KR100420074B1 - A Construction Method of Underwater Concreting - Google Patents

Abstract

The present invention relates to an underwater concrete placing method that is carried out when it is unavoidable to place concrete in the water such as in the seabed or in the sea and the high groundwater area, in particular, a rubber ball or styrofoam in the tremi tube during the initial casting of the underwater concrete. Contrary to the conventional method, which caused many problems by adding a large amount of water, instead of a rubber ball or styrofoam, a cylindrical ice crystal that is not contracted by water pressure is injected into the water, and ice floats on the water in the Tremi tube. The method of pouring provides the method of pouring underwater concrete that allows the ice crystals to completely block the contact between the initial concrete and the water, and separates the materials that are inevitably generated by placing concrete in the water using Tremie. Significantly reduces phenomena, resulting in higher quality concrete To get the structure.

Description

A Construction Method of Underwater Concreting

The present invention relates to an underwater concrete placing method to be carried out when it is inevitable to place concrete in the water, such as in the seabed or the sea and high groundwater areas, in particular by pouring concrete in the water using Tremie (Tremie) The present invention relates to an underwater concrete placing method for drastically reducing material separation.

In placing the conventional underwater concrete, as shown in Fig. 1, a Tremie tube 1 having a diameter of 25 to 50 cm is put into the water, and the lower end inlet of the Tremi tube 1 is placed at the bottom of the water. The air-injected rubber ball (2) is placed in the inside of the tremy tube (1) and floated on the water filled in the tremy tube (1), and then the concrete (c) Is started to be poured, while the lower tip of the tremy tube 1 is buried in the concrete (c) to be poured for about 2 to 6 m while being pulled upward and poured continuously.

In addition, Korean Patent No. 148168 discloses a technique of placing stitrofoam into a tremi tube instead of a rubber ball, floating it on water filled in a tremi tube, and then pouring initial concrete.

In the above, the rubber ball (2) or styrofoam is first put into the tremi tube (1) and then the concrete is injected because the contact between the water filled in the tremi tube (1) and the concrete initially injected This is to prevent material separation of concrete.

By the way, in the construction process as described above, using a rubber ball (2) or styrofoam similar to the diameter of the tremy tube (1) to block the concrete contact with water at the time of initial concrete casting, but the concrete is initially injected The material separation phenomena, reliability of pour joints, and serious problems with reinforcement and concrete attachment remain unresolved.

That is, the rubber ball 2 or styrofoam is contracted under water pressure as it dives into the water as shown in FIG. It may be mistaken that there was no change, but in reality, as it descends deep into the water, the volume of the ball (2) or styrofoam decreases and is gradually spaced apart from the inner circumferential surface of the tremi tube (1). As it is lowered and accumulated on the floor while being washed by water, the quality of the concrete structure is greatly degraded.

And, the rubber ball (2) or styrofoam was difficult to recover, and when buried in the concrete pile to be poured on the surface of the concrete is formed, there is a problem that a large void is formed at the lower end of the concrete structure to remain as a defect of the finished concrete structure. .

In addition, in order to discharge the ball 2 or the styrofoam inside the tremi tube 1, the tremi tube 1 is lifted by the diameter of the ball 2 from the bottom surface, where a large amount of water rapidly enters the concrete. By penetrating and causing extreme concrete washing phenomenon, the quality of the concrete structure is increased.

On the other hand, the upper part of the tremble tube 1 is unstable and the lower part of the tremble tube 1 is buried too deeply in concrete during underwater concrete placement, so that the tremble tube 2 can be pulled out or the unit of the tremble tube 1 When the lot is removed, the flow of the tremble tube 1 is severe and a large gap is generated between the outer peripheral surface of the tremble tube 1 and the concrete. It is caused largely.

In consideration of the problems of the conventional construction method, there are other underwater concrete placing methods such as concrete pump method, bottom box and bottom bag using method, bag concrete method, etc. Although attempts have been made to reduce, any method cannot be used as a factor that increases the cost of construction, and cannot be excluded from the contact with water.

Accordingly, the present invention is devised to suppress the concrete material separation phenomenon that is inevitably generated when placing underwater concrete.

Therefore, an object of the present invention is to minimize the area of contact between the water filled in the interior of the Tremie tube and the concrete that is initially introduced by using ice crystals during the initial concrete placement, where material separation occurs most frequently during underwater concrete placement. State is to provide underwater concrete pouring method.

Another object of the present invention is to allow ice crystals that isolate concrete and water in the Tremi tube to easily escape without having to enter the Tremi tube when it reaches the bottom of the water and exits the Tremi tube. It is to provide an underwater concrete pouring method to prevent water from rapidly penetrating into concrete when placing concrete.

It is another object of the present invention to stably support the upper part of the trem tube so that it does not flow when lifting the trem tube or removing the unit lot of the trem tube. The present invention provides an underwater concrete pouring method to prevent water from penetrating into concrete through an outer circumferential surface.

1 and 2 is a view showing the underwater concrete casting scene using a conventional rubber ball

3 and 4 is a view showing the underwater concrete pouring scene according to the present invention

Figures 5a and 5b is a cross-sectional view and one side view showing the ice crystals used in the present invention

Figure 6 is a perspective view showing a state in which the upper portion of the tremi tube fixed in accordance with the present invention

<Description of the symbols for the main parts of the drawings>

10: Tremi tube 11: Hopper

20: ice crystal 21: steel wire structure

30: spacing 40: tofu fixing frame

c: concrete

In the present invention, in order to build structures such as cast-in-place concrete piles and underground continuous walls in the sea or the sea where the groundwater level is high, the inlet of the lower end of the Tremie tube is placed at the bottom of the water while leaving the water intact. Next, when the concrete is poured into the tremi tube and the concrete is cast to a certain height, the construction method for continuously pouring underwater concrete while raising the tremi tube to the upper part has the same technical concept as the prior art.

However, in the present invention, instead of putting rubber balls or styrofoam into the tremi tube during the initial pouring of the underwater concrete, a cylindrical ice crystal that is not contracted by water pressure is introduced, and the ice is placed on the water in the tremi tube. After floating, by placing concrete, the ice crystals completely block the initial contact between concrete and water, thereby providing an underwater concrete pouring method that prevents material separation from the first concrete to be poured. .

Hereinafter, the technical configuration of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 3, the present invention locates the lower tip inlet of the tremi tube 10 at the bottom of the water, and then, before the concrete is injected into the tremi tube 10, the interior of the tremi tube 10. FIG. Into the cylindrical ice crystals 20 made of the same size as the diameter of the Tremi tube 10 is put on the water filled in the tremi tube (10).

Next, the concrete (c) is started to be injected into the interior of the tremi tube 10 through the hopper 11 provided at the upper end of the tremi tube 10 in a state where the purified state of water is maintained.

As described above, when the concrete is injected, as shown in FIG. 4, the concrete (c) first injected into the tremi tube 10 is discharged through the tip inlet of the tremi tube 10 until the ice crystal 20 is discharged. By blocking the contact between the concrete (c) and the water and then out of the tremi tube (10), to prevent the material separation of the concrete to be poured first.

In carrying out the present invention as described above, a certain height (approximately equal to the maximum height of the ice crystal 20 to be described later) in the lower tip portion of the tremy tube 10 prior to the insertion of the tremy tube 10 in water. Ice crystals 20 are placed in the water by installing a gap holder 30 for maintaining the height), grounding the bottom end of the gap holder 30 to the bottom of the water, and then pouring concrete c. When it arrives at the bottom of it is desirable to be able to escape out of the tremi tube (10).

Therefore, in the present invention, since the ice crystal 20 does not need to be lifted up or moved in order to discharge the ice crystals 20 from the inside of the tremi tube 10, the water rapidly flows into the concrete c during initial concrete pouring. It doesn't flow in.

The ice crystal 20 is floated on the water surface when it comes out of the tremi tube 10, in this case, even if the ice crystal is buried in the concrete pile to be poured without being injured, it will automatically melt away when the water elapses There are no voids in the cross section of the concrete structure to be constructed, which does not have any bad effect.

By the way, the ice crystals 20, as shown in Figures 5a and 5b, it is preferable that the upper portion is formed to be inclined in one direction at a predetermined angle.

As such, the structure in which the upper end of the ice crystal 20 is formed to be inclined is pushed out by sliding sideways by the weight of concrete when the ice crystal 20 arriving at the bottom of the water exits out of the tremi tube 10. To help injuries.

The ice crystal 20 has a diameter of about 10 mm smaller than that of the tremi tube 10, and a height of about 100 mm and a height of about 150 mm are used. This is advantageous because the initial concrete can be poured with the beauty tube 10 slightly lower from the bottom of the water.

In addition, in order to prevent the ice crystals 20 from being damaged during transportation to the site or input into the inside of the tremi tube 10, it is preferable to insert the steel wire structure 21 therein and to form the ice crystals 21 therein.

Meanwhile, in carrying out the present invention, as shown in FIG. 6, the head fixing frame is extended and fixed to the ground surface while surrounding the circumference of the trem tube 10 in a lattice form on the upper head of the trem tube 10 ( 40) is installed to absorb and stably support vibrations and shocks generated during underwater concrete placement and when removing the unit lot of the tremy tube 10, thereby supporting concrete through the outer circumferential surface of the tremy tube embedded in the poured concrete. To prevent the penetration of water into the water as much as possible.

The present invention carried out as described above is very useful for the construction method such as Benoto, Earth drill, Reverse Circulation (RCD), Slurry wall, etc., which concrete is poured in water, especially large diameter Since the cast-in-place concrete pile is structure that resists external force with tip support, the stress concentration part of the pile tip must be strictly managed, but in actual work, the pile bottom encounters the limit of concrete placing and the pile bottom has the most material separation. Because it can be used very effectively.

The present invention made as described above has the following effects.

Before the concrete is first injected, ice crystals introduced into the Tremi tube block the contact between water and the original concrete as much as possible, thereby completely preventing the separation of concrete materials, thereby constructing a structurally robust concrete structure.

In addition, by installing a gap support at the bottom of the tremi tube, the ice crystals that separate the concrete and the water from the tremi tube arrive easily at the bottom of the water without having to lift the tremi tube. In this process, material separation of the concrete does not occur rapidly because water does not rapidly penetrate into the concrete when the concrete is discharged out of the trem tube.

In addition, when lifting the trem tube or removing the unit lot of the trem tube during concrete pouring, it is stably supported so that the trem tube does not flow through the head fixing frame installed on the upper part of the trem tube. There is no gap around the outer circumference of the buried tremi tube, which prevents water from penetrating into the concrete, resulting in a higher quality concrete structure.

Incidentally, ice used as a barrier between concrete and water is much cheaper than rubber balls or styrofoam, which is used in the prior art, so it is not only economically economical, but also has no problem of environmental pollution due to natural melting.

As described above, the present invention is a very useful invention to realize a high quality concrete structure by preventing the concrete material separation phenomenon as much as possible when placing underwater concrete.

Claims (3)

In order to build structures such as cast-in-place concrete piles and underground continuous walls in the seabed or the sea where the groundwater level is high, place the lower end entrance of the tremi tube at the bottom of the water with water intact, and then inside the tremi tube. In the case of pouring concrete into the concrete, when the concrete is poured to a certain height, the method of continuously pouring underwater concrete while pulling up the tremi tube to the top, Just before the concrete is injected into the Tremi tube, a cylindrical ice crystal 20 made of the same size as the tube diameter of the Tremi tube 10 is introduced into the Tremi tube 10, and the Tremi tube 10 is introduced. After floating on the water filled in, the concrete (c) is started to be injected into the interior of the tremi tube (10), so that the concrete (c) first injected into the tremi tube (10) of the tremi tube (10) Until the ice crystal 20 blocks the contact between the concrete (c) and water until just before being discharged through the tip inlet, the ice crystal 20 exits out of the tremi tube 10 so that the material separation phenomenon of the first poured concrete does not occur. Underwater concrete pouring method characterized in that. According to claim 1, wherein the ice crystals 20 is a steel wire structure 21 is inserted therein, the upper portion is formed using a predetermined angle to be inclined in one direction, the ice crystals 20 that arrived at the bottom of the water is Underwater concrete pouring method characterized in that when sliding out of the tremi tube (10) by sliding the side by the weight of the concrete to be pushed out onto the water surface. According to claim 1, wherein the lower end of the tremi tube 10, the interval for maintaining a predetermined height so that the ice crystals 20 to escape the tremi tube 10 when it reaches the bottom of the water After installing the holding table 30, the bottom end of the spacing table 30 is grounded to the bottom of the water, and then the concrete (c) is injected into the inside of the tremi pipe (10), the tremi pipe (10) In the upper head of the head) is installed a head fixing frame 40 which extends and is fixed to the ground surface while wrapping the periphery of the tremi tube 10 in a lattice form to remove the unit lot of the underwater concrete and the tremi tube 10. Underwater concrete pouring method characterized by absorbing the vibration and shock generated when the support is stable.