KR200387364Y1 - steel well foundation equipment - Google Patents

Abstract

The present invention can construct the base of steel wells by manufacturing, transporting and installing a plurality of lots (lower, middle, upper well caissons) as small cranes in rivers, reservoirs, estuaries, etc., where marine large cranes cannot enter. The present invention relates to a steel water well foundation construction facility.

Description

Steel well foundation equipment

The present invention can construct the base of steel wells by manufacturing, transporting and installing a plurality of lots (lower, middle, upper well caissons) as small cranes in rivers, reservoirs, estuaries, etc., where marine large cranes cannot enter. The present invention relates to a steel water well foundation construction facility.

The basic types of bridges constructed at sea, rivers, rivers, etc. include direct foundations, pile foundations, well well foundations, and caisson foundations. The most commonly used foundation is well well base, which is divided into concrete well base and steel well base. If the water depth is shallow, construct the concrete well base with a shaft, and if the water depth is deep (more than 5m), the steel well caisson is manufactured on land and then transported to the site with a large marine crane (3) of 1500 tons or more. After installing steel well bucket caisson at a time (see Korean Patent Publication No. 1999-42532).

That is, the height of one steel well caisson is 1.5 to 2m and the weight is about 150 to 200 tons. Therefore, in order to install at a depth of 5m or more, at least a plurality of steel well caisson lots, such as three, should be bolted together or welded (to ensure watertightness) to be joined to each other. The combined integral steel well caisson 1 has a weight of 600 tons or more depending on its height. The offshore large crane for transporting this heavy steel well caisson 1 shall be at least 1000 tonnes or more (see Fig. 1). Currently, there are 3,000 tons of Samsung cranes, 2000 tons of Seorak and 1500 tons of Daelim.

There is a limit that the marine oversize crane of more than 1000 tons cannot enter the reservoir, the upper area of the river, or the inner shore of the embankment such as the Sihwa Lake and the Image River. Therefore, it is understood that the cost of separating, moving, and reassembling marine large cranes is, for example, about 780 million.

The present invention was devised to solve the above-mentioned problems. The construction of the steel well container base can be used to construct the foundation of the steel water well caisson as a small crane that is easy to carry, install and inexpensive in an area where marine large cranes cannot enter. The purpose is to provide the equipment.

Steel well ventilation foundation construction equipment of the present invention for achieving the above object is a first inner wall, the first outer wall, a floor connecting the lower end of the first inner wall and the first outer wall, between the first inner wall and the first outer wall A first well caisson where the first reinforcing bar is disposed in the first partition of the first well; It comprises a second well caisson installed in the first well caisson.

According to this configuration, it is possible to construct the foundation of the steel water well caisson with a small crane that is easy to transport, install and inexpensive in an area where marine large cranes cannot enter.

In the above-described configuration, the second well barrel caisson is composed of a second inner wall installed on the first inner wall, a second outer wall provided on the first outer wall, and a second reinforcing bar connected to the first reinforcing bar. Preferably, the connection between the reinforcing bar is made by the male screw formed on each of the reinforcing bars and the coupling screwed to the male screw, the connection is fast and robust to improve the workability on the water.

In addition, a tube is installed on the first inner wall of the first well caisson, a third well caisson is installed on the second well caisson, the third well caisson is a third installed on the second inner wall Preferably, the inner wall, the third outer wall provided on the second outer wall, and the third rebar connected to the second reinforcing bar by a coupling.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

2 is a view showing a state in which the lower well bucket caisson of the steel well bucket caisson according to a preferred embodiment of the present invention is installed on the land to move to the base position with a small crane, Figure 3a to 3d is a lower well bucket 4 is a view showing the installation procedure of the intermediate well caisson in the caisson, Figure 4 is a diagram for placing concrete on the partition wall of the lower / middle well caisson, Figure 5 is a step of filling the interior after installing the steel well caisson. Figure 6 is a flow chart illustrating a steel water well foundation construction method according to the present invention.

Steel well base construction method of the present embodiment, first, to produce a lower well caisson having a shoe on the land (S10). As shown in FIGS. 2 and 3A, the lower well barrel caisson 10 has a bottom inclined at a lower end of the lower inner wall 11, the lower outer wall 13, the lower inner wall 11, and the lower inner wall 13 ( It is preferable that it consists of the cylindrical steel shoe lower caisson which has the shoe which consists of 15). In addition, in the lower partition wall between the lower inner wall 11 and the lower outer wall, the gap reinforcing material 17 of the L-shaped steel is welded to the lower inner wall 11 and the lower outer wall 13, and the reinforcing bars 18 and 19 are disposed. desirable.

Since the lower well caisson 10 is about 180 tons when the height is 20 m, it can be lifted by the small crane 5 of 150 to 200 or 200 tons, so that it can be installed at the well well base site (S13). . That is, float the lower well caisson 10 on the surface of the field. It is preferable to install the tube 20 in consideration of the draft state of the lower well barrel caisson 10 in the floating state (S12). That is, because the length of the lower well caisson 10 is placed on the surface of the site in a state shorter than the length of the conventional completed steel well caisson 1, because there is a high risk of not going down than the long case. This tube 20 is preferably provided by the fastening member 21 on the inner peripheral surface of the lower inner wall (11). For example, the fastening member 21 may be implemented by the hook of the lower inner wall 11 and the hook of the tube. On the other hand, before installing the lower well caisson 10 in the field, it is possible to arrange the lower bed and install the guide pile (7).

After installing the lower well caisson 10 in the field and install the intermediate well caisson 30 thereon (S14). The intermediate well caisson 30 welds or bolts the intermediate inner wall 31 to the lower inner wall 11 (FIG. 3B), and then connects the intermediate vertical reinforcement 38 to the lower vertical reinforcing bar 18 (FIG. 3C). ), The intermediate outer wall 33 is welded or bolted to the lower outer wall 13 (FIG. 3D). Connection method of the reinforcing bar 18 and the reinforcing bar 38 is composed of overlapping, pressure welding, coupling, in this embodiment is implemented by the coupling 40, which is a cylindrical nut, can improve the workability. That is, when the female threaded coupling 40 is rotated, the male thread machined to the vertical bars 18 and 38 is screwed and simply connected. In addition, it is preferable to reinforce the horizontal reinforcement 39 to the vertical reinforcement 38. In the case where the intermediate inner wall 31 is a divided cylinder, not only the circumferential welding but also the longitudinal welding may be performed.

After the intermediate well caisson 30 is installed to remove the tube (20) (S15). After removing the tube 20, the concrete is poured into the partitions 12 and 32 to a suitable height so as not to sink in consideration of the draft (S16).

Then, if necessary, the upper well caisson 50 is installed in the intermediate well caisson 30 (S17) to form a steel well caisson assembly 100. Since the installation of the upper well caisson 50 is the same as the installation of the intermediate well caisson 30, a detailed description thereof will be omitted.

After the steel well barrel caisson assembly 100 is formed, as shown in Figure 4, the concrete is poured into the partition wall to gradually sink (S18). The internal drilling of the sinking steel well caisson 100 is repeated to reach the support layer (S19). If necessary, after installing the formwork on the upper end of the upper well caisson 50 before the step (S19) to form a wall by placing concrete, it can be carried out internal drilling.

After the steel well bucket caisson 100 reaches the support layer, it fills the interior of the steel well bucket caisson, first pouring the concrete for the watertight between the support layer and the steel well bucket caisson 100 on the support layer and pumping, as shown in FIG. As described above, the concrete (or sand) is poured to complete the filling (S20).

As described above, the lower well caisson 10 constituting a part of the steel well caisson 100 is manufactured on the ground and installed on the site, and then the middle well caisson 30 and the upper well caisson 50 thereon. It can be installed to work with small cranes that can enter inland rivers, reservoirs, banks of Sihwa Lake or Yeongsan River without disassembly and assembly. Therefore, the cost and time for disassembly and assembly can be remarkably saved.

Steel well base construction equipment according to the present invention is not limited to the above embodiment can be carried out in a variety of modifications within the range allowed by the technical idea of the present invention.

As apparent from the above description, the present invention has the following effects.

First, by installing multiple steel well caissons, it is possible to carry out heavy lifting work with small cranes in the field, so that additional costs are required in reservoirs or banks where marine large cranes cannot enter (disassembly, assembly of marine large cranes and vice versa). Can be constructed without generating

Second, by installing a tube on the inner circumferential surface of the lower well caisson, it is possible to eliminate the high risk of the lower well caisson of relatively short length.

Third, the connection between the reinforcing bar is performed by the coupling, it is possible to improve the workability on the water by connecting the connection between the reinforcing bar quickly and firmly.

1 is a view showing a state in which a steel well barrel caisson manufactured integrally on a conventional land and installed by moving to a base position by a large marine crane.

2 is a view showing a state in which the lower well bucket caisson of the steel well bucket caisson according to a preferred embodiment of the present invention is installed on the land to move to the base position with a small crane.

Figures 3a to 3d is a view showing the installation procedure of the intermediate well caisson in the lower well caisson.

Figure 4 is a view showing a state in which concrete is poured on the partition wall of the lower / middle well caisson.

Figure 5 is a view showing the step of filling the interior after installing the steel well caisson.

Figure 6 is a flow chart showing the steel well ventilation foundation construction method according to the present invention.

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

10: lower (first) well caisson 20: tube

30: middle (second) well bucket caisson 40: coupling

50: upper (third) water well caisson 100: steel water well caisson

Claims (3)

A first well barrel caisson in which a first reinforcing bar is disposed on a first inner wall, a first outer wall, a floor connecting a lower end of the first inner wall and the first outer wall, and a first partition wall between the first inner wall and the first outer wall. ; Steel well cylinder foundation construction equipment comprising a second well caisson installed in the first well caisson. According to claim 1, wherein the second well caisson is composed of a second inner wall is installed on the first inner wall, a second outer wall provided on the first outer wall, and a second reinforcing bar connected to the first reinforcement , The connection between the reinforcing bar is a steel well ventilation foundation construction equipment, characterized in that made by a male screw formed in each of the reinforcing bars, the coupling is screwed with the male screw. The method of claim 2, wherein a tube is installed on the first inner wall of the first well caisson, The third well caisson is installed in the second well caisson, The third well caisson is composed of a third inner wall is installed on the second inner wall, a third outer wall is installed on the second outer wall, and a third reinforcing bar connected by coupling to the second reinforcing bar Steel well ventilation foundation construction equipment.