KR101739699B1 - Construction Method Of Geomembrane Core Rockfill Dam - Google Patents

Abstract

The present invention relates to a construction method of a core rockfill dam using a waterproof sheet and, more specifically, to a construction method of a core rockfill dam using a waterproof sheet which lays a waterproof sheet in a dam body in a zigzag shape without forming a separate core zone, and repeats dam body soil compaction and heat fusion adhesion between waterproof sheets to improve constructability and watertightness. According to a proper embodiment of the present invention, the construction method of a core rockfill dam using a waterproof sheet comprises: (a) a step of excavating in a reversed trapezoidal cross section to form an inclined surface on an upstream side and a downstream side to form a foundation unit; (b) a step of laying a waterproof sheet on the inclined surface of the downstream side; (c) a step of building with a building material in a prescribed thickness to form an upward inclined surface towards the upstream side of an upper portion of the inclined surface of the foundation unit to form a first layer; (d) a step of laying a waterproof sheet on the inclined surface of the first layer and fuse the waterproof sheet into the waterproof sheet previously laid below; (e) a step of building in a prescribed thickness to form an upwards inclined surface towards the downstream side on an upper end of the inclined surface of the first layer to form a second layer; (f) a step of repeating steps (b) to (d) to lay waterproof sheets in a zigzag shape in steps to construct a layer of a required height; and (g) a step of building the building material on an upper portion of an uppermost layer to finish.

Description

Technical Field [0001] The present invention relates to a method of constructing a core-type rock-fill dam using a water-

The present invention relates to a method of constructing a core-type lock-fill dam using an aqueduct sheet, and more particularly, to a method of constructing a corrugated rock- To a method of constructing a core-type lock-fill dam using an aqua regenerated sheet which improves workability and water-tightness by repeating fusion bonding.

The global efforts to reduce construction costs and shorten the construction time in the construction of the dam continued to result in various technological developments in the dam type and construction method.

Concrete dams and fill dams have been developed as composite dams where the merits of each type are fused. The concrete dams and fill dams are improved by using the characteristics of the damping materials, so that RCC, RCD , Hardfill Dam construction method and ACRD construction method.

In addition, the ICOLD has continuously developed a Geomembrane Sealing Systems Dam (GSSD) in 1981 by Bulletin 38, Bulletin 78 of 1991, and Bulletin 135 of 2010, I am suggesting. In addition, the surface carmount material of such a dam is concrete. Asphalt, iron plate, PVC and HDPE are used. Concrete Face Rockfill Dam (CFRD) and Asphalt Face Rockfill Dam (AFRD) are known to be mainly used. However, As a result, there are 265 dams around the world in the case of dams based on geomembrane, and materials and construction methods are continuously improving.

However, the surface dam type dam is complicated in construction and is not easy to stabilize the surface. In addition, the core material is mainly used in clay when the existing core type fill dam is applied, but it is difficult to secure the clay.

As a background of the present invention, there is a patent registration No. 1570939 entitled " Asphalt core fill dam where a core zone is formed by using a corrugated index material "(patent document 1). The core zone 1 is formed at the center between the upstream and downstream sides of the dam body 2 and the transition zone 3 is formed on both sides of the core zone 1. In the core zone 1, Like index material 10 having a constant vertical waveform is formed between the core zone 1 and the transition zone 3. The core zone 1 is formed of a core made of a low strength asphalt concrete, And the curtain grouting 60 is formed by grouting the expanded concrete 50 at a predetermined depth below the exponent concrete 50. The curtain grouting 60 is formed by the ash concrete 20, Asphalt core filler dam with a core zone formed using a corrugated exponent.

However, the background art has a problem that the construction method is complicated and the construction cost and the construction period are increased.

Patent No. 1570939 entitled "Asphalt core fill dam in which core zone is formed using corrugated index material"

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems described above, and it is an object of the present invention to provide a method of manufacturing a steel sheet, in which an aisle sheet is disposed in a zigzag form inside a steel sheet without forming a separate core zone, It is possible to improve the workability and the watertightness by improving the workability and the watertightness of the core material. Further, by using the water-absorbing sheet which can be easily supplied to the core material, the core material does not require a separate clay, The present invention provides a method of constructing a core-type lock-fill dam using an aqua regenerable sheet that can reduce the collection and transportation costs, thereby securing constructability and economy.

The present invention provides a method of manufacturing a steel plate, comprising the steps of: (a) excavating a steel plate having an inverted trapezoidal cross-section so as to form an inclined surface on an upstream side and a downstream side, respectively, (b) laying an aisle sheet on a downstream side slope; (c) forming a first layer having a predetermined thickness with a building material so as to form an upward inclined surface from an upper part of the inclined surface of the foundation part to an upstream side; (d) laying an aisle sheet on an inclined surface of the first layer and fusing the same with the underlying aisle sheet; (e) forming a second layer with a predetermined thickness so as to form an upward sloping surface from the upper end of the sloped surface of the first layer to the downstream side; (f) repeating the steps (b) to (d) so as to lay the order sheet stepwise in a zigzag shape to construct a layer having a required height; (g) constructing and finishing a building material on top of the uppermost layer to provide a core-type lock-fill dam construction method using the water-receiving sheet.

The present invention also provides a method of constructing a core-type lock-fill dam using the water-receiving sheet, wherein the water-receiving sheet is installed in a lateral direction of the body.

The method for constructing a core-type lock-fill dam using an aqueduct sheet according to claim 1, wherein after step (g), a water-receiving sheet is laid on an inclined surface on the upstream side of the body and a concrete mat formed on the water- .

The concrete mat of the aquifer is composed of a cement mixture and a nonwoven fabric formed respectively at the upper and lower portions of the cement mixture and is formed so as to solidify the water after spraying the concrete mat. To provide a method of constructing a fill dam.

The core type lock-fill dam construction method using the water-sheeting sheet of the present invention allows the water-sheeting sheet to be disposed in a zigzag form in the interior of the body without forming a separate core zone, And it is possible to improve the workability and the watertightness of the clay by improving the workability and the watertightness of the clay by using the water-absorbing sheet which is easily supplied to the core material, It is possible to reduce material collection and transportation costs, so that it has a very useful effect of securing workability and economy.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention, Shall not be construed as limiting.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side cross-sectional view showing a core type lock-fill dam construction method using the water-receiving sheet of the present invention in the order of construction.
2 is a view showing another embodiment of a lock-fill dam constructed by a core-type lock-fill dam construction method using the water-receiving sheet of the present invention.
3 is a perspective view of a base portion showing an embodiment of a method for laying an aisle sheet in a core type lock-fill dam construction method using the water-in-oil sheet of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

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

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side cross-sectional view showing a core type lock-fill dam construction method using the water-receiving sheet of the present invention in the order of construction.

As shown in FIG. 1F, the rock-fill dam constructed by the method of constructing the core-type lock-fill dam using the water-receiving sheet of the present invention does not have a separate core zone or the like inside the body 10, (L 1, L 2,... Ln) in a zigzag manner so as to compose the embedding of each layer layer and repeat the heat fusion bonding between the water receiving sheets 20 Thereby improving the workability and watertightness.

First, as shown in FIG. 1A, a base 11 is formed on a water bottom surface where a dam is installed (a).

The base portion 11 can be formed by being formed in an inverted trapezoidal cross section so that the inclined surfaces 111 and 112 are formed on the upstream side and the downstream side, respectively, so that the watertightness at the foundation of the lower portion of the body can be improved.

In addition, the downstream side inclined surface 112 is formed for zigzag laying the water receiving sheet 20 so that the foundation 11 is formed at a certain depth.

Thereafter, as shown in Fig. 1B, the aeration sheet 20 is installed on the downstream side inclined surface 112 (b).

The water receiving sheet 20 is laid on the whole of the downstream side inclined surface 112 and the upper end of the water receiving sheet 20 is further projected from the inclined surface 112 so as to be horizontally finished so that the water receiving sheet 20, To facilitate fusion bonding.

The water receiving sheet 20 may be formed of a polyethylene resin mat, a geomembrane mat, or the like having an order performance. The water receiving sheet 20 may be formed to have a high degree of strength and tensile force A separate wire may be formed.

1C, the first layer L1 is formed to have a predetermined thickness with the substrate material so that the upward inclined surface S1 is formed upstream of the inclined surface 112 of the base portion 11 c).

As shown in the figure, a base material 11, a molding material such as sand, gravel and rock is stacked on the upper part of the base part 11 to have a predetermined thickness, and the base part 11 has a downstream side inclined surface 112, So as to form an upward sloping surface S1 from the upper end to the upstream side.

Thereafter, as shown in FIG. 1D, the sheet 20 is laid on the sloped surface S1 of the first layer L1 (d).

The water receiving sheet 20 to be laid on the inclined surface S1 of the first layer L1 is formed so as to be continuous with the water receiving sheet 20 laid on the downstream side inclined surface 112 of the base portion 11, And the upper end of the first layer L1 is further projected upward from the upper end of the inclined face S1 of the first layer L1 so as to be horizontally finished, Thereby facilitating fusion.

Then, as shown in FIG. 1E, the second layer L2 is formed by constructing the building material to a predetermined thickness (e).

The second layer L2 is formed to have a predetermined thickness so as to form an upward sloped surface S2 from the upper end of the sloped surface S1 of the first layer L1 to the downstream side.

Therefore, the inclined plane 112 on the downstream side of the base 11 and the inclined plane S1 of the first layer L1 and the inclined plane S2 of the second layer L2 are zigzag.

Thereafter, steps (b) to (d) are repeated to place the water receiving sheet 20 in a zigzag fashion so as to construct the layers L1, L2, ..., Ln of a required height.

The layers L1, L2, ..., Ln are formed stepwise so that the inclined surfaces of the respective layers are staggered so as to form a material having a required height, and the layers L1, L2, ..., Ln are staggered on the inclined surfaces S1, (G), the joining portion is fused while the joining portion 20 is laid on the uppermost layer Ln. Then, the joining material is formed on the uppermost layer Ln and finished.

3 is a perspective view of a base portion showing an embodiment of a method for laying an aisle sheet in a core type lock-fill dam construction method using the water-in-oil sheet of the present invention.

Since the width of the water receiving sheet 20 is generally 7.0 m in the case of a base product, the connecting portions between the water receiving sheets 20 should be fused to each other at the time of installation in the longitudinal direction of the body, as shown in Fig. Therefore, in the present invention, as shown in Fig. 3 (b), if the water-distributing sheet 20 is provided in the lateral direction of the body, the lateral direction of the body can be laid all at once without connection.

2 is a view showing another embodiment of a lock-fill dam constructed by a core-type lock-fill dam construction method using the water-receiving sheet of the present invention.

The water layer 30 may be further formed on the upstream side inclined surface of the body 10 after the completion of the step (g).

2, a water receiving sheet 31 is disposed on the upstream side inclined surface of the body 10 and a concrete mat 32 is disposed on the water receiving sheet 31 to form the water receiving layer 30, So that the surface of the upstream side inclined surface of the body 10 can be primarily arranged.

The aeration sheet 30 is made up of a concrete mat 32 that is placed on the upper side of the aeration sheet 31. The aeration sheet 31 is placed outside the slope on the upstream side and is made of polyethylene A resin mat, a geomembrane mat, or the like so as to impart an order performance to an inclined surface, and a separate wire may be formed in the interior to have high strength and tensile strength.

A concrete mat (32) is installed on the water-receiving sheet (31) to ensure the watertightness and durability of the body (10).

The concrete mats 32 may be formed of a mixture of a cement mixture 321 in a dry state and a cement admixture 321 in a dry state, And a nonwoven fabric 322 formed on upper and lower portions of the concrete sheets 321 and 321 so that the concrete mat 32 is laid outside the water sheet 31 on the inclined surface of the body 10, Water may be sprayed from the outside of the mat 32 to hydrate and solidify the cement mixture 321 in the concrete mat 32.

If the concrete mat 32 is constructed using the cement mixture 321 in a dry state, it is very easy to manufacture in the factory and can be installed in the same manner as the mat in the field, and the surface of the water- So that it is easy to construct and can be solidified by simply spraying water, so that the construction period can be greatly shortened.

Such an aqueduct layer 30 may be formed only on the inclined surface of the body 10 but may cause problems such as lowered durability due to exposure of the upper end. The aeration layer 30 may be embedded.

In the method of constructing a core-type lock-fill dam using the water-receiving sheet of the present invention as described above, the water-receiving sheet is placed in a zigzag form inside the body without forming a separate core zone and the heat- In addition to the effect of improving the workability and the watertightness by providing a water-repellent performance, it is possible to reduce the damage to the surrounding environment by using a water-absorbing sheet which is easily supplied to the core material, And it is possible to reduce the collection cost and transportation cost of existing clay materials, and thus it has a very useful effect of securing the workability and economy.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

10: Formation
11: Foundation
20: Order sheet
L1, L2, ... Ln: Layer
S1, S2, ... Sn: inclined surface
30: an aisle
31: Order sheet
32: Concrete mat
321: Cement admixture
322: Nonwoven fabric

Claims (4)

(a) forming a base portion (11) by drilling an inverted trapezoidal cross section so that slopes (111) and (112) are formed on the upstream side and the downstream side, respectively;
(b) A water-receiving sheet (20) composed of a geomembrane mat on which wires are formed on a downstream side inclined surface (112) of the base part (11) Projecting and horizontally finishing;
(c) forming a first layer (L1) with a certain thickness so as to form an upward sloped surface (S1) upstream of the sloped surface (112) on the downstream side of the base portion (11);
(d) An order sheet 20 made of a geomembrane mat on which wires are formed on the inclined plane S1 of the first layer L1 is installed, and the order sheet 20, which is laid on the slope face 112 on the downstream side of the base portion 11, The upper part and the lower part of the water receiving sheet 20 provided at the lower part of the lower layer are thermally fused so as to be continuous with the sheet 20 and the upper part is further protruded upward from the upper end of the inclined surface S1 of the first layer L1, Laying it down to finish;
(e) The second layer L2 is formed so as to have a predetermined thickness so as to form an upward sloped surface S2 from the upper end of the sloped surface S1 of the first layer L1 to a downstream side, ;
(f) Repeating the steps (b) to (d), the order sheet 20 composed of a geomembrane mat having wires formed therein is stepwise laid in a zigzag form, and a layer L1 , L2, ..., Ln);
(g) constructing and finishing a building material on top of the uppermost layer (Ln). The method according to claim 1,
Wherein the water receiving sheet (20) is installed in a lateral direction of the body (10). The method according to claim 1,
After step (g)
Wherein a water receiving sheet (31) is laid on an upstream side inclined surface of the body (10) and a concrete mat (32) formed on the water receiving sheet (31) is laid to form a water receiving layer Core type rock fill dam construction method. The method of claim 3,
The concrete mat 32 of the aquifer 30 comprises a cement mixture 321 and a nonwoven fabric 322 formed at the top and bottom of the cement mixture 321,
Wherein the water is sprayed and solidified after the concrete mat (32) is installed.

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