KR20190097459A - A bolck-assembly type eco pillar debris barrier and construction method thereof - Google Patents

Abstract

The present invention discloses a block stacking eco pillar debris barrier and a construction method thereof. According to the present invention, the block stacking eco pillar debris barrier has a plurality of hollow pillars constructed into a pillar-shaped structure in a constant arrangement pattern on a concrete foundation layer, wherein the hollow pillar forms a segment by allowing a plurality of unit hollow pillar blocks manufactured by precast concrete to be stacked in order so that a plurality of penetration holes penetrating an upper end and a lower end of a cylindrical body are arranged in a ring shape. The present invention has a structure of being constructed to form an integral structure by a connection reinforcing part formed by a grouting material filled so as to surround a steel bar inserted into the penetration hole of each unit hollow pillar block as a prestress tendon and surroundings thereof. Therefore, the block stacking eco pillar debris barrier and the construction method thereof are economic through improvement of construction efficiency and shortening of a construction period.

Description

A bolck-assembly type eco pillar debris barrier and construction method

The present invention relates to an eco-pillar all-round dam and its construction method, and more specifically, the unit hollow pillar block made of precast (PC) concrete is sequentially laminated to a concrete foundation layer cast on the ground. It relates to a block-layered eco-pillar square dam constructed by the construction and its construction method.

In recent years, as the frequency and intensity of sudden localized torrential rains caused by the effects of climate change due to global warming increase, the number of cases of earthquake damage is increasing and the size is increasing, and the demand for disaster prevention measures is increasing rapidly.

In particular, Korea has a steep slope of the mountainous area, which occupies about 65% of the national territory, narrow valleys, and high population density, which leads to the development of mountain areas due to the characteristics of land use. It is located in the foot of a mountain and is known to have a high risk of potential earth and sand disasters.

Since ordinary earthquake disasters occur sporadically with spatiotemporal nonuniformity, there is a limit to accurate predictions. Therefore, it is very important to implement everywhere projects to prevent potential earthquake disaster risk areas in order to minimize earthquake disasters such as landslides . The Sabang Dam, which occupies the largest portion of all earthquake disaster prevention projects, is a transverse structure that is mainly constructed to suppress the outflow of soil, soil, and driftwood. It will function as a disaster prevention facility that prevents damages to private houses, farmland and roads in the downstream areas.

As described above, Sabang Dam was first constructed in Korea in 1986, and the impact of disaster reduction began to be known, and as the heavy rain caused by extreme weather caused forest damages and occurred frequently, it was a solution to minimize damages. It is recognized as a necessary facility for the preservation of the clinic, and it is gradually expanding through the construction facilities in earnest from the 1990s.

However, conventional conventional four-sided dams are constructed in a uniform form of concrete wall structure, do not harmonize with the surrounding landscape, and do not take into consideration the river ecosystem. Development of environmentally friendly Eco-Pillar dams, as presented in No. 10-0965467, is being promoted.

In other words, the existing steel frame or gravity concrete four-sided dam has waste mines upstream, so if the soil continues to fall down, it is necessary to dredge the soil to deepen the ground. There is a problem that acts as a cause. As a result, the size of the four-sided dam has been enlarged, which greatly damages the surrounding landscape, hinders the crossing of mountain streams, and causes ecological disruption.

On the other hand, Eco-Pillar Sabang Dam was developed to compensate for the shortcomings and problems of the existing Sabang Dam mainly focused on blocking, and to minimize the damage to the surrounding natural landscape by miniaturizing the facility size. Construction has the advantage of free movement of fish, amphibians and animals, and visually friendly.

In addition, the eco-pil Sabang dam has the advantages of high safety of the waterproof passage and lowering the height of the dam as it can perform the role and function of the waterproof passage itself, which greatly improves the construction efficiency and economic efficiency.

However, the Eco Pill Sabang Dam, which has been constructed and constructed so far, is a construction method that assembles formwork and cures cast-in-place concrete, and thus the construction process is complicated by formwork placement and reinforcing steel assembly. The construction period has the disadvantage of increasing.

In addition, the existing eco-pillar square dam has a disadvantage in that it is difficult to secure quality due to the long time required to cure concrete, and there are many cases where ready-mixed concrete vehicles with limited concrete casting time cannot enter the construction site. It is being affected a lot.

Republic of Korea Patent Publication No. 10-1418998 Republic of Korea Patent Publication No. 10-1313868 Republic of Korea Patent Publication No. 10-0995832 Republic of Korea Patent Publication No. 10-0965467 Republic of Korea Patent Publication No. 10-0908676 Korea Utility Model Registration No. 20-0291969

The present invention was created in order to improve this in consideration of the disadvantages and problems of the existing four-sided dam as described above, the object of the present invention can minimize the installation of fixtures such as highways and temporary curtains at the same time the site of rebar It is to provide an economical block-laminated eco-pillar all-round dam and its construction method through efficient air shortening due to elimination of processes such as assembly and form curing and ease of material handling.

Another object of the present invention is to form a connection reinforcement through the filling of steel rods and grouting material pre-stressed to the connection of the unit hollow pillars made of precast concrete used as laminated segments to form structural reinforcement and durability to easily ensure corrosion To provide a new type of block stacked eco-pillar four-side dam and its construction method that can effectively replace the existing high-cost steel four-side dam with high concern.

Still another object of the present invention is to install an economical block-laminated eco-pillar all-round dam and its construction to be advantageous for light weight and miniaturization by sequentially stacking precast (PC) concrete unit hollow pillar blocks on a concrete foundation layer placed on a sloped ground. It is to provide a method.

It is still another object of the present invention to provide a block stack type eco pillar all-round dam and a construction method of the new type that can minimize the influence of environmental geographic constraints and at the same time ensure maximum harmony with the surrounding environment.

Still another object of the present invention is to provide a precast concrete hollow pillar block unit for constructing a block-laminated eco-pillar square dam for achieving the above objects.

In order to achieve the above object, the block-laminated eco-pillar square dam according to the present invention comprises a plurality of hollow pillars constructed of a concrete foundation layer placed on the ground and an upright columnar structure formed at a predetermined interval pattern on the concrete foundation layer. In the eco-pillar square dam, the hollow pillar is a plurality of unit hollow pillar blocks made of precast concrete are sequentially stacked so that a plurality of through holes penetrating the upper and lower ends of the cylindrical body is formed in an annular arrangement It is formed to form a segment, each unit hollow pillar block is integral structure by a connecting reinforcement formed by the steel rod is inserted into the through-hole prestressed tension material and the grouting material is filled to surround the steel rod It is characterized by being constructed to achieve.

In order to achieve the above object, another block-laminated eco-pillar square dam according to the present invention includes a plurality of hollow structures constructed of a concrete foundation layer that is placed on the ground and an upright columnar structure that is arranged in a constant interval pattern on the concrete foundation layer. In the eco-pillar four-way dam including a pillar, the hollow pillar is a plurality of unit hollow pillar blocks made of precast concrete are sequentially stacked so that a plurality of through holes penetrating the upper and lower ends of the cylindrical body in an annular arrangement Each unit hollow pillar block is formed by a connecting reinforcement formed by a steel rod inserted into the through hole as a prestressed tension material and a grouting material filled to surround the rod. It is constructed to achieve the most mounted on the concrete foundation layer The unit hollow pillar block at the bottom includes a reinforcement joint formed by a plurality of reinforcing bars embedded to protrude into the concrete foundation layer and aligned in a state inserted into the hollow, and a mortar layer which is poured for embedding the reinforcing bars. It is done.

In order to achieve the above object, the block laminated eco-pillar dam construction method according to the present invention, in the construction method of the eco-pillar all-round dam in which a plurality of hollow pillars are constructed in an array pattern at regular intervals in a concrete foundation layer to be placed on the ground, Placing a concrete foundation layer on the ground to bury the steel rod installed as a prestressed tension material, and a plurality of penetrations penetrating the top and bottom of the cylindrical body to form a segment laminated to form the hollow pillar. The steps of manufacturing the unit hollow pillar block having holes are made of concrete precast in a separate process, and the unit hollow pillar block is transported to the site in order to sequentially insert the steel bar into the through hole. Laminating with; And installing a fixing device to apply prestress to the steel rod, and filling the grouting material into the through-hole.

According to another aspect of the present invention, there is provided a method for constructing an eco-pillar four-sided dam, in which a plurality of hollow pillars are constructed in a constant spaced array pattern on a concrete foundation layer that is placed on the ground. Placing a concrete foundation layer on the ground to bury the steel rod installed as a prestressed tension material, and a plurality of penetrations penetrating the top and bottom of the cylindrical body to form a segment laminated to form the hollow pillar. The steps of manufacturing the unit hollow pillar block having holes are made of concrete precast in a separate process, and the unit hollow pillar block is transported to the site in order to sequentially insert the steel bar into the through hole. Laminating with; And installing a fixing device to apply prestress to the steel rod, and filling the grouting material into the through-hole.

In the block-laminated eco-pillar square dam according to the invention having the above-described configuration and its construction method, it is preferable that the steel bar is embedded in the concrete foundation layer in an arrangement state corresponding to the through-hole of the unit hollow pillar block.

According to another aspect of the present invention, the steel bar may have a configuration in which a plurality of units are extended by at least one or more couplers.

The unit hollow pillar block has a recess formed on the upper track surface and the lower track surface so as to be stepped so as to extend around the through hole, respectively, and the recess portion is a container made of a complementary space that is matched when the unit hollow pillar blocks are stacked. It is preferable that the grouting material is filled by forming a chamber in the form.

On the other hand, the unit hollow pillar block is continuously provided with grooves formed stepped to extend around the through hole on the upper track surface and the lower track surface, the grooves are matched and complementary when the unit hollow pillar blocks are stacked It may have a configuration in which the grouting material is filled by forming a donut-shaped chamber made of a space.

According to the present invention, it is preferable that the unit hollow pillar block is formed of any one selected from an elliptical shape, a water drop shape, and a horseshoe shape.

According to another aspect of the present invention, the unit hollow pillar block may have a configuration in which the through-holes are introduced in a section in which the prestressed tension members are overlapped by steel bars which are manufactured so that the through-holes are arranged on different axes and staggered on different axes. have.

According to one aspect of the invention, the uppermost unit hollow pillar block constituting the hollow pillar is preferably further provided with a cap member installed to close the hollow portion.

The lowest unit hollow pillar block mounted on the concrete foundation layer may have a structure in which a reinforcing convex portion is formed on a hollow inner wall constituting the reinforcing joint.

In order to achieve the above object, the hollow pillar block unit for pillar construction of another block-laminated eco-pillar square dam according to the present invention is constructed by forming hollow pillars arranged at a constant interval pattern on a concrete foundation layer placed on the ground to form a square dam. It is made of cast concrete to form a segment that is sequentially laminated on the concrete base layer, a plurality of through-holes formed so that the prestressed tension material is inserted through the upper and lower ends of the cylindrical body by the production of precast concrete, the cylindrical Each of the upper track surface and the lower track surface of the body is provided with a stepped groove formed so as to extend around the through hole, respectively, when the sequential stacking on the concrete base layer is matched to face the groove to form a chamber consisting of a complementary space Doing that in that chamber Routing material is filled characterized in that configured to enable the formation of the reinforcing connecting portion.

The groove portion is provided with grooves continuously formed so as to extend around the through hole, the grooves are matched during the stacking of the cylindrical body to form a donut-shaped chamber consisting of a complementary space to fill the grouting material have.

According to the block-laminated eco-pillar square dam according to the present invention and a manufacturing method thereof, the following effects can be obtained.

First, as the unit hollow pillar block made of free-cast concrete is laminated on the concrete foundation layer, it is possible to construct an economical four-side dam by facilitating ease of material handling, efficiency, light weight and miniaturization. Accordingly, it is possible to minimize the influence of environmental geographic constraints, it is possible to provide a new type of eco-pillar all-round dam and its construction method that can maximize the harmony with the surrounding environment.

Second, it is possible to minimize the installation of temporary facilities such as temporary curtains and highways, and to eliminate processes such as on-site reinforcement and form curing. Therefore, it is possible to construct economically all-round dams through efficient air reduction and reduction of city parks. .

Third, by constructing the connection reinforcement by introducing a prestressed tension to the connection portion of the unit hollow pillar block made of concrete base layer and pre-cast concrete, it is possible to build a four-sided dam that can easily secure structural stability and durability. Accordingly, it is possible to provide a new type of four-sided dam and its construction method that can effectively replace the existing high-cost steel four-side dam with high corrosion concerns.

1 is a perspective view showing a main portion ablation schematically showing a block-layered eco-pillar square dam according to the present invention.
Figure 2 is a plan view schematically showing a block stacked eco-pillar four-sided dam according to the present invention.
Figure 3 is a schematic vertical cross-sectional view showing an enlarged portion of the main portion of the block-layered eco-pillar square dam according to the present invention shown in Figures 1 and 2,
4 and 5 are respectively a schematic perspective view and a cross-sectional view of the unit hollow pillar block used as the construction element member of the block laminated eco-pillar square dam according to the present invention;
6 and 7 are schematic plan views illustrating an embodiment in which a main portion of a unit hollow pillar block used as a construction element member of a block stacked eco-pillar square dam according to the present invention is modified.
8 and 9 are schematic plan views illustrating an embodiment in which a shape structure of a unit hollow pillar block used as a construction element member of a block stacked eco-pillar square dam according to the present invention is modified,
10 is a schematic cross-sectional view showing the main process to explain the construction method of the block-laminated eco-pillar four-way dam according to the present invention.
11 is a schematic cross-sectional view showing a main process for explaining the construction method of the block-laminated eco-pillar square dam according to another embodiment of the present invention.
12 is a schematic cross-sectional view of a block stacked eco-pillar square dam according to another embodiment of the present invention.
Figure 13 is a schematic cross-sectional view showing a block stacked eco-pillar square dam according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a block-laminated eco-pillar square dam and its construction method according to the present invention. The following description and the accompanying drawings are only preferred embodiments for understanding the technical configuration and operation state thereof according to the present invention, and do not limit the present invention described in the claims, which are common in the technical field of the present invention. Portions that can be easily implemented by a technician can be omitted.

1 and 2 are respectively a perspective view and a plan view of a main portion ablation block diagram showing the block stacked eco-pillar square dam according to the present invention, Figure 3 is a block stacked eco-pillar square dam according to the present invention shown in Figures 1 and 2 Is a schematic vertical cross-sectional view showing an enlarged portion of the main portion of the

Referring to Figures 1 to 3, the block-layered eco-pillar all-round dam 100 according to the present invention, the concrete foundation layer 110 to be placed on the ground, and the pillars arranged in a predetermined interval pattern on the concrete foundation layer 110 It includes a plurality of hollow pillars 120 are constructed in the form of a structure, the hollow pillars 120 is a plurality of unit hollow pillar blocks 121 made of precast concrete to sequentially form a segment (segment) It is constructed so that the reinforcement connection part by prestressing is formed in each connection part in the laminated state.

The concrete foundation layer 110 is, for example, a foundation structure that is to be installed on the ground, such as a slope, when in-site casting steel rods 131 buried with prestressed tension material for forming the reinforcing connection of each unit hollow pillar block 121 ) Is provided in an upright state to protrude a certain length.

According to one aspect of the present invention, the steel bar 131 is not limited to the length protruding from the upper surface of the concrete foundation layer 110, for example by lifting the unit hollow pillar block 121 by lifting a crane or the like In order to ensure the ease and efficiency of the construction work for it is preferably installed to a height of less than 3m, the height of the protrusion of the steel bar 131 is not limited to the present invention.

According to another aspect of the present invention, the steel bar 131 may be used as a prestressed tension by connecting a plurality of units cut in a predetermined length by the coupler (C).

For example, when the concrete is placed on the ground such as a slope, the steel bar 131 used as a prestress tension material is placed in the upright state to be embedded in a state protruding a predetermined length to form a foundation structure.

According to one aspect of the present invention, the steel bar 131 is not limited to the length protruding from the upper surface of the concrete foundation layer 110, for example by lifting the unit hollow pillar block 121 by lifting a crane or the like In order to ensure the ease and efficiency of the construction work for it is preferably installed to a height of less than 3m, the height of the protrusion of the steel bar 131 is not limited to the present invention.

According to another aspect of the present invention, the steel bar 131 is a prestressed tension material is connected to the plurality of units cut by a certain length in the lamination process of the unit hollow pillar block 121 by a coupler (C) as described below It can be used as, the specific configuration for this will be described in detail in the construction method illustrated in Figure 10 to be described later.

On the other hand, the concrete foundation layer 110 may be embedded with a reinforcing reinforcing bar (not shown) so as to be disposed along the edge, for example, when in-site casting.

4 and 5 are respectively a schematic perspective view and a cross-sectional view of the unit hollow pillar block used as the construction element member of the block stacked eco-pillar square dam according to the present invention.

4 and 5, the unit hollow pillar block 121 is formed to penetrate the upper and lower ends of the body 121a formed of a cylindrical wall, and includes a through hole 121h arranged in an annular shape.

The through-hole 121h of the unit hollow pillar block 121 has a diameter of a certain size so that the grouting material G is injected and filled to surround the steel bar 131 while being inserted to allow the steel bar 131 to pass therethrough. It is formed to have (口徑).

Therefore, the steel rod 131 having a smaller diameter is inserted into the through-hole 121h of the unit hollow pillar block 121 as the prestressed tension member. As a result, a gap space having a predetermined size is formed between the inner wall of the through hole 121h and the outer circumferential surface of the steel bar 131, and the grouting material G is injected into the gap space and filled. As a result, the plurality of unit hollow pillar blocks 121 sequentially stacked on the concrete foundation layer 110 may have an effective counter force against shear force because a solid reinforcement connection part is formed at each boundary to form an integral reinforcement structure. Built into a hollow columnar structure.

According to one aspect of the present invention, the upper and lower track surfaces of the unit hollow pillar block 121 is provided with a circular groove portion 121w formed to be stepped to extend around the through hole 121h.

As shown in a sectional view of the recessed part of the recess 121w extracted and enlarged in the circular interior of FIG. 2, each unit hollow pillar block 121 of the lower and upper portions of the unit hollow pillar block 121 is stacked. The upper track surface and the lower track surface of the contact with each other to form a chamber-like chamber consisting of a complementary space. Accordingly, the grouting material G injected into the through hole 121h of the unit hollow pillar block 121 is received and filled in a chamber formed by the recess 121w.

FIG. 6 illustrates another embodiment in which the recess 121w is deformed, and is formed to be stepped in a rectangular shape around the through hole 121h. The modified embodiment of the recess 121w is performed to control the capacity of the grouting material G filled in the recess 121w in various forms when the unit hollow pillar blocks 121 are stacked. can do.

FIG. 7 illustrates another modified embodiment, wherein the unit hollow pillar block 121 may have a configuration in which grooves 121g continuously formed to be stepped to extend around the through hole 121h are continuously provided. . Accordingly, the groove 121g is formed of a complementary space while the upper track surface and the lower track surface of each unit hollow pillar block 121 of the lower and upper portions contact each other when the unit hollow pillar block 121 is stacked. It forms a chamber of the form, the grouting material (G) injected into the through hole (121h) is received in the donut-shaped chamber is filled with.

Meanwhile, the reference numeral 121d of FIG. 7 is a stepped portion formed to block the continuity of the groove 121g, which is grouting filled in the groove 121g when the unit hollow pillar block 121 is stacked. Various modified embodiments are applicable as a means for appropriately controlling the capacity of the ash G.

8 and 9 are schematic plan views illustrating an embodiment in which the shape structure of the unit hollow pillar block 121 is modified.

That is, the unit hollow pillar block 121 used in the construction of the block-laminated eco-pillar four-way dam 100 according to the present invention is not limited to the shape structure of the elliptic shape as described above, and the block-laminated eco-pillar according to the present invention. As illustrated in FIG. 8 according to the environment and characteristics of the construction site of the four-side dam 100, for example, it may have a flat-shaped structure of water droplets deformed in the shape of an elliptical track is reduced in the front and extended in the rear, and On the other hand, as shown in Figure 9 may have a planar shape of the horseshoe shape.

Hereinafter, a construction method of the block-laminated eco-pillar square dam according to the present invention having the configuration as described above will be described in detail with reference to the drawings.

10 is a schematic cross-sectional view showing the main process to explain the construction method of the block-laminated eco-pillar square dam according to the present invention.

Referring to Figure 10, the construction method of the block laminated eco-pillar square dam according to the present invention, the step of curing by pouring the concrete foundation layer (110) on the ground such as inclined surface (a), and the unit hollow pillar block in the factory ( A step (not shown) of precast fabrication 121 is performed by a separate process, and the unit hollow pillar block 121 is transported to a site and sequentially stacked on the concrete foundation layer 110 (b). ) and (d) and injecting grouting material G into the through-hole 121h of the unit hollow pillar block 121.

According to the present invention, in the step (a) of pouring the concrete foundation layer 110, for example, the steel rod 131, which is used as a prestress tension member when the concrete is placed on the ground such as a slope protrudes a predetermined length in an upright state Concrete is laid to form foundation structures.

According to one aspect of the present invention, the steel bar 131 is not limited to the length protruding from the upper surface of the concrete foundation layer 110, for example by lifting the unit hollow pillar block 121 by lifting a crane or the like In order to ensure the ease and efficiency of the construction work for it is preferably installed to a height of less than 3m, the height of the protrusion of the steel bar 131 is not limited to the present invention.

According to another aspect of the present invention, the steel bar 131 is a prestressed tension material is connected to the plurality of units cut by a certain length in the lamination process of the unit hollow pillar block 121 by a coupler (C) as described below It can be used as, a detailed configuration for this will be described in detail in the construction method illustrated in FIG.

On the other hand, in the present invention, the steel bar 131 is inserted into the through-hole 121h of the unit hollow pillar block 121 to be described later to function as a prestressed tension material, thereby penetrating the unit hollow pillar block 121 Designed and installed at an array interval that can be complementary to the hole 121h.

According to another aspect of the present invention, the steel bar 131 is a prestressed tension material is connected to the plurality of units cut by a certain length in the lamination process of the unit hollow pillar block 121 by a coupler (C) as described below Can be used as

On the other hand, when the concrete foundation layer 110 is placed, for example, reinforcing reinforcing bars (not shown) may be buried in the core along the edges.

Meanwhile, although not illustrated by the drawings, the unit hollow pillar block 121 is manufactured through a conventional concrete precast manufacturing process, and the upper and lower ends of the cylindrical body as described with reference to FIGS. 1 to 7. A plurality of through holes 121h penetrating the through holes and grooves 121w and 121g extended stepwise around the through holes 121h are formed. Thus, the unit hollow pillar block 121 made of concrete precast is used as a segment that is transported to the site where the concrete foundation layer 110 is formed to form the hollow pillar 120.

According to the present invention, the through hole 121h of the unit hollow pillar block 121 is filled with a grouting material G that is injected to allow the steel rod 131 to penetrate therein and is enclosed therein. It is formed to have a certain diameter as much as possible. Accordingly, the steel bar 131 of the concrete foundation layer 110 is provided with a diameter smaller than the diameter of the through hole 121h of the unit hollow pillar block 121. Due to this configuration, the steel rods 131 are prestressed in the through-holes 121h of the unit hollow pillar blocks 121 in steps (a) to (d) of stacking the unit hollow pillar blocks 121 to be described later. When inserted into the gap between the inner wall of the through-hole (121h) and the outer peripheral surface of the steel bar 131 is formed a gap of a certain size grouting material (G) can be injected and filled in the gap space.

Meanwhile, the recesses 121w and 121g of the unit hollow pillar block 121 are each unit hollow pillar block 121 at the lower and upper portions when the unit hollow pillar block 121 is stacked as described with reference to FIG. 3. The upper track surface and the lower track surface of the to form a chamber consisting of a complementary space while abutting each other, a circular as illustrated in FIGS. 1 and 4 or a square as illustrated in FIG. 6 or illustrated in FIG. An embodiment modified to the track groove 121g as described above may be applied, and a detailed description thereof will be omitted since it has been described with reference to FIGS. 6 and 7.

As a next construction step, in the steps (b) to (d) of laminating the unit hollow pillar block 121 to the concrete base layer 110, for example, by lifting the unit hollow pillar block 121 with a crane or the like to the concrete The steel bar 131 of the base layer 110 is loaded to be inserted into the through hole 121h. In the loading process as described above, the through-hole 121h of the unit hollow pillar block 121 is coaxially aligned with the steel rod 131 of the concrete foundation layer 110 in parallel with the shaft hole and the shaft through the coupling of the steel rod. The unit hollow pillar block 121 is inserted into and restrained by 131.

Therefore, while repeatedly performing the loading operation of the unit hollow pillar block 121 as described above, a plurality of unit hollow pillar blocks 121 are laminated on the concrete foundation layer 110 at a predetermined height to form a pillar-shaped hollow pillar 120. Build a structure.

In the present invention, the stack height of the unit hollow pillar block 121 may be constructed in variously adjusted state to meet the specifications designed according to the construction site, environment, and characteristics of the four-side dam.

As a next construction step, in the step (d) of filling the grouting material in the through-holes (121h), grouting in the through-holes (121h) of the unit hollow pillar block 121 stacked to be located at the top of the hollow pillars 120 Inject ash (G). Accordingly, the grouting material G is injected and filled into the gap space formed between the inner wall of the through hole 121h of the unit hollow pillar block 121 and the outer circumferential surface of the steel bar 131. In this case, as described with reference to FIG. 2, the grouting material G is injected into the chamber in which the recesses 121w and 121g of the unit hollow pillar block 121 form a complementary space until they are sufficiently received and filled. .

Subsequently, a pre-stress is applied by installing a fixing anchor 132 at an upper end of the steel bar 131 in the upper through hole 121h of the unit hollow pillar block 121 at the uppermost stage. As a result, the plurality of unit hollow pillar blocks 121 sequentially stacked on the concrete foundation layer 110 may have an effective counter force against shear force because a solid reinforcement connection part is formed at each boundary to form an integral reinforcement structure. Built into a hollow columnar structure.

According to the present invention, the plurality of unit hollow pillar blocks 121 are sequentially stacked on the concrete base layer 110 through the steps as described above, and the upper portion of the hollow pillar 120 constructed as a columnar structure is also illustrated. Install the cap member 141 as illustrated in 1 to finish the construction work for a single hollow pillar (120).

Therefore, according to the construction method of the block-layered eco-pillar square dam according to the present invention, the block-layered eco-pillar in which a plurality of hollow pillars 120 are arranged in a predetermined interval pattern on the concrete base layer 110 through the steps as described above. Construction of all sides of the dam can be completed.

On the other hand, Figure 11 is a schematic cross-sectional view showing the main process to explain the construction method of the block-layered eco-pillar four-way dam according to another embodiment of the present invention.

Referring to Figure 11, according to the construction method of the block-laminated eco-pillar four-way dam according to another embodiment of the present invention, the step of curing by placing the concrete foundation layer 110 on the ground, such as the inclined surface (a), and in the factory A precast manufacturing step (not shown) of the unit hollow pillar block 121 is performed by a separate process, and the unit hollow pillar block 121 is sequentially transported to the concrete foundation layer 110 by transporting it to the site. And (d) injecting the grouting material G into the through holes 121h of the unit hollow pillar block 121 and stacking (b) to (d).

In short, the construction method of the block-layered eco-pillar square dam according to another embodiment of the present invention is substantially the same as the flow of the overall process steps and the construction method of the present invention described by Figure 10, the unit hollow pillar block 121 The plurality of steel bars 131 cut to a predetermined length in the lamination process of the connection is tightened by the coupler (C) is connected to be tensioned has a structural difference used as a prestress tension material.

That is, according to the construction method of the block-layered eco-pillar square dam according to another embodiment of the present invention, in the step (a) of pouring the concrete foundation layer 110 and curing, for example, when pouring concrete on the ground such as inclined surface The foundation is formed by pouring concrete so that the coupler (C) is exposed in the state where the coupler (C) can be installed at the end of the steel bar 131 used as the tension material.

Although not illustrated by the drawings, the unit hollow pillar block 121 is manufactured through a conventional concrete precast manufacturing process in the same manner as the construction method described with reference to FIG. 9, and a detailed description thereof will be omitted. do.

As a next construction step, in the step (b) ~ (d) of laminating the unit hollow pillar block 121 to the concrete base layer 110, the end of the steel bar 131 embedded in the concrete base layer 110 Coupled to the coupler (C) is introduced into the pre-stressed tension material by the connection of the other unit steel bar 131 cut to a certain length, for example, by lifting the unit hollow pillar block 121 with a crane or the like through the through hole (121h) The steel rod 131 is loaded in a confined state.

Therefore, while repeatedly performing the loading operation of the unit hollow pillar block 121 as described above, a plurality of unit hollow pillar blocks 121 are laminated on the concrete foundation layer 110 at a predetermined height to form a pillar-shaped hollow pillar 120. Build a structure. Here, the stacking height of the unit hollow pillar block 121 may be constructed in variously adjusted state to meet the specifications designed according to the construction site, environment, and characteristics of the four-side dam.

As a next construction step, in the step (d) of filling the grouting material in the through-holes (121h), grouting in the through-holes (121h) of the unit hollow pillar block 121 stacked to be located at the top of the hollow pillars 120 Inject ash (G). Accordingly, the grouting material G is injected and filled into the gap space formed between the inner wall of the through hole 121h of the unit hollow pillar block 121 and the outer circumferential surface of the steel bar 131. In this case, as described with reference to FIG. 2, the grouting material G is injected into the chamber in which the recesses 121w and 121g of the unit hollow pillar block 121 form a complementary space until they are sufficiently received and filled. .

Subsequently, a pre-stress is applied by installing a fixing anchor 132 at an upper end of the steel bar 131 in the upper through hole 121h of the unit hollow pillar block 121 at the uppermost stage. As a result, the plurality of unit hollow pillar blocks 121 sequentially stacked on the concrete foundation layer 110 may have an effective counter force against shear force because a solid reinforcement connection part is formed at each boundary to form an integral reinforcement structure. Built into a hollow columnar structure.

According to the present invention, the plurality of unit hollow pillar blocks 121 are sequentially stacked on the concrete base layer 110 through the steps as described above, and the upper portion of the hollow pillar 120 constructed as a columnar structure is also illustrated. Install the cap member 141 as illustrated in 1 to finish the construction work for a single hollow pillar (120).

Therefore, according to the construction method of the block-layered eco-pillar square dam according to another embodiment of the present invention, a plurality of hollow pillars 120 are arranged in a predetermined interval pattern on the concrete base layer 110 through the steps as described above. Construction of block stacked eco-pillars can be completed.

12 is a cross-sectional view schematically showing the main portion of the block-layered eco-pillar square dam according to another embodiment of the present invention.

Referring to FIG. 12, the block-laminated eco-pillar four-side dam according to another embodiment of the present invention is constructed in a columnar structure arranged in a predetermined interval pattern on the concrete foundation layer 110 that is placed on the ground. The hollow pillars 120 of the plurality of unit hollow pillar blocks 121 made of precast concrete are sequentially stacked to form a segment (segment) is formed in each connection to form a reinforced connection by prestressing, the concrete foundation layer ( The reinforcing joints 111 and 112 are formed at the connection portion between the 110 and the lowermost unit hollow pillar block 121. Here, the same reference numerals as the reference numerals of the drawings shown above correspond to the same components, and detailed descriptions of the components will be omitted.

That is, according to the block-laminated eco-pillar square dam according to another embodiment of the present invention, the lowest unit hollow pillar block 121 mounted on the concrete foundation layer 110 is buried so as to protrude from the concrete foundation layer 110. The reinforcement joint portion is formed by the mortar layer 112 cast in the hollow of the lowermost unit hollow pillar block 121 so that the plurality of reinforcing bars 111 and the reinforcing bars 111 are aligned in the hollow interior. 111, 112 are constructed to form.

In addition, the lowermost unit hollow pillar block 121 mounted on the concrete foundation layer 110 is preferably provided with a reinforcing convex portion (not shown) on the hollow inner wall forming the reinforcing joint portion.

In addition, the plurality of unit hollow pillar blocks 121 sequentially stacked on the concrete foundation layer 110 are inserted into the through holes 121h by the steel rods 131 installed as prestressed tension members, thereby being fixed by both fixing anchors 132. The stage is fixed, and the grouting material G is injected into the gap space formed between the inner wall of the through hole 121h and the outer circumferential surface of the steel bar 131, thereby filling the edge of the unit hollow pillar block 121. Since the reinforcing connection is formed to form an integral structure, it is constructed as a hollow columnar structure that can hold an effective counter force against shear force.

FIG. 13 is a schematic cross-sectional view of a block stacked eco-pillar square dam according to another embodiment of the present invention. Here, the same reference numerals in the same drawings as those of the previous drawings correspond to the same components, and detailed descriptions of the components will be omitted.

Referring to FIG. 13, the block stack type eco pillar all-round dam according to another embodiment of the present invention may be manufactured so that the through holes 121h of the unit hollow pillar block 121 are arranged on different axes. Accordingly, the steel rods 131 may be installed as a prestressed tension member in a plurality of unit numbers such that the steel rods 131 are arranged in a staggered state on different axes by a plurality of couplers C.

Therefore, the unit hollow pillar block 121 may have a configuration in which the prestressed tension members are introduced into overlapping sections by the steel bars 131 installed in staggered states on different axes.

The present invention as described above is not limited to the specific preferred embodiment described above, and anyone skilled in the art to which the invention belongs without departing from the gist of the invention claimed in the claims. Various modifications are possible, of course, and such changes fall within the scope of the claims set forth.

110: concrete foundation layer
111: rebar
120: hollow pillar
121: unit hollow pillar block
121h: through hole
121w: groove
121g: Groove Groove
131: steel bar
132: anchorage
141: cap member
C: coupler
G: Grouting Material

Claims (18)

In the eco pillar all-round dam comprising a concrete base layer 110 to be poured into the ground and a plurality of hollow pillars 120 constructed in an upright columnar structure structure arranged in a predetermined interval pattern on the concrete base layer 110,
The hollow pillar 120 has a plurality of unit hollow pillar blocks 121 made of precast concrete so that a plurality of through holes 121h penetrating the upper and lower ends of the cylindrical body 121a are formed in an annular arrangement. Stacked to form segments,
Each unit hollow pillar block 121 is connected to the reinforcing portion formed by a steel rod 131 inserted into the through-hole 121h as a prestressed tension material and a grouting material filled to surround the steel rod 131. Block stacked type eco-pillar square dam characterized in that it is constructed to form an integral structure. In the eco pillar all-round dam comprising a concrete base layer 110 to be poured into the ground and a plurality of hollow pillars 120 constructed in an upright columnar structure structure arranged in a predetermined interval pattern on the concrete base layer 110,
The hollow pillar 120 has a plurality of unit hollow pillar blocks 121 made of precast concrete so that a plurality of through holes 121h penetrating the upper and lower ends of the cylindrical body are formed in an annular arrangement. Is made to form
Each unit hollow pillar block 121 is connected to the reinforcing portion formed by a steel rod 131 inserted into the through-hole 121h as a prestressed tension material and a grouting material filled to surround the steel rod 131. Are constructed to form an integral structure,
The lowermost unit hollow pillar block 121 mounted on the concrete foundation layer 110 is embedded so as to protrude into the concrete foundation layer 110 and is arranged in a state of being inserted into the hollow. Block stacked type eco-pillar square dam, characterized in that it comprises a reinforcing junction formed by the mortar layer 112 is poured for embedding (111). The method according to claim 1 or 2,
The steel bar 131 is a block stacked eco-pillar square dam, characterized in that the buried so as to protrude upward in the concrete base layer 110 in the arrangement state corresponding to the through hole (121h) of the unit hollow pillar block 121. The method according to claim 1 or 2,
The steel bar 131 is a block laminated eco-pillar square dam, characterized in that installed in a state in which a plurality of units are extended by at least one or more couplers (C). The method according to claim 1 or 2,
The unit hollow pillar block 121 is provided with a recess formed on the upper track surface and the lower track surface to be stepped so as to expand around the through hole 121h, respectively.
Wherein the groove is block laminated eco-pillar square dam, characterized in that the grouting material is filled by forming a container-like chamber consisting of a complementary space is matched when the unit hollow pillar block 121 stacked. The method according to claim 1 or 2,
The unit hollow pillar block 121 is continuously provided with grooves 121g formed stepwise to extend around the through hole 121h on the upper track surface and the lower track surface.
The groove (121g) is a block laminated eco-pillar square dam, characterized in that the grouting material (G) is filled by forming a donut-shaped chamber formed of a complementary space is matched when the unit hollow pillar block 121 is stacked. The method according to claim 1 or 2,
The unit hollow pillar block 121 is a block stacked type eco-pillar square dam, characterized in that the track cross-section is formed of any one selected from the shape of oval or water droplets and horseshoe. The method according to claim 1 or 2,
The unit hollow pillar block 121 is manufactured so that the through-holes 121h are arranged on different axes and is introduced in a section in which the prestressed tension material is overlapped by steel rods 131 installed in a staggered state on different axes. Block stacked eco-pillars everywhere. The method according to claim 1 or 2,
Block hollow eco-pillar four-side dam, characterized in that the uppermost unit hollow pillar block 121 constituting the hollow pillar 120 is further provided with a cap member 141 installed to close the hollow portion. The method of claim 2,
The lowest unit hollow pillar block 121 mounted on the concrete foundation layer 110 is a block laminated eco-pillar square dam, characterized in that the reinforcing irregularities are formed on the hollow inner wall forming the reinforcing joint. In the construction method of the eco-pillar four-sided dam to construct a plurality of hollow pillars 120 in an array pattern at regular intervals in the concrete foundation layer 110 to be placed on the ground,
The steel rod 131 installed as a prestressed tension member is placed in the ground to bury the concrete foundation layer 110 to bury the protrusion and to form a segment stacked to form the hollow pillar 120 of the cylindrical body of Performing a pre-fabricated unit hollow pillar block 121 having a plurality of through holes 121h penetrating the top and the bottom by concrete precast, respectively,
Carrying the unit hollow pillar block 121 to a site and sequentially laminating the concrete pillar layer 110 so that the steel rod 131 is inserted into the through hole 121h;
And installing a fixing device to apply prestress to the steel rods (131), and filling grouting material into the through-holes (121h). In the construction method of the eco-pillar four-sided dam to construct a plurality of hollow pillars 120 in an array pattern at regular intervals in the concrete foundation layer 110 to be placed on the ground,
Placing and curing the concrete foundation layer 110 on the ground so that the reinforcing reinforcing bars 111 for forming the joints are embedded in a protruding state (S-10);
Manufacturing a unit hollow pillar block 121 having a plurality of through holes 121h penetrating through the upper and lower ends of the cylindrical body to form segments stacked to form the hollow pillar 120 by concrete precast (S-20);
Transporting the unit hollow pillar block 121 to a site and mounting the reinforcing reinforcement 111 on the concrete foundation layer 110 at one end so as to be located inside the hollow;
Forming a reinforcing joint by embedding the mortar layer 112 in the hollow portion of the unit hollow pillar block 121 mounted on the concrete foundation layer 110 in one end;
Stacking other unit hollow pillar blocks 121 sequentially on the unit hollow pillar blocks 121 mounted on the concrete foundation layer 110 in one end;
At least one steel rod 131 is inserted into the through hole 121h of each unit hollow pillar block 121 as a prestressing tension material to apply prestress by a fixing unit and a connector, and to fill the through hole 121h with a grouting material. Construction method of the block-laminated eco-pillar four-way dam comprising a ;. The method of claim 11 or 12,
The unit hollow pillar block 121 is provided with a groove portion 121w formed on the upper track surface and the lower track surface to be stepped so as to expand around the through hole 121h, respectively.
The groove portion 121w is formed when the unit hollow pillar block 121 is stacked to form a container-shaped chamber made up of a complementary space, and the grouting material is filled, characterized in that the construction method of the four-sided pillars dam. The method of claim 11 or 12,
The unit hollow pillar block 121 is continuously provided with grooves 121g formed on the upper track surface and the lower track surface to be stepped to extend around the through hole 121h.
The groove 121g is formed when the unit hollow pillar block 121 is stacked to form a donut-shaped chamber made up of a complementary space, and the grouting material is filled, characterized in that the construction method of the four-sided eco-pillar square dam. The method of claim 11 or 12,
The unit hollow pillar block 121 is a block cross-sectional construction method of the eco-pillar square dam, characterized in that the track cross-section is formed of any one selected from the shape of oval, water droplets and horseshoe. Constructed with hollow pillars arranged in a predetermined interval pattern on the concrete foundation layer to be placed on the ground to form a segment made of precast concrete to form a four-sided dam and sequentially stacked on the concrete foundation layer,
A plurality of through holes 121h formed to penetrate the upper and lower ends of the cylindrical body by precast concrete to be inserted into the prestress tension member, and the through holes 121h respectively on the upper track surface and the lower track surface of the cylindrical body. With grooves formed stepped to extend around the),
Block stacking type, characterized in that when the sequential lamination on the concrete foundation layer 110 is matched to face the groove to form a chamber consisting of a complementary space, the grouting material is filled in the chamber to form a reinforcing connection portion Hollow pillar block unit for pillar construction of four dams. The method of claim 16,
The groove portion is formed by grooves 121g formed stepwise so as to extend around the through hole 121h on the upper track surface and the lower track surface of the cylindrical body, respectively, when sequentially stacked on the concrete foundation layer 110. The hollow pillar block unit for pillar construction of a four-sided dam, characterized in that to form a donut-shaped chamber formed of a complementary space. The method according to claim 16 or 17,
The hollow pillar block unit for pillar construction of the four-sided dam, characterized in that the track cross-section of the cylindrical body is formed of any one selected from the shape of oval or water droplets and horseshoe.

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