and the inner surface of the segment.

Here, the first fireproof layer and the first fireproof material which is inserted perpendicular to the bottom surface of the anchor plate on both sides of the space portion; A second refractory material is inserted horizontally from the bottom of both ends of the first refractory material.

The plate member may further include a base plate having both ends thereof bent to form first and second wing plates and having irregularities formed in a central portion thereof in a longitudinal direction to support the second refractory material; A first joint fixed to one side of the space by an anchor and bolted to the first wing plate of the base plate; And a second joint fixed to the other side of the space by an anchor and bolted to the second blade plate of the base plate to form an elliptical guide hole to allow the base plate to flow.

Here, the second fireproof layer is formed by first applying a refractory material on the bottom of the first and second wing plates of the base plate and the bottom of the unevenness at the same height as the bottom height of the base plate, but mutually with the space part. The gap G1 is formed to be separated, and the refractory material is secondarily applied to the bottom surface of the base plate and the bottom surface of the segment, and the gap G2 is formed to be separated from each other at the bottom surface of the second wing plate.

Here, the second refractory layer adheres the separator upon application of the fire resistant agent to the bottom of the second blade plate.

According to the fireproof continuous coating structure for improving the refractory performance of the joint portion of the variable seabed structure of the present invention configured as described above, when applying the refractory material to the joint, when the fire occurs by continuously applying the refractory material to allow the deformation of the joint portion to maintain the fire resistance performance By preventing the damage of the water products in advance, the enormous damage caused by the fire can be prevented.

In addition, according to the present invention when installing the refractory material to prevent the cracks on the surface of the refractory material by the flow of the segment to install the plates so that the mutual flow in the overlapping state in the overlapping state, respectively, and overlap the construction of the refractory material on the plate The continuity of the refractory material can be provided by preventing the generation of cracks in the refractory material even when displacement occurs.

In addition, according to the present invention it is possible to effectively cope with the flow of the segment by providing a separation membrane in the cum part of the refractory material to be separated from each other.

1 is a cross-sectional view showing a segment joint configuration of a general immersion tunnel.
Figure 2 is a cross-sectional view showing the configuration of the refractory continuous coating structure for improving the joint fire resistance performance of the variable seabed structure according to the present invention.
Figure 3 is a cross-sectional view showing the behavior of the refractory continuous coating structure for improving the fire resistance performance of the joint of the variable seabed structure according to the present invention.

Hereinafter, with reference to the accompanying drawings the configuration of the refractory continuous coating structure for improving the fire resistance performance of the joint portion of the variable seabed structure according to the present invention will be described in detail.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intentions or customs of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

Hereinafter, an embodiment of the present invention will be described based on the submerged enclosure of the subsea tunnel structure, but is not limited thereto.

Figure 2 is a cross-sectional view showing the configuration of the refractory continuous coating structure for improving the joint fire resistance performance of the variable seabed structure according to the present invention. In FIG. 2, the same part as FIG. 1 is attached | subjected, and the duplication description is abbreviate | omitted.

Referring to Figure 2, the refractory continuous coating structure for improving the fire resistance performance of the joint portion of the variable seabed structure according to the present invention is the first refractory layer 110 and the plate member at the joint, that is, the segment joint 10 installation position 120 is formed, and the second fireproof layer 130 is formed on the inner surface of the segment 11 including the segment joint 10 installation position.

First, the first fireproof layer 110 is a space portion 12 having an “iron” shape formed between the segment 11 and the segment 11 and the bottom surface of the anchor plate 17 of the segment joint 10. The first refractory material 111 of the mineral wool material is inserted into the vertical and the second refractory material 113 of the mineral wool material is inserted into the bottom of the first refractory material (111).

In addition, the plate member 120 has both bases bent to form first and second wing plates 121a and 121b, and a base plate having a concave-convex portion 121c formed in the center in the longitudinal direction to support the second refractory material 113. The first joint 123 formed in the form of a "memory" and fixed to one side of the space portion 12 by an anchor 101 and bolted to the wing plate 121a of the base plate 121. And, it is formed in the form of "memory" is fixed to the other side of the space portion 12 by the anchor 101, the wing plate 121b of the base plate 121 is bolted, in the base plate 121 The second joint 125 is formed with an elliptical guide hole 125a to flow.

In addition, the second fireproof layer 130 is applied to the first and second wing plates 121a and 121b and the uneven surface 121c of the base plate 121 at the same height as the bottom height of the base plate 121 by primary coating. The gap G1 is formed so as to be separated from the space part 12, and the refractory material is secondarily applied to the bottom surface of the base plate 121 and the bottom surface of the segment 11 to form a second wing plate ( A gap G2 is formed to be separated from each other at the bottom of 121b). Here, the second fireproof layer 130 adheres the separator 131 when the fire resistant agent is applied to the bottom surface of the second blade plate 121b in a second manner.

Hereinafter, the installation process of the refractory continuous coating structure for improving the refractory performance of the variable seabed structure according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a cross-sectional view showing the behavior of the refractory continuous coating structure for improving the fire resistance performance of the joint of the variable seabed structure according to the present invention.

First, the rubber index member 13 is installed at the joint site by the conventional method, and the rubber tube buffer 14 is installed between the rubber index members 13, and then the rubber tube buffer 14 The omega seal 15 is fixed using the anchor bolt 16 and the anchor plate 17 that are already installed to install the segment joint 10.

Then, one end of the first joint 123 and one end of the second joint 125 of the plate member 120 are fixed to the anchors 101 formed on both sides of the space 12.

In this state, the first blade plate 121a of the base plate 121 is fastened to the first joint 123 with a bolt, and the second blade plate 121b of the base plate 121 is fastened to the second joint 125. Tighten with bolts. At this time, the end of the second blade plate 121b of the base plate 121 is spaced apart from the second joint 125 by a predetermined distance to form a gap G1 to be formed in the second joint 125 even in the flow of the segment 11. The guide plate 125a allows the base plate 121 to flow from side to side as shown in FIG. 3.

Then, the first refractory material 111 and the second refractory material 113 is inserted between the space portion 12 and the base plate 121.

When the insertion of the first refractory material 111 and the second refractory material 113 is completed, the second refractory material in the form of paint is applied to the bottom surface of the first blade plate 121a, the second blade plate 121b, and the uneven surface 121c by applying a coating material. The fireproof layer 130 is formed, but the second fireproof layer 130 is primarily formed by applying to the same height as the bottom surface of the base plate 121. At this time, when the second fireproof layer 130 is formed on the bottom surface of the second blade plate 121b, the space 12 and the gap G1 are maintained to separate the second fireproof layer 130.

Then, the separation membrane 131 is bonded to the bottom of the second fireproof layer 130 formed on the bottom of the second blade plate 121b.

When the bonding of the separation membrane 131 is completed, the refractory material is secondarily applied to the bottom surface of the base plate 121 and the bottom surface of the segment 11 to be formed at the same height, but separated from each other at the bottom surface of the second blade plate 121b. The gap G2 is formed.

Then, since the second refractory layer 130 is separated from each other by the separator 131 and the gap G2 when the segment 11 flows, the second refractory layer 130 may flow left and right, as shown in FIG. 3.

Therefore, the fire resistance performance of the segment joint can be improved by forming the first fire resistant layer and the second fire resistant layer corresponding to the flow of the segment in the space part.

As those skilled in the art would realize, the described embodiments may be modified in various ways, all without departing from the spirit or scope of the present invention. It is to be understood, however, that the present invention is not limited to the specific forms referred to in the description, but rather includes all modifications, equivalents, and substitutions within the spirit and scope of the invention as defined by the appended claims. Should be.

10: segment joint 11: segment
12: space portion 13: rubber index material
14: rubber tube cushioning material 15: omega seals
16: anchor bolt 17: anchor plate
110: first fireproof layer 120: plate member
121: base plate 123, 125: first and second joint
130: second refractory layer 131 separator

Claims (5)

The joint portion consisting of a rubber index member provided in the space of the "iron" shape formed between the segment and the segment, and an omega seal provided by the anchor bolt and the anchor plate on one side of the rubber tube buffer member and the rubber tube buffer member In the variable subsea tunnel structure comprising,
A first fireproof layer having a plate shape inserted into both sides and a bottom of the space part;
A plate member fixed to both ends of a bottom surface of the space part to separate the space part of the first fireproof layer; And
A refractory continuous coating structure for improving the joint fire resistance performance of the variable subsea structure, characterized in that the second refractory layer is applied to the bottom surface of the plate member and the inner surface of the segment. The method of claim 1,
The first fireproof layer,
First refractory materials inserted perpendicularly to bottom surfaces of the anchor plates at both sides of the space part;
A refractory continuous coating structure for improving the refractory performance of the junction portion of the variable seabed structure, characterized in that the second refractory material is inserted horizontally from the bottom of both ends of the first refractory material. The method of claim 1,
The plate member,
A base plate having both ends bent to form first and second wing plates, and having unevenness formed in a longitudinal direction at a central portion thereof to support the second refractory material;
A first joint fixed to one side of the space by an anchor and bolted to the first wing plate of the base plate; And
It is fixed by the anchor to the other side of the space portion, the second wing plate of the base plate is bolted, the variable seabed structure, characterized in that it consists of a second joint is formed with an elliptical guide hole to flow the base plate Refractory continuous coating structure for improved joint fire resistance. The method of claim 3, wherein
The second fireproof layer,
The first and second wing plates of the base plate and the bottom surface of the unevenness is formed by applying a refractory material in the same manner as the bottom height of the base plate, but the gap (G1) is formed so as to be separated from the space portion, The refractory performance of the joint portion of the variable subsea structure, characterized in that formed by applying a second refractory material to the bottom of the base plate and the bottom of the segment secondary, the gap (G2) to be separated from each other at the bottom of the second wing plate. Refractory continuous application structure for improvement. The method of claim 4, wherein
The second fireproof layer,
Refractory continuous coating structure for improving the fire resistance performance of the junction portion of the variable seabed structure, characterized in that for bonding the separator when applying the second refractory to the bottom of the second wing plate.

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