KR101018289B1 - Pile-deck type Light Beacon Structure with Prestressed Anchor - Google Patents

Abstract

The present invention relates to a pile deck type isostructure using the preceding tension anchors, and does not perform a separate rock drilling or excavation work on the underwater rock formed in the river or the sea, and makes the most of the original underwater rock shape, New advances that can reduce the process at sea by minimizing contact with the sea, eliminating processes at sea such as concrete casting, and instead fabricating the structure in advance on land and then assembling the structure at sea. The present invention relates to pile deck type iso structures using tension anchors.

In order to achieve the above object, the present invention is installed in the underwater rock anchorage perforated to a certain depth in the ground of the underwater rock is fixed between the surface structure and the ground to restrain the ground structure through the resistance or resistance to the ground through the restraint or preceding load An anchor portion for applying a; A base having a support column shape mounted on the underwater arm; In the state in which the anchor portion and the base portion are installed in the underwater arm, to provide a pile deck structure using a preceding tension anchor, characterized in that it comprises a deck plate installed on it to serve as a medium for directly supporting the isopja do.

Back structure, underwater rock, anchor part, base part, deck plate part

Description

Pile-deck type Light Beacon Structure with Prestressed Anchor}

The present invention relates to a pile deck type isostructure using the preceding tension anchors, and more specifically, when installing the isotop on the underwater rock formed in the sea or river, it does not perform a separate rock drilling work on the underwater rock, The present invention relates to a piled deck structure using a leading tension anchor to install a table using the shape as much as possible.

In general, when the lamp is to be installed in the underwater rock, a position suitable for installing the lamp is preferentially selected, and a part of the underwater rock is cut off by excavation at the selected lamp mounting position.

A tubular caisson is installed in the vertical direction on the top of the submerged underwater arm.

After the caisson (Caisson) is installed on the underwater rock as described above, a plurality of tubular caisson (Caisson) is installed on the top of the caisson, the caisson located on the top is installed to be exposed higher than the sea level.

Then, if the concrete is inserted into the water after installing the reinforcing bar including the H-beam inside the top of the caisson (Caisson), the bottom surface of the back surface can be formed.

At this time, the bottom surface of the back surface is not filled with all the underwater concrete in the interior of the caisson (Caisson) is located at the top, the water is put into the concrete so that the empty space of about 2 to 3m is formed on the upper side, At the bottom of the backlit space where space is formed, the backrest made on land is built.

The concrete is poured into the empty space of the bottom surface of the lamp, and the lower part of the lamp is fixed by the concrete to be poured to complete the work of installing the lamp on the underwater rock.

However, such a prior art installation method of the dung table has a problem that the work is difficult and the precision is reduced because the submersible to submerge the underwater rock to cut the underwater rock using a rock drill.

In addition, not only the parts needed to rock the underwater rock is rocked, but also the rocking of the surrounding rock is broken according to the condition of the underwater rock is excessively generated because the excessive scour phenomenon occurs because the reef is conducted In addition to the frequent occurrence of the phenomenon, the rocking part is not rocked flatly in the form of caisson insertion, but is unevenly rocked, which makes it difficult to install the caisson and the rocking work on the upper part of the rock. There are various problems such as the weakness of rock support and weakness of support after installation, and the high cost of construction because it takes a lot of work time and manpower.

Referring to the attached structure of FIG. 5 with reference to the accompanying drawings as follows.

As shown in FIG. 5, the underwater rock is excavated, and a large excavation surface 210 is formed in the underwater rock 200 by the rock drilling operation by the diver, and the excavation surface 210 is formed on the excavation surface 210. In the case where the caisson 100 is provided in the drawing, the excavation surface 210 is formed on the outer circumference of the caisson 100.

In addition, after rocking the underwater rock 200 as described above, a separate treatment operation is required to remove the residue from the water, and thus a lot of construction costs are required. As it has various problems such as adversely affecting marine ecosystems, urgent countermeasures are required.

Therefore, the present invention has been invented to solve the above problems, and does not perform a separate rock drilling work or excavation work on the underwater rock formed in the river or the sea, and at the same time maximize the use of the original underwater rock form, underwater rock Minimize the contact point with the water, eliminate the process in the sea, such as concrete placing, instead of making the structure in advance on the land and then assembling the structure in the sea to reduce the process in the sea To provide a pile deck isostructure using anchors.

In order to achieve the above object, the present invention is installed in the underwater rock anchoring portion 21 perforated to a specific depth in the ground of the underwater rock 20 is fixed between the table top structure 10 and the ground to resist the ground An anchor portion 11 for applying a restraining force or a preceding load to the back structure 10 through; A base 12 having a support column shape mounted on the underwater arm 20; It is characterized in that it is configured to include a deck plate portion 13 is installed on the base portion 12 as a medium for directly supporting the table.

In a preferred embodiment, the anchor portion 11 is a head (11a) for fixing to the deck plate portion 13, a steel wire tension portion (11b) extending to a constant diameter long in the head (11a), and the head At the end of the steel wire tensioning portion 11b in the direction corresponding to 11a, the diameter of the steel wire tensioning portion 11b is formed larger than that of the rod fixing portion 11c fixed to the underwater rock anchoring portion 21. The coating member 11d surrounding the steel wire tension portion 11b exposed to seawater is further included.

In addition, the surface of the subsea 20 is flattened by grinding (grinding) so that the base 12 can be upright perpendicular to the subsea 20.

The deck plate portion 13 is provided with a through hole anchor fixing portion 13a and a groove-shaped pillar fixing portion 13b so that the anchor portion 11 and the base portion 12 are mounted in place. It features.

The anchor portion 11 is inserted into the anchor fixing portion 13a of the deck plate portion 13 so that the head portion 11a is fastened and fixed through the fixing member 11e.

As seen above, according to the pile deck-type structure using the preceding tension anchor according to the present invention, it is possible to install the structure of the back to the underwater rock without a separate excavation or rock drilling work to damage the underwater rock, scour problem, etc. In addition to preventing, there is an effect that can minimize the destruction of aquatic ecosystems.

In addition, as a structure to apply the preceding load by the anchor, there is an effect that can be applied economically by reducing the upper load by that much.

In addition, the construction of the land by reducing the proportion of offshore construction is easy to construction, there is an effect that can reduce the cost.

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

1 is a view showing the installation state of the pile deck-type isotopic structure using the preceding tension anchors according to the present invention, Figures 2a to 2d is an installation process of the pile deck-type etc. structure using the preceding tension anchors according to the present invention It is a figure which shows.

In addition, Figure 3 is a plan view showing a pile deck type isometric structure using a preceding tension anchor according to the present invention, Figure 4 is a plan view showing another embodiment of a pile deck type isometric structure using a preceding tension anchor in accordance with the present invention.

The present invention eliminates the process in the sea, such as concrete casting, and instead of the process in the sea using a pre-cast concrete method of manufacturing the structure in advance on the land and then assembling the structure at sea It is a piled deck iso structure using a new leading tension anchor that can be shrunk.

To this end, the present invention, as shown in Figure 1, anchoring the barge adjacent to the underwater arm 20, using the heavy equipment mounted on the barge to support the table at the position where the table is to be installed The structure 10 is to be installed, first, in order to install the anchor portion (11) to perform a drilling operation to drill a hole in the surface of the underwater arm (20).

The drilling operation for the underwater arm 20 is to perform the drilling for the underwater arm 20 by using a separate pressing means installed in the heavy equipment.

As shown in FIG. 2A, after all the perforations are made in the ground of the underwater rock 20 to a specific depth, the anchor portion 11 is inserted into the underwater rock anchoring portion 21 generated by the perforation. The portion 11 is pressed downward toward the lower portion of the underwater arm 20 so that a plurality of the portions 11 are continuously positioned at the corresponding positions so as to coincide with the positions of the through-hole anchor fixing portions 13a formed in the deck plate portion 13 to be described later. Is installed.

Since the anchor portion 11 installed in the ground of the underwater arm 20 has a diameter relatively smaller than the diameter of the underwater arm anchoring portion 21 perforated in the underwater arm 20, the anchor portion 11 and Separate reinforcement work is required for the spaced space between the underwater rock anchoring portion 21.

In this way, the anchor portion 11 installed on the underwater arm 20 is fixed to the back surface structure 10 and the ground by the frictional resistance or acupressure resistance with the ground in the transverse direction or vertical direction to the back structure 10 By applying the restraint force or the preceding load of to ensure the stability of the back structure 10, and to minimize the deformation of the surrounding ground by pre-stress (pre-stress).

In this way, when the anchor portion 11 is applied to the subterranean rock anchoring portion 21 in order to apply the preceding load to the ground of the underwater rock 20 and introduce pre-stress in the vertical direction, the structure 10 There is a difference from the simple support member in that it is fixed by applying a tensile force in advance in order to reduce the displacement of.

Therefore, the anchor portion 11 is important to secure a large resistance to the draw, and for this purpose, the rod fixing portion 11c formed at the end of the anchor portion 11 must be firmly mounted in the ground.

Although not shown in the drawings, the anchor portion 11 is typically composed of a circular inner rod formed of steel and a hollow circular outer tube coupled to an outer side of the inner rod.

The inner rod has a head 11a for fixing to the deck plate portion 13, which is the back mark structure 10, a steel wire tension portion 11b extending at a constant diameter from the head 11a, and the head 11a. The diameter of the steel wire tension portion 11b in the direction corresponding to the larger than the steel wire tension portion 11b is formed as a rod fixing portion (11c) is fixed to the underwater rock anchoring portion (21).

The head portion 11a is a portion for transferring the intensive stress generated in the table structure 10 to the steel wire tension portion 11b without difficulty, and using the fixing member 11e composed of a fixing nut or the like. It is fixed to the structure 10, that is, the deck plate portion (13).

To this end, the head 11a has a male screw part (not shown) for fastening to a nut on its outer circumference.

The anchor portion 11 configured as described above is configured to cover the steel wire tension portion 11b exposed to seawater through the coating member 11d to prevent corrosion, and to prevent corrosion directly on the steel wire tension portion 11b. Will be coated for.

On the other hand, a preferred embodiment of the present invention includes a base portion 12 consisting of a plurality of support pillars mounted on the underwater arm 20 to be installed, as shown in Figure 2b, the base portion (12) is a reinforced concrete support column or steel pipe using a pre-cast method that is produced in a suitable size in advance in a factory on land, alternately arranged alternately with the anchor portion 11, a plurality of decks are installed It is continuously installed in the corresponding position so as to match the position of the column fixing part 13b formed in the plate part 13.

Here, the appropriate size of the base portion 12 is the installation surface and the deck plate portion of the underwater arm 20 in advance using a surveying device before installing the base portion 12 on the underwater arm 20 It is a size which measured the height between 13 and designed the height of the appropriate base part 12, and is made beforehand on the land through this pre-design work.

Unlike the anchor fixing part 13a, the column fixing part 13b of the deck plate part 13 in which the base part 12 is positioned indicates the mounting position of the base part 12 which is not a through-hole shape. The base portion 12 has a recess shape larger than the shape of the upper end surface, and the base portion 12 is configured to support the deck plate portion 13 in the correct position between the anchor portion (11).

On the other hand, the bottom surface of the base portion 12 is smoothed by grinding (surface) the surface of the underwater arm 20 so that it can be installed on the underwater arm 20, the base portion 12 is underwater It is possible to stand upright in the vertical direction on the arm 20.

At this time, the base portion 12 is the upper end of the base portion 12 is also mounted horizontally so that the deck plate portion 13 to be described later to be mounted horizontally, the length is the shape of the underwater arm 20 According to each other is formed.

That is, even if the bottom surface of each base portion 12, which is a base thereof, is arranged at any position of the underwater arm 20 so that the lamps can be installed horizontally on the underwater arm 20, the top surfaces thereof are horizontal to each other. Will be achieved.

By the way, when a step occurs because the top surface of the base portion 12 is not horizontal, the steel plate having a predetermined thickness is inserted into the bottom portion of the base portion 12 to reinforce or the top portion of the base portion 12. The base portion 12 is leveled by mounting a reinforcement portion 12a such as a height variable stage such as a screw jack for changing the height.

As described above, in the state where the anchor portion 11 and the base portion 12 are installed in the underwater arm 20, as shown in FIGS. 3 and 4, a horizontal cross section for directly supporting the isomark is circular. Alternatively, the deck plate portion 13 having a quadrangular shape is placed horizontally on the top surface of the anchor portion 11 and the base portion 12 (see FIG. 2C).

Here, the anchor fixing portion 13a and the pillar fixing portion 13b formed in the circular or rectangular deck plate portion 13 are formed in close proximity to the edge surface of the deck plate portion 13 to each anchor. The distance between the fixing part 13a and the pillar fixing part 13b becomes the maximum separation distance.

This is because the support range for the underwater arm 20 of the anchor fixing portion (13a) and the column fixing portion (13b) is widely distributed, so that the top structure 10 located on the upper side is installed more stably.

Thus, the anchor fixing portion 13a in the state in which the anchor portion 11 and the base portion 12 are positioned in the anchor fixing portion 13a and the pillar fixing portion 13b formed in the deck plate portion 13. After fixing the anchor structure 11 by connecting the anchor portion 11 to the preceding load (10), and then fastening the fixing nut to the head (11a) of the anchor portion (11).

As described above, in the state in which the structure of the back structure 10 is completed, as shown in FIG. 2D, the work is completed by separately installing the top of the back structure 10 exposed on the water surface.

On the other hand, in the preferred embodiment according to the present invention, after the base portion 12 is installed in water, a method of mounting the deck plate portion 13 thereon has been introduced, but the base portion 12 and the deck plate portion 13 ) Can be manufactured in one piece in advance in the land and then installed directly on the underwater rock at the site.

Accordingly, the anchor portion 11 and the base portion 12 are supported on the ground of the underwater arm 20, and the deck plate portion 13 is spaced apart from the underwater arm 20 in the anchor portion 11. And when fixed on the base portion 12, it is possible to solve problems such as scour and excessive wave pressure by the caisson that is previously installed in contact with the underwater arm 20.

In particular, it is possible to reduce the proportion of the offshore construction through the on-shore manufacturing of the top structure 10, it is possible to reduce the cost accordingly.

Although the above has been shown and described with respect to the preferred embodiments of the present invention, the present invention is not limited to the above-described embodiment, in the technical field to which the present invention pertains without departing from the spirit of the invention as claimed in the claims. Various modifications can be made by those skilled in the art, and such changes are within the scope of the appended claims.

1 is a view showing the installation state of the pile deck type isometric structure using the preceding tension anchor according to the present invention,

2a to 2d is a view showing the installation process of the pile deck type surface structure using the preceding tension anchor according to the present invention,

3 is a plan view showing a pile deck type isostructure using the preceding tension anchors according to the present invention;

Figure 4 is a plan view showing another embodiment of the pile deck type isometric structure using a preceding tension anchor in accordance with the present invention,

5 is a view showing an installation state of a conventional back structure.

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

10: mark structure 11: anchor part

12: foundation 12a: reinforcement

13 deck plate portion 13a: anchor fixing portion

13b: column fixing portion 20: underwater arm

21: submersible anchorage

Claims (9)

It is installed in the underwater rock anchoring portion 21 perforated to a specific depth in the ground of the underwater rock 20 to fix the back structure 10 and the ground to restrain the lead structure 10 through the resistance with the ground. An anchor portion 11 for applying a load; A base 12 having a support column shape mounted on the underwater arm 20; It is installed on the base portion 12 and serves as a medium for directly supporting the table, the anchor portion 13a of the through-hole shape so that the anchor portion 11 and the base portion 12 is mounted in place; Pile deck type isometric structure using a preceding tension anchor, characterized in that it comprises a deck plate portion 13 having a columnar fixing portion (13b) of the groove shape. The method of claim 1, wherein the anchor portion 11 A head 11a for fixing to the deck plate portion 13; A steel wire tension portion (11b) extending from the head (11a) to a constant diameter long; Rod fixing portion 11c fixed to the underwater arm anchoring portion 21 having a larger diameter than that of the steel wire tensioning portion 11b at an end portion of the steel wire tensioning portion 11b in a direction corresponding to the head 11a. ; And Pile deck type isometric structure using a preceding tension anchor, characterized in that it comprises a coating member (11d) surrounding the steel wire tension portion (11b) exposed to sea water. 2. The preceding tension anchor as claimed in claim 1, wherein the surface of the underwater arm 20 is flattened by grinding so that the foundation 12 can be erected perpendicularly to the underwater arm 20 in a vertical direction. Piled deck iso structures. The method according to claim 1 or 3, When the base portion 12 is not horizontally aligned with the top surface, when the step occurs, the reinforcing portion 12a is installed on the base portion 12 where the step is generated so that the level can be leveled. Pile deck etc. delete The method of claim 1, The anchor part 11 is inserted into the anchor fixing part 13a of the deck plate part 13 so that the head part 11a is fastened and fixed through the fixing member 11e. Equation structure. The method of claim 6, The head (11a) is a pile deck-type structure using a leading tension anchor, characterized in that the outer threaded portion for processing the tightening nut. The method of claim 1, The anchor fixing portion (13a) and the column fixing portion (13b) is a pile deck structure using the preceding tension anchors, characterized in that arranged in succession alternately alternately along the circumference of the deck plate portion (13). The method according to claim 1 or 8, The anchor fixing portion (13a) and the column fixing portion (13b) is a pile deck type using a preceding tension anchor, characterized in that formed close to the edge surface of the deck plate portion 13 so that the gap between them is maximized Isometric structure.

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