KR200380103Y1 - Device of repairing a constructive material in water - Google Patents

Abstract

The present invention relates to an apparatus for repairing underwater structures, and more specifically, to install buoyancy control caissons in a short period of time, and to be safe from sudden danger of immersion of caissons due to water damage and reuse, and to reduce construction period and cost. One relates to an underwater structure repair apparatus.

Underwater structure repair apparatus according to the present invention is provided with a standard form which is fixed along the outer wall of the underwater structure and has a predetermined space for placing underwater concrete to empty the inside, and is mounted along the outside of the standard formwork A buoyancy control caisson block having a step gap for maintaining the formwork and a predetermined gap, and to order the water flowing into the caisson through the space formed between the standard formwork and the buoyancy control caisson block Characterized in that the rubber watertight material is fixed along the outer periphery of the standard formwork.

Description

Device of repairing a constructive material in water

The present invention relates to an apparatus for repairing underwater structures, and more specifically, it is possible to install buoyancy control caissons in a short period of time, and to be safe from sudden danger of immersion of caissons due to breakage of rubber watertight materials, and to be reused, and to reduce construction period and cost. To an underwater structure repair device.

The general structure of the bridge, as shown in Figure 1, the lower well 10 and the upper portion of the bridge 11, the bridge is a structure supporting the bridge top plate 12.

Therefore, the well 10 is always submerged in water, and as a result, the concrete gradually neutralizes from alkaline, so that the strength gradually decreases. Given the well circumference of the well is continuously crushed by this is exposed to the rebar (15) of the well (10) is exposed to the phenomenon of corrosion. As this process is repeated, the bridge becomes unstable and the strength of the bridge structure falls short of the original design, resulting in a decrease in the through load.

In order to prevent such a problem, pre-inspection and repair work on the crushed part were carried out underwater, or a sheet pile was formed around the well and drained after securing the space. Due to the small space at the bottom, continuous driving of piles is impossible and the drainage is continued due to the large amount of inflow water in the large work space, which is insufficient in construction and watertight stability.

In contrast, the tube caisson method (caisson), compared to the sheet pile method, diagnoses the repair and reinforcement of the deeper water in a safe dry space under the same conditions as the land, establishes the appropriate construction plan, and enables short-term construction and inspection. Construction costs can also be reduced. Related technologies are presented in Korean Patent Registration No. 0366252, 0369917.

In the dry construction method of the tube caisson method currently being constructed, as shown in FIG. 2, the tube 16 is made of a tent material made of polyurethane in the same circumference as the corresponding well 10 and is fixed to the lower part of the caisson 17 to designate a position. After falling to the caisson 17 is fixed to the piers from the top and the tube 16 is inflated by blocking the gap between the well 10 and the caisson 17 method.

However, in this method and the structure apparatus for performing the method, although the outer surface of the well 10 is exactly in contact with the inner surface of the tube, the order is achieved, the outer surface of the well 10 to be repaired is Since the scour and corrosion are already in progress and partially crushed, there is a problem in that the outer surface of the well 10 may not be good, and thus the order is not. That is, the surface of the well 10 is crushed deeply or deeply holed, there is also a place where the reinforcement concrete is projected to the outside due to the past underwater repair work, its shape is irregular and difficult to predict.

Accordingly, the tube 16 to be in contact with the concrete to be adopted by adopting a strong and tough material. In other words, the tube 16 is in contact with the concrete surface, so when puncture occurs during the friction with the rough concrete surface, the operator is in danger of sudden water sinking inside the caisson 17, so that a strong and tough material tube can be adopted. There is only one.

Strong and tough tubing lacks flexibility and can not be ordered in well or recessed well surface. At this time, divers will take additional measures. In this process, it takes a long time and excessive work costs, and when the water inside the caisson 17 is drained after the degree of work, the tube 16 hydraulic pressure acts, and often the subsidiary materials are partially pushed away by the hydraulic pressure.

The basic theory of the order by the tube caisson method is that the expansion pressure of the tube must be larger than the water pressure at the depth where the expanded tube is located, but the tube does not shrink against the water pressure to block the inflow of water. Therefore, in deep water, the expansion pressure of the tube is high, which increases the risk of puncture of the delamination or weak areas of the tube.

In addition, since the tube is manufactured by a thermal bonding method, the adhesive part is cured, the adhesive part is dropped during the expansion process, the tube pressure is reduced, the tube is contracted, and water is introduced into the caisson to continuously operate the drain pump.

In addition, the tube is expanded in parallel, at any one moment the tube shrinks rapidly, a large amount of water fills the caisson in a moment, and the dry state is destroyed. At this point, all work is stopped, the tube is replaced immediately, and the drainage work is carried out again. In this case, partial watertight work by the diver is carried out as before.

The apparatus for performing the repairing method of various underwater structures, including the well tube by the conventional tube caisson method, because of the rigidity and rigidity of the material to be applied to the tube to contact with the concrete, the lack of flexibility and irregularity There is a fatal problem that can not be ordered to the concrete surface, and because the expansion pressure of the tube is deep in the depth of water, there is a problem that the adhesive portion of the tube is peeled off or the risk of puncture of the weak area is increased, the tube manufactured by the thermal bonding method There was a problem that the adhesive part was hardened, the adhesive part fell during the expansion process, the tube pressure was lowered, the tube contracted, and water was introduced into the caisson to continuously operate the drainage pump. When it contracts rapidly, a large amount of water fills the caisson The state was destroyed, and when this state was stopped, all the work had to be stopped, and the tube had to be replaced immediately and drained again. Therefore, the work stability was extremely low and inefficient, and the economy was low.

Accordingly, an object of the present invention is to increase the degree of freedom in the physical properties of watertight materials according to the watertight material in order to make the watertight material in close contact with the surface of the concrete in order to maintain the stability of the watertight material.

Another object of the present invention, in repairing the underwater structure, to eliminate the peeling of the adhesive portion of the watertight material and to reduce the risk of puncture of the fragile site.

Another object of the present invention is to improve the problem of preventing the deformation of the watertight material in the repair of the underwater structure to block the inflow of water and to operate the drainage pump therefrom.

Another object of the present invention, in the repair of the underwater structure, the stable installation of the watertight material to enable a high-efficiency repair, while always maintaining the work stability, and economical repair is possible by reducing the construction period and cost.

Underwater structure repair apparatus according to the present invention for achieving this object, the buoyancy control caisson is installed along the circumference of the underwater structure, and the watertight material to block the water between the buoyancy control caisson and the underwater structure to be introduced into the caisson In the underwater structure repair device consisting of,

The standard formwork is provided along the outer wall of the underwater structure by having a predetermined space to pour the concrete inside the empty,

A buoyancy control caisson block mounted along the outside of the standard formwork and having a step for maintaining the gap to maintain a predetermined distance from the standard formwork;

Characterized by consisting of a rubber watertight member is settled along the outer periphery of the standard formwork to order the water flowing into the caisson along the space formed between the standard formwork and the buoyancy control caisson block.

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 3 to 6.

3 is a flowchart illustrating a method for repairing underwater structures to which the present invention is applied. Figure 4 is a repair structure construction state applying the underwater structure repair apparatus according to an embodiment of the present invention, Figure 5 is a detailed view of the portion A of FIG. 6 is various examples of the rubber watertight material according to the embodiment of the present invention, (a) is a cylindrical shape, (b) is an L-type, (c) is a T-type rubber watertight material.

Underwater structure repair apparatus configuration according to an embodiment of the present invention is as follows.

In the repair method applying the underwater structure repair apparatus according to an embodiment of the present invention, as shown in Figs. 3 and 4, by making the rubber watertight material 30 the same as the underwater structure 20, the underwater structure 20 It is installed along, the buoyancy control caisson block 40 is mounted on the upper side along the underwater structure 20, the rubber watertight material 30 is fixed to the lower portion of the caisson block 40 and lowered to a designated position caisson The block 40 is fixed to the underwater structure 20 at the top, and the rubber watertight material 30 is expanded to block the space between the underwater structure 20 and the caisson block 40 by the expansion of the rubber watertight material 30. By creating a dry space around the underwater structure 20 to repair a specific portion or all of the underwater structure 20 to be repaired under the same conditions as the land.

Specifically, the standard formwork 50 is installed at a lower position along the underwater structure 20 (S100), and the water-incomparable concrete (inside surface) of the standard formwork 50 installed along the underwater structure 20 ( Pour 60 and curing (S200), the step of fixing the standard formwork 50 along the underwater structure 20 (S300), the upper portion of the standard formwork 50 is settled along the underwater structure 20 At least one buoyancy control caisson block 40 for buoyancy control at the side through the step of stacking the caisson block 40 by stacking the underwater structure 20 (S400), the outside of the standard formwork 50 The space between the standard formwork 50 and the caisson block 40 is formed by winding the rubber watertight member 30 along the underwater structure 20 around the space between the lower ends of the caisson block 40, which is in contact with the side, and connecting the two ends. Order pretreatment step (S500) to prevent When the rubber watertight material 30 is installed along the underwater structure 20 through the order pretreatment step, the fresh water in the caisson block 40 is drained (S501). 30) to dry the interior of the caisson block 40 by filling the space between the standard formwork 50 and the caisson block 40 with buoyancy (S600) to complete the reinforcement and repair work on the repair target site of the underwater structure (S700 to S701).

The fixing of the standard formwork 50 to be fixed to the underwater structure 20, by dividing the standard formwork 50 into at least one or more, and fixing them in combination to reduce the volume in the installation step to simplify the installation work in poor water can do.

The fixing of the buoyancy control caisson block 40, the buoyancy tank 41 is installed in the lower portion, the buoyancy control caisson 42 is installed in the upper portion, and the caisson block in the order of installing the work footrest 43 on the top. 40 is fixed around the underwater structure (20).

The brace 70 is installed in the space between the underwater structure 20 and the buoyancy control caisson block 40 in order to prevent the flow and position deformation of the buoyancy control caisson block 40 settled around the underwater structure 20. The underwater structure 20 can be repaired stably.

Preferred repairing apparatus for an underwater structure according to the present invention for implementing the above repair method in repairing the underwater structure, as shown in Figures 4 to 6, buoyancy control caisson block is installed along the circumference of the underwater structure 20 ( 40) and the buoyancy control caisson block 40 and the underwater structure 20 to block the water flowing into the caisson block 40 to the water-tight material 30 is a structure.

The main part is provided with a predetermined space 61 for emptying the interior concrete 60, the standard formwork 50 is fixed along the outer wall of the underwater structure 20, and the standard formwork 50 Buoyancy adjustment caisson block (40) mounted along the outside and having a gap step 44 for maintaining a predetermined distance with the standard formwork 50, and the standard formwork 50 and the buoyancy control It is made of a rubber watertight material 30 that is settled along the outer circumference of the standard formwork 50 to order the water flowing in the hydraulic pressure into the interior of the caisson block 40 along the space formed between the caisson block 40 .

The bottom surface of the standard mold 50 is bent in the form of a flange 62 in close contact with the underwater structure 20 to prevent the loss of the underwater concrete 60, the upper surface is poured underwater concrete (60) It is formed as an open space for.

The buoyancy control caisson block 40 is the lower portion is made of a buoyancy tank 41, the upper portion is made of a buoyancy adjustment caisson 42, the top may be provided with a working footrest 43.

The rubber watertight material 30 can be produced in a variety of cylindrical cross-sections and L-shaped T, such as (a) (b) (c) of Figure 6, through which the bottom or standard formwork of the caisson block 40 (50) and the appropriate one can be selected and applied according to the wall shape of the underwater structure 20, such a rubber watertight material 30 is basically between the standard formwork 50 and the caisson block (40) with the underwater floating force Due to the space, the tubular watertight material does not have to be used. That is, only the flexibility enough to be wound around the underwater structure 20 is given, it is possible to apply a structure that does not have to put the air pressure, so that the degree of freedom of choice of rubber watertight material.

Such an underwater structure repair apparatus, as shown in Figures 3 to 6, to install the standard formwork 50 at the lower portion of the repair site around the underwater structure 20, the underwater formable concrete 60, the standard formwork ( After curing by pouring in 50) and then set the buoyancy control caisson block (40) to the upper side without removing the standard formwork (50), the rubber watertight member (30) and the standard formwork (50) and caisson block ( By turning around 40, it is possible to simply repair the underwater structure 20.

Here, the caisson block 40 and the standard formwork 50 can be easily assembled and installed without mutual interference because they have the same cross-sectional shape, and the standard formwork 50 uses steel as a base material in consideration of possible strength and the caisson block. (40) has a buoyancy tank (41) that can be easily supplied and drained during the movement and installation and dismantling of the caisson block (40) by fixing the plumbing submersible pump fixed pipe inside the buoyancy tank (41), By installing the working scaffold 43 on the uppermost floor, it is possible to secure work stability by protecting a worker from slipping or leaving.

In addition, as shown in Figure 5, by turning the cylindrical rubber watertight material 30 on the side of the standard formwork 50, the lower end of the caisson block 40 by connecting the both ends with the rubber of the same material inside the caisson block 40 When the water is drained, the deeper the water, the stronger the pressure pushes the cylindrical rubber watertight material 30 at a higher water pressure, this method is not a simple order by the pressure of the tube, but the autogenous by the installation position of the rubber watertight material 30 Water pressure indicates the order action using the buoyancy force of the rubber watertight material 30 acting in the upward direction, and there is no risk of puncture of the rubber watertight material 30, thereby causing a sudden inflow of water into the caisson block 40. There is no worry about it, so it is possible to get rid of the unstable condition and secure the working stability.

In addition, the rubber watertight material 30 can be produced in a variety of shapes, as shown in Figure 6, can be selected and applied according to the shape of the underwater structure 20 and the caisson block 40 of the other shape and reuse is also economical to be.

The apparatus for repairing an underwater structure according to the present invention has an effect of increasing the degree of freedom of selection regarding the properties of the watertight material according to the watertight material in order to bring the watertight material into close contact with the surface of the concrete. In addition, in repairing underwater structures, it is possible to eliminate the peeling of adhesive parts of watertight materials and to reduce the risk of breakage of vulnerable parts, thereby ensuring operational stability due to the repair of underwater structures, shortening repair air, and high efficiency reinforcement and repair at low cost. Has the effect of enabling. In addition, in repairing the underwater structure, there is an effect to improve the workability and work stability by improving the drainage pump operation problems due to the water flowing into the caisson. In addition, in repairing the underwater structure, the stable installation of the watertight material to enable a high-efficiency repair while maintaining the work stability at all times, there is an effect that enables economic repair by saving time and cost.

1 is a reference diagram for explaining the structure of a general bridge foundation well

2 is a reference diagram for explaining a conventional tube caisson method

3 is a flowchart illustrating a method for repairing an underwater structure applying a repair device according to an embodiment of the present invention.

Figure 4 is a repair structure construction state applying the underwater structure repair apparatus according to an embodiment of the present invention

5 is a detailed view of portion A of FIG.

6 is various examples of the rubber watertight material according to the embodiment of the present invention, (a) is a cylindrical shape, (b) is L-type, (c) is a T-type rubber watertight material

* Description of the symbols for the main parts of the drawings *

20: underwater structure 30: rubber watertight

40: caisson block 41: buoyancy tank

42: buoyancy adjustment caisson 43: working step

44: step 50: standard mold

60: concrete 61: space

62: flange 70: brace

Claims (4)

In the buoyancy control caisson is installed along the circumference of the underwater structure, and the underwater structure repair device consisting of a watertight member to block the water between the buoyancy control caisson and the underwater structure to enter the caisson, The standard formwork is provided along the outer wall of the underwater structure by having a predetermined space to pour the concrete inside the empty, A buoyancy control caisson block mounted along the outside of the standard formwork and having a step for maintaining the gap to maintain a predetermined distance from the standard formwork; Underwater structure repair, characterized in that made of a rubber watertight settled along the outer periphery of the standard formwork to order the water flowing into the caisson along the space formed between the standard formwork and the buoyancy control caisson block Device. The method of claim 1, The bottom surface of the standard formwork is bent in a flange shape to be in close contact with the underwater structure to prevent the loss of the underwater concrete, the upper surface is an underwater structure repair device, characterized in that formed as an open space for placing underwater concrete . The method of claim 1, The buoyancy control caisson block is a lower portion is made of a buoyancy tank, the upper portion is made of a buoyancy control caisson, the top of the underwater structure repair apparatus, characterized in that it has a working scaffold. The method of claim 1, The rubber watertight member is an underwater structure repair device, characterized in that formed in a cylindrical cross section.