KR20080004274U - A compound erosion control dam - Google Patents

Abstract

The present invention relates to a steel and concrete composite four-sided dam and its construction method, and more particularly, to a composite four-sided dam and its construction method that can simultaneously perform the function of blocking the downstream runoff of soil and driftwood.

Composite four-way dam of the present invention and its construction method is concrete four-way dam to capture and load the soil; A drip tray for inducing flowing water from the four dams; And a driftwood membrane disposed on a downstream side of the drip tray to block driftwood, wherein the driftwood membrane structure comprises: a plurality of pillars arranged in two rows perpendicular to the flow direction of the flowing water; And a connecting member connecting the plurality of pillars, wherein upstream columns of the two rows are arranged in a zigzag form and downstream rows are arranged in a straight line, each of the columns of the upstream row and the columns of the downstream row, respectively. The technical feature is that the arrangement includes a one-to-one correspondence.

Description

A compound erosion control dam

The present invention relates to a steel and concrete composite four-sided dam and its construction method, and more particularly, to a composite four-sided dam and its construction method that can simultaneously perform the function of blocking the downstream runoff of soil and driftwood.

By setting up four-sided dams in the valleys of mountains where there is a risk of landslides and upstream rivers where soils and soils are severely lost, landslides are prevented. The conventional four-sided dam construction of the steel aggregate four-sided dam to construct a concrete four-sided dam made of reinforced concrete walls or a box-shaped unit assembly made of steel in the form of a dam, and to load a stone or the like to increase the weight and drainage effectively Was implemented. These dams are effective in preventing the outflow of sedimentary rocks, but the trees flowing down during the landslides flowed down with the water, causing damage to the small bridges around the village.

In order to prevent such damages, buttresses are installed upstream of concrete concrete dams to block driftwood. However, by constructing two types of four-side dams at the limit, such as a valley, waste of time and money was added.

As described above, when the driftwood structure is installed in the related art, there has been a problem of installing a four-sided dam.

In addition, in the conventional driftwood structure, driftwood can be accumulated from an upstream support, even if only a little driftwood is accumulated, there is a high possibility that the stacked driftwood falls over the structure, and the load is concentrated only on a part of the structure so that the driftwood structure can be easily damaged. There was a problem.

The present invention devised to solve the problems of the prior art as described above is an object of the present invention to provide a combined four-way dam that can perform the function of blocking the flow of drift downstream and block the driftwood at the same time.

Another object of the present invention is to provide a complex four-sided dam and its construction method that can significantly reduce the construction period and its cost.

Another object of the present invention is to provide a combined four-sided dam having a driftwood film structure that can increase the amount of driftwood loaded, and distribute the load.

The object of the present invention is a concrete four-side dam to capture and load the soil; A drip tray for inducing flowing water from the four dams; And a driftwood membrane disposed on a downstream side of the drip tray to block driftwood, wherein the driftwood membrane structure comprises: a plurality of pillars arranged in two rows perpendicular to the flow direction of the flowing water; And a connecting member connecting the plurality of pillars, wherein upstream columns of the two rows are arranged in a zigzag form and downstream rows are arranged in a straight line, each of the columns of the upstream row and the columns of the downstream row, respectively. Is achieved by a combined four-way dam arranged in a one-to-one correspondence.

Another object of the present invention is to construct a drip tray after laying a concrete four-side dam, the step of constructing the foundation for the driftwood structure, the step of installing a fixing anchor for fixing the structure of the driftwood on the foundation and placing the foundation concrete The externally produced driftwood film is achieved by a complex four-sided dam construction method comprising assembling the structure to a fixing anchor and placing the plain concrete on the foundation concrete.

In the composite four-sided dam according to the present invention, the column and the connecting member may be formed of any one or a combination of two or more of cylindrical steel, H-beam steel, and square bar steel.

Therefore, the combined four-sided dam and the construction method of the present invention can perform the function of blocking the downstream runoff of the earth and the driftwood at the same time, the structure and construction method is simple, and the existing facilities can be used as it is There is an advantage that can significantly reduce the time period and its cost.

The driftwood barrier structure of the combined four-sided dam according to the present invention has an advantage of increasing the amount of driftwood loaded and distributing the load.

1 is a view showing the role of the combined four-sided dam in accordance with the present invention,

2 is a perspective view of a combined four-sided dam in accordance with the present invention;

Figure 3 is a perspective view of the driftwood barrier structure of the composite four-way dam in accordance with the present invention.

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

10: flowing 20: driftwood

30: earth and sand 100: concrete dam

200: driftwood structure 210: downstream pillar

220: quadrilateral column 230, 250: coupling portion

260: beam 270: vertical column

300: drip tray 310: side wall

320: drip bottom

The terms or words used in this specification and claims are not to be construed as limiting in their usual or dictionary meanings, and the inventors may appropriately define the concept of terms in order to best describe their own design. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention on the basis of the principle of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical ideas of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

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

1 and 2 is a conceptual diagram of a combined four-sided dam in accordance with an embodiment of the present invention.

The concrete four-side dam 100 may be configured in the same structure as in Figure 2, it may be used a conventional four-sided dam. That is, the concrete four-way dam 100 of the composite four-way dam according to the present invention has the advantage that it can use the existing four-way dam as it is. Referring to FIG. 1, when the flood occurs, the concrete four-side dam 100 prevents the earth and sand 30 from descending downstream. However, when the concrete four-way dam 100 overflows, the driftwood 20 such as timber floating over the flowing water 10 can be over the concrete four-way dam 100.

Drip 300 is a place that serves to collect the flow of the flowing water 10 over the concrete four-side dam 100 is composed of a drip bottom 320 and the side wall 310. The width of the structure narrows toward the downstream direction, and the driftwood installed downstream of the drip tray 300 has an angle narrowed according to the width of the structure 200 and the distance between the concrete four-side dam 100 and the driftwood structure 200. Different. In general, the side wall 310 of the drip tray 300 may be formed of concrete, but the bottom of the drip tray 320 may be left in its natural state or may be formed of concrete. If the structure of the valley to install the composite four-way dam is a structure that can replace the dripsing portion 300, without using the drips 300 to use the natural state of the valley as it is or the dripsing portion 300 through a slight reinforcement work You can also complete

Driftwood block structure 200 is located downstream of the drip tray 300, to reduce the flow rate of flowing water 10 collected in the drip tray 300 overflowed from the concrete specification dam 100, as shown in Figure 1, floating driftwood Prevent (20) from going downstream. The driftwood structure 200 of the present invention may have a structure such that the structure shown in FIG. 3 extends in the direction in which the beam 260 extends as shown in FIG. 2, and the width thereof is determined according to the width of the valley or the like.

3 is a schematic diagram showing the unit structure of the driftwood membrane structure 200.

The pillars 210, 220, and 270 fixed to the floor in the structure 200 are arranged in two rows in a direction perpendicular to the flow of the flowing water. Upstream of the two rows arranges the pillars 220 and 270 in a zigzag form such as v and w, and downstream columns arrange the pillars 210 in a row. In the upstream row, a quadrilateral column 220 inclined in the downstream direction is disposed in a portion corresponding to the mountain of the zigzag, and a vertical column 270 is almost vertically disposed in the portion corresponding to the valley of the zigzag. It is desirable to be. The downstream column 210 is disposed in the downstream column, the upper side of which is inclined in the upstream direction. At this time, the downstream pillars 210 are disposed at positions corresponding to the vertical pillars 270 or the quadrilateral pillars 220.

A connecting member comprising a beam 260 placed between the pillars 230 in a direction perpendicular to the flow of running water and a plurality of coupling parts 230 and 250 connecting the beams to the pillars connects the upper portions of the pillars to each other. Done. The beam 260 does not necessarily need to be integral, but may be divided into several parts.

The shape of the driftwood membrane structure 200 allows the driftwood that is blocked to be loaded from the inside of the structure 200 driftwood membrane. This will be described with reference to an example in which the upstream columns are arranged in a v shape as shown in FIG. 3. 3, it can be seen that the spacing of each column in the upstream column is wider than the spacing of each column in the downstream column. In addition, the quadrilateral column 220 and the vertical column 270 of the upstream side with respect to the flow direction of the runoff are inclined about 30 to 60 degrees from each other, but the downstream columns 210 of the downstream side have Right angle to

Due to this structure, the driftwood is less likely to span between the quadrilateral pillars 220 or the quadrilateral pillars 220 and the vertical pillars 270 even though the driftwood is relatively large in size. The probability of striking is increased. That is, the driftwood 20 is a driftwood film is naturally stacked from the inside of the structure.

If the driftwood 20 is stacked from the inside of the structure 200, the driftwood 20 may allow the driftwood film to accumulate in the structure 200 without sending more driftwood 20 downstream, and the driftwood film to the structure 200. The loaded load can be evenly distributed on each axis so that the driftwood film increases the durability of the structure 200.

This effect becomes larger when two or more rear supports 210 and pedestals 270 are disposed between each support 210, 220, 230, but the size of each terrain and driftwood, and the driftwood barrier limit the load on the structure. Consideration should be given to proper placement.

Each pillar 210, 220, 270 and the connecting members 230, 250, 270 of the driftwood is made of steel, formed of cylindrical steel, H-beam steel or square bar steel, or a combination thereof. Can be.

The columns, in which the driftwood is fixed to the floor in the structure, are joined by the base concrete structure of the floor and the anchoring anchor, and the plain concrete is placed on the foundation concrete structure to prevent corrosion of the reinforced concrete and the anchor anchor. . The foundation concrete structure is preferably embedded not only in the area where the driftwood supports the structure but also downstream thereof so that the driftwood supports the structure in the downstream direction.

The method of installing such a combined four-sided dam is as follows.

First, a concrete four-side dam is built. The concrete four-sided dam in the composite four-sided dam according to the present invention may be newly constructed, but since the existing facility can be used as it is, the step of building the concrete four-sided dam may be omitted when using the conventional concrete four-sided dam.

Construct the drip trays downstream of the concrete dams. A driftwood membrane is installed in the downstream part of the drip tray for the structure, a fixing anchor is installed on the foundation and the foundation concrete is placed there. Separately constructed driftwood assembles the structure into the anchoring anchor. In the present invention, since the reinforcing structures need not be manufactured in the installation area as described above, only the reinforcing structures manufactured outside are assembled and assembled so that the installation work can be completed very simply.

After the driftwood joins the structure to the anchoring anchor, the bare concrete is placed on the foundation concrete to protect the foundation concrete and anchoring anchor from the risk of corrosion.

The present invention has been shown and described with reference to the preferred embodiment as described above, but is not limited to the above embodiments and those skilled in the art to which the subject innovation belongs within the scope not departing from the spirit of the present invention. Various changes and modifications will be possible.

Claims (5)

Concrete ripple dams that capture and load soil; A drip tray for inducing flowing water from the four dams; And Driftwood block structure that blocks the driftwood located on the downstream side of the drip tray The driftwood structure, A plurality of columns arranged in two rows perpendicular to the flow direction of the flowing water; And Connection member for connecting the plurality of pillars The composite four-side dam of the two rows, the upstream row is arranged in a zigzag form and the downstream row is arranged in a straight shape, each of the columns of the upstream and the columns of the downstream row is arranged one-to-one correspond. The method of claim 1, The four-sided dam is arranged in the zigzag upstream of the column is a quadrilateral column, the vertical column is arranged in the valley. The method of claim 2, wherein the connecting member, Beams arranged vertically in the flowing direction; And Coupling portion connecting the plurality of pillars to the beam Compound four sides dam with. The method according to any one of claims 1 to 3, The pillar and the connecting member is a composite four-sided dam formed of any one or a combination of two or more of the cylindrical steel, H-beam steel and rectangular bar steel. The method of claim 4, wherein the drip tray, Drip bottom; And Sidewall The composite four-sided dam, characterized in that the width is narrow in the downstream direction.