KR20040050955A - Reinforcement structure for dike and constructing method thereof - Google Patents

Abstract

PURPOSE: The construction method for an embankment reinforcing structure is provided to prevent the loss or breaking of soil by external pressure and earth pressure, to have excellent constructability by executing repair and reinforcement works simply, and excellent durability and stability by improving bearing force, and to cut down the expenses by decreasing the manpower and a period of construction. CONSTITUTION: The construction method for an embankment reinforcing structure(10) comprises the steps of: forming a working yard of 3 meters in width and 15 meters in length on an embankment(1); installing many H-beams(11) longitudinally on the upper part of the embankment(1) with an interval of 5 meters to support and guide an embankment reinforcing structure(10), then installing a reinforcing bar(14) having an inner space(15) on the upper part of a structure supporter blade(13); laying reinforcing bars(14) under the embankment(1) by dipping soil, gravel, etc. out through an inner space(15) of the reinforcing bar(14) using a crane clamshell(3); and connecting the buried reinforcing bars(14) mutually along the embankment(1), placing soil, gravel and rubber into the inner space(15) of each reinforcing bar(14) and removing the H-beams(11) installed on the lower part of the embankment(1).

Description

Reinforcement structure for dike and constructing method

The present invention relates to a dike reinforcement structure and a construction method, and more particularly, to embed a reinforcement structure formed in a grid shape inside the dike to make the structure of the dike more robust, and also to improve the fixing property to lose and collapse the dike. The present invention relates to a dike reinforcement structure and a construction method which can reduce construction cost and construction cost by reducing construction personnel and shortening construction period.

In general, dikes are installed to prevent damage to farmland and private houses due to flooding of rivers due to rainy seasons, heavy rains, and typhoons. Such a levee was mainly used for the construction method of finishing the slope by applying a block on the slope after the foundation compaction, the bottom protection construction, the slope road covering construction, and the like.

However, the embankment according to the conventional construction method is difficult to be deformed by external shear that is not easily sheared or not very large because its structure is not strong and its durability is weak, and thus it is not possible to exert its function due to failure and crack of the embankment. have. In addition, because the dike lacks firmness, when the rainwater and sewage seeps, the ground of the entire dike is eroded in series, causing loss and collapse of the dike.

In addition, frequent repairs were required to maintain the function of the dike by repairing the lost or collapsed parts of the dike caused by the inherent failure of the dike, which required a lot of manpower, repair, and maintenance costs. It became.

In addition, if the water is not repaired and reinforced in a timely manner, the banks collapsed due to the rainy season and heavy rains in summer, and rivers flowed into and flooded private and agricultural lands. It causes problems such as financial loss.

The present invention has been made in order to solve the problems as described above, to prevent the loss or collapse of earth and earth by external pressure and earth pressure, easy repair and reinforcement work, excellent workability, improve the bearing capacity, durability and stability The purpose of the present invention is to provide an embankment reinforcement structure and a construction method that can reduce costs by reducing workforce, construction and air.

Figure 1a, 1b is a schematic view showing the construction method of the embankment reinforcement structure according to the present invention,

2 is a plan view showing the embankment reinforcement structure according to the present invention,

Figure 3 is a perspective view showing a structure shoe blade installed in the lower part of the embankment reinforcement structure according to the present invention.

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

1 embankment, 3 clamshell,

10 reinforcing structures, 11 supporting beams,

13, structure shoe blade, 14, reinforcement,

15 space, 17 guide rail,

33 ... bolts, 35 ... nuts.

In order to achieve the object as described above, the present invention forms a predetermined working yard in the upper part of the embankment, a plurality of support beams on the upper surface of the embankment is placed at the bottom of the embankment with a predetermined interval spaced apart in the length of the embankment, After placing the structure shoe blade on the upper working yard of the embankment in the longitudinal direction of the embankment, the reinforcing bar having an internal space is separately constructed on the upper surface of the structure shoe blade, and a space is formed inside the reinforcing bar by a crane clamshell. The reinforcing rods are buried sequentially below the embankment by spreading soil, gravel, and rubble through the banks, and the buried reinforcing rods are interconnected in the lengthwise direction of the embankment. It is a construction method of the embankment reinforcement structure characterized in that the support beam placed in the lower portion is removed.

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

1A and 1B are schematic views showing the construction method of a levee reinforcement structure according to the present invention.

As shown in the drawings, the present invention forms a working yard having a width of 3m and a length of 15m on the top of the embankment (1), the support beam having an H-shaped cross section that can support and guide the embankment reinforcement structure (10) (11) is spaced apart at intervals of 5m in the length direction on the upper surface of the embankment (1) and placed in a plurality of places and laid in the lower part. Next, the reinforcing structure 10 consisting of the structure support blade 13 and the reinforcing table 14 is installed on the upper surface of the embankment (1).

The structure shoe blade 13 is arranged at a predetermined position on the upper side of the embankment 1 so as to be aligned with the inner side of the support beam 11 installed in the downward direction of the embankment 1, A reinforcing bar 14 having a lattice-shaped cross section consisting of one row is provided on the upper surface.

The reinforcing rod 14 is installed by welding the reinforcing bar on the upper surface of the structure shoe blade 13, and reinforces a plurality of reinforcing bar around the upper surface of the structure shoe blade blade 13 , Iron formwork is installed in the periphery and concrete is poured and poured. Then, after curing the poured and injected concrete is formed by dismantling the iron formwork.

Soil and gravel are pumped out to the crane cramshell 3 through the space 15 formed inside the reinforcing structure 10 of the reinforcing structure 10 installed as described above. That is, through the internal space 15 of the reinforcing table 14 installed on the upper part of the embankment 1 by the crane cram shell 3 used for sand collection and other excavation work in rivers, repairs and dredging works, The reinforcement structure 10 is buried under the bank 1 as rubble, soil, and the like are swept away.

At this time, the reinforcing structure 10 is buried in the depth direction on the upper surface of the embankment 1 while being guided and supported in the longitudinal direction to the support beam (11). In addition, while the friction of the outer side is reduced by the structure shoe blade (13) installed in the lower portion of the reinforcing rod 14 is buried in the lower side inside the embankment (1) by the weight of the reinforcing structure (10).

On the other hand, after the reinforcement structure 10 is embedded in the lower part of the embankment 1, rubble, gravel, soil, etc. are buried in the space 15 formed inside the reinforcement 14 of the reinforcement structure 10. Then, the work is completed by removing and removing the support beam 11 installed on the lower part of the embankment 1.

On the other hand, the reinforcing structure 10 is installed by the reinforcing rod 14 is continuously coupled to each other in the longitudinal direction by the fastening means along the length of the embankment (1). This construction step is repeated several times in the longitudinal direction along the length of the dike.

In addition, the reinforcing structure 10 may be constructed by dividing the bottom several times according to the depth of the embankment (1). That is, before reinforcing the reinforcing bar 14 from the upper part of the embankment 1 to the lower part, the reinforcing bars are installed, steel formwork is installed in the periphery thereof, the concrete is poured and cured, and then the lower part of the embankment 1 After buried in, reinforcing the reinforcement to the upper side of the reinforcing structure 10 according to the depth and install the iron formwork and then can be poured after curing by pouring concrete.

As described above, the reinforcing bar 14 is repeatedly installed to a predetermined depth to bury the reinforcing structure 10 from the upper part of the embankment 1 to the position and base surface desired by the contractor. Thus, the reinforcing structure 10 may be constructed by dividing several times step by step depending on the depth of the embankment (1).

Figure 2 is a plan view showing the embankment reinforcement structure according to the present invention, Figure 3 is a perspective view showing a structure shoe blade provided on the lower end of the embankment reinforcement structure according to the present invention.

As shown in the drawings, the embankment reinforcement structure 10 is formed on the upper surface of the wedge-shaped structure shoe blade 13, the grid reinforcement 14 is formed separately, the reinforcement 14 is embankment (1) Are mutually coupled in the longitudinal direction of the () and embedded in the lower part of the embankment (1).

The embankment structure 10 is a reinforcing bar 14, which is separately installed on the upper surface of the structure shoe blade 13 disposed in the longitudinal direction of the embankment (1) to the fastening means such as bolts 33 and nuts 35, etc. By interconnecting in the longitudinal direction of the embankment (1).

As described above, the reinforcing bar 14 of each of the embankment structures 10 is integrally coupled to the upper surface of each structure shoe blade 13, and the reinforcing structure 10 is rubble, soil, The gravel is filled to improve the bearing capacity and fixability against external pressure and external force.

On the other hand, the top of one side of the reinforcing structure 10 is provided with a guide rail 17 protruding outward in the upward direction. That is, one side of the river overflows the top of the reinforcing structure 10 is provided with a guide rail 17 formed to be about 1m higher than the other side.

Thus, the guide rail 17 formed to protrude outward from the upper portion of the embankment 1 contributes to the prevention of safety accidents of the tiller and the vehicle.

The reinforcing structure 10 having the above configuration may be configured in a straight line along the embankment, but may also be configured in a curved shape having an S-shaped curve or curved portion in some cases. That is, the installation shape of the reinforcing structure 10 is adaptively arranged depending on the shape of the bank and the conditions inside and outside the bank.

The present invention having the configuration as described above is to prevent the loss or collapse of the soil by the external pressure and earth pressure, and easy to repair and reinforcement workability, excellent durability and stability, reducing the workforce and construction period It can shorten the effect.

Claims (3)

Create a predetermined working yard at the top of the embankment, On the upper surface of the embankment, the support beam is spaced apart at a predetermined interval in the longitudinal direction of the embankment and poured into the lower part of the embankment, Placing the structural shoe blade on the upper working yard of the embankment in the longitudinal direction of the embankment and separately constructing reinforcement with internal space on the upper surface of the structural shoe blade, By embedding the soil, gravel, rubble through the space formed inside the reinforcement with a crane clamshell, the reinforcement is sequentially buried below the embankment, A method of constructing a levee reinforcement structure, comprising: connecting the buried reinforcement bars in the lengthwise direction of the embankment and then removing the supporting beams installed in the lower part of the embankment after embedding soil, gravel, and rubble in the inner space of each reinforcement arm. A wedge-shaped structure embankment reinforcement structure is provided on the upper surface of the shoe blade blade is provided separately, the reinforcement is configured to be interconnected in the longitudinal direction of the embankment. The method of claim 2, Embankment reinforcement structure, characterized in that the top of one side of the reinforcement structure is provided with a guide rail protruding outward.