KR100867414B1 - Precasted concrete retaining wall with tension - Google Patents

Abstract

A precast concrete retaining wall is provided to make construction convenient and to stabilize the structure through raising the resistance about load to the retaining wall. A precast concrete retaining wall comprises a bottom surface having a tensile member through-hole formed along the retaining wall, a retaining wall segment(10) including a wall surface which has a tensile member through-hole along the retaining wall and which is extended from the bottom surface, a tensile member(20) inserted into the tensile member through-hole of the retaining wall segment, an anchorage(30) prepared respectively in the retaining wall segment in order to mount the tensile member on the retaining wall, an anti-rust means for preventing rust in the tensile member.

Description

Precasted Concrete Retaining Wall with Tension}

The present invention relates to a precast concrete retaining wall in which a tensile force is introduced, and more particularly, a structure capable of effectively introducing a tensile force by installing a tension member in the longitudinal direction of the retaining wall and effectively preventing corrosion of the tension member. It relates to a precast concrete retaining wall, which includes a tensile force.

In general, retaining walls constructed for slope stabilization on roads, railways, river banks, coastal roads, and slopes of residential areas have been constructed by site-cast concrete until now. In other words, in order to construct the retaining wall, formwork and reinforcing bars are installed, concrete is cast and cured with the formwork to build the retaining wall.

The construction method of the field casting retaining wall goes through many processes such as ground excavation, foundation concrete placing, reinforcing steel reinforcement, concrete placing, back filling, etc. After installing the concrete, and after the curing period of at least 7 days to express the strength that the concrete can be self-supporting, and then to dismantle the form again, air for the construction of the retaining wall The problem is that it becomes very long.

In addition, as described above, when the air is long, not only is it economically disadvantageous, but also a problem that causes a large social loss due to problems such as controlling vehicles or securing a bypass road when there are roads in the vicinity. There is this.

In addition, when the height of the wall portion of the retaining wall is high, there is a case in which there is a problem in the synthesis between concretes because the concrete cannot be poured at once.

In order to solve some of these problems, a method of constructing a retaining wall using precast retaining wall segments, such as Korean Utility Model Publication No. 420394, is shown. The symbol used in the present specification is partially different from the symbol used in the heading 440394.

Each retaining wall segment 6 presented in the above-mentioned Utility Model Publication No. 420394 is composed of two foundation plates 1 and 2 and two walls 3 and 4, and two foundation plates 1 and 2, respectively. The base plates 1, 2 and the lower wall 3 are connected by a tension member 5 penetrating the lower wall 3 and the lower wall 3, and the connection between the respective walls is partially connected to the connecting grooves 231,232. The wall connecting members 233 and 234 formed to protrude and the coupler 235 connecting the wall connecting members 233 and 234 from both sides and the filler 236 filled in the connecting grooves 232 and 232 are performed.

Such a retaining wall consists of several pieces, such as two base plates 1 and 2 and two walls 3 and 4, so that the retaining wall segments 6 take excessive time to assemble it in the field. In addition, the tension material 5 to be applied to the tensile force is very much there is also a disadvantage that a lot of time and manpower should be put to apply the tensile force to the tension member (5). More deadly, the longitudinal connection of the retaining wall depends entirely on the wall connecting members 233 and 234 and the coupler 235. Since the fastening force by these structures is weak, the retaining wall structure does not properly support the soil load and slips after construction. There is a possibility of causing deformation of the back. This is caused by poor integration of the retaining wall segments. When stress is concentrated in a retaining wall segment, the connection between the retaining wall segment and the surrounding retaining wall segment is the weakest, which causes the retaining wall to move or collapse. This may cause problems.

The present invention is derived to solve the above problems, the construction is easy and can build the retaining wall at a high speed, the resistance to the load on the retaining wall is increased by strongly integrating the retaining wall segments not only during construction but also after construction It is an object to provide a precast concrete retaining wall in which tension is introduced, which is structurally stable and can easily prevent corrosion of the tension member.

In order to achieve the above object, the precast concrete retaining wall in which the tensile force is introduced according to the present invention is manufactured by using reinforced concrete as a precasting method and is connected to each other to form a long retaining wall in one direction, and the length of the retaining wall A retaining wall segment including a bottom portion having a tension member passage hole in a direction and a wall surface portion extending from the bottom portion and having a tension member passage hole in a longitudinal direction of the retaining wall; A tension member inserted into the tension member through-hole of the retaining wall segment; Fixing units for fixing the tension member to the retaining wall segments, the fixing units being provided in retaining wall segments positioned at both ends of the retaining wall segments in the longitudinal direction of the retaining wall; And a rust preventive means for preventing rust on the tension member, wherein the rust preventive means is covered with an outer circumference of the tension member and a tube filled with a rust preventive agent for preventing rust of the tension member therein; It is comprised by any one of the coating members of the epoxy material coat | covered and attached.

As described above, according to the present invention, not only can the construction of the retaining wall be simple and fast, but also the strong resistance of the precast cast retaining wall segments increases the resistance to the load on the retaining wall, thereby making it structurally stable. There is also provided a precast concrete retaining wall in which tension is introduced, which can be easily performed when corrosion of the tensile material is prevented so as to strongly integrate the retaining wall segments in the future.

Hereinafter, a precast concrete retaining wall introduced with a tensile force according to an embodiment of the present invention with reference to the drawings will be described.

FIG. 2 is a view for explaining a precast concrete retaining wall in which tensile force is introduced according to an embodiment of the present invention, and FIGS. 3 and 4 are cross-sectional views taken along line III-III and line IV-IV, respectively. FIG. 5 is a view in which some segments of the retaining wall segments shown in FIG. 2 are separated, and FIG. 6 is a cross-sectional view of the VI-VI line shown in FIG. 5.

First, referring to FIGS. 2 to 6, the precast concrete retaining wall in which the tensile force is introduced according to the present embodiment includes the retaining wall segment 10, the tension member 20, the fixing unit 30, and the rust preventive means.

The retaining wall segment 10 is made of iron-based concrete as a material and manufactured by a precasting method (a method manufactured by a separate manufacturing plant, not on-site), and as shown in FIG. 2, a plurality of retaining wall segments 10 are arranged side by side in a long direction in one direction. It will form a retaining wall.

Each retaining wall segment 10 includes a bottom face 12 and a wall face 13 extending from the bottom face 12. The bottom surface portion 12 and the wall surface portion 13 are provided with a tension member through-hole 11 formed to extend in the longitudinal direction of the retaining wall, respectively. In the present embodiment, three tension member through-holes 11 (two on the bottom 12 and one on the wall 13) are formed.

Each retaining wall segment 10 is formed with a plurality of protrusions 15 and grooves 17. The protrusions 15 are located on one side wall surface of each retaining wall segment 10 (side wall surface of one of the wall surfaces perpendicular to the longitudinal direction of the retaining wall) and evenly disposed on the bottom portion 12 and the wall surface portion 13. It is. The groove portions 17 are located on the other side wall surface (side wall surface opposite to the surface on which the protruding portion 15 is formed) of each retaining wall segment 10 and are evenly disposed on the bottom portion 12 and the wall surface portion 13. . The protrusions 15 and the grooves 17 of each retaining wall segment 10 are arranged symmetrically about the central axis of the retaining wall segment 10 so that the protrusions 15 of each retaining wall segment 10 are adjacent retaining walls. It is adapted to fit into the corresponding grooves 17 of the segment, respectively.

As the tension member 20, for example, a PC strand or a PC rod used for introduction of prestress into a concrete structure such as a bridge can be suitably used, and in this embodiment, it is illustrated as being a PC steel rod. The tension member 20 is inserted into the tension member through-hole 11 of the retaining wall segment 10 and used to apply the force in the longitudinal direction of the retaining wall to the retaining wall segments 10. The number of tension members 20 provided in this embodiment is three, similar to the number of tension member through holes 11.

The fixing unit 30 is for fixing the tension member 20 to the retaining wall segment 10, and the retaining wall segments 10 positioned at both ends in the length direction of the retaining wall among the retaining wall segments 10, that is, FIG. The case at 2 is provided in the retaining wall segments 10 located at the leftmost and rightmost. When the tension member 20 is fixed while the tension member 20 is applied, the compressive force is applied to the retaining wall segments 10 by the elastic restoring force of the tensioned tension member 20, and the retaining wall segments 10 are compressed by the compressive force. It is to be integrated. The fixing unit 30 is installed at a position corresponding to the tension member through-hole 11, in the present embodiment, three pairs of the fixing unit 30 are provided in accordance with the number of the tension member through-holes (11).

The fixing unit 30 includes a fixing plate 31, a wedge segment 32, and a wedge plate 33. The fixing plate 31 is fixed to the retaining wall segment 10 and includes a first through hole 311 formed at a position in communication with the tension member through-hole 11 so as to pass through the tension member 20. . The wedge segment 32 is formed in a wedge shape surrounding the outer circumferential surface of the tension member 20, and a product generally used to fix the tension member 20 may be used. The wedge plate 33 may include a second through hole 331 communicating with the first through hole 311, a taper portion 332 for accommodating the wedge pieces 32, and a screw portion 333. Have The taper portion 332 is in contact with the outer circumferential surface of the wedge segments 32 and prevents the wedge segments 32 from moving in the clamped state of the tension member 20. The screw portion 333 is provided on the outer circumferential surface of the wedge plate 33 in order to be screwed with the corresponding screw portion 101 formed in the tensioner 100 (see FIG. 7) for applying a tensile force to the tension member 20.

The rust preventive means is for preventing rust from the tension member. In this embodiment, the rust preventive means includes a tube 25 and a rust preventive agent 29. The tube 25 is covered on the outer circumference of the tension member 20, and is preferably made of synthetic resin such as polyethylene (PE). The rust inhibitor 29 is filled inside the tube 25, that is, between the tube 25 and the tension member 20. This rust preventive agent 29 is for preventing the tension member 20 from rusting and corroding. For example, grease or the like may be used.

In this embodiment, the cap members 40 are provided. Each cap member 40 is covered with each fixing unit 30 and fixed to the retaining wall segment 10 by suitable fixing means such as, for example, a bolt B. The cap member 40 is filled with a rust preventive agent 49 such as grease through an injection port 41 formed in the cap member. The rust preventive agent 49 is for preventing the fixing unit 30 and the tension member (specifically, the end of the tension member in the vicinity of the fixing unit) from rusting and corroding. Reference numeral 45 denotes a lid for opening and closing the injection port 41. In addition, reference numeral 47 denotes a sealing member manufactured by rubber or the like and installed between the retaining wall segment 10 and the cap member 40 to prevent the waterproofing and leakage of the rust preventive agent in the cap member 40.

Hereinafter, the function, function and effect of the precast concrete retaining wall in which the tensile force is introduced according to the above-described embodiment will be described.

In the present embodiment, the retaining wall segment 10 is manufactured by a precasting method. When the retaining wall segment 10 is manufactured by the precasting method, the retaining wall segment 10 is pre-fabricated using a fixed facility in a factory. It is possible, there is an advantage that can improve the precision and strength compared to the concrete product installed in the field.

When the retaining wall segment 10 manufactured by the precast method comes to the construction site, the retaining wall segments 10 are arranged in a line, covered with a tube 25, and a rust inhibitor 29 is filled between the tubes 25. After the tension member 20 is inserted into the tension member through-holes 11 to penetrate the retaining wall segments 10, both ends of the tension member 20 are applied to the fixing unit 30 while the tension member is applied to the tension member 20. By fixing to the retaining wall segment 10. Thereafter, the sealing member 47 is installed, and the cap members 40 are respectively covered with the corresponding fixing units 30 and fixed to the retaining wall segment 10 with the bolts B. As shown in FIG.

As described above, when the tension member 20 is fixed in the tensioned state, prestress is applied to the retaining wall segment 10, and thus the retaining wall segments 10 may be very strongly integrated. And, when integrating the retaining wall segments 10 as described above, the projections 15 of each retaining wall segment 10 are fitted into the groove portions 17 of the other retaining wall segments, respectively, thereby retaining the wall retaining segment 10. Even if an external force is applied in the vertical direction or the front-rear direction, the relative movement between the retaining wall segments is effectively suppressed.

On the other hand, when a long time is elapsed after completion of the construction and the long tension is weakened by relaxation of the tension member 20, the compressive force applied to the retaining wall segments 10 by tensioning the tension members again (retaining wall segment 10). Cohesion between the two) can be enhanced, which will be described in more detail below.

In the case where the tension force of the tension member 20 is weakened and it is to be restrained, the cap member 40 is first removed by removing the bolt B from the retaining wall segment 10. Thereafter, as shown in Fig. 7, the wedge of the corresponding screw portion 101 of the tensioner 100 (only a part of the tensioner is shown in the drawing, which can be used a hydraulic tensioner generally used). After screwing on the threaded portion 333 of the plate 33, pulling the wedge plate 33 through the tensioner 101, the tension member 30 fixed to the wedge plate 33 by the wedge segment 32. The one end of) will be pulled together. At this time, the tension member 20 maintains a state in which corrosion is prevented by the rust preventive agents 29 and 49, so that cutting due to corrosion does not occur during tensioning. In addition, since the rust preventive agent 29 between the tube 25 and the tension member 20 is lubricated together with the rust preventive action, the tension member 20 can be easily rubbed without directly rubbing against the tube 25 or the retaining wall segment 10. It is to be tensioned. As the tension member 20 is tensioned as described above, the bonding force between the retaining wall segments 10 is increased. On the other hand, by pulling the wedge plate 33 with the tensioner 101, there is a gap between the wedge plate 33 and the fixing plate 31, the appropriate reinforcing plate 50 is inserted in the gap When placed, since the wedge plate 33 is prevented from being restored to its original position, the tension member 20 is maintained in the tensioned state. Thereafter, the tensioner 20 is separated from the wedge plate 33, and the cap member 40, which has been peeled off, is fixed to the retaining wall segment with a bolt B or the like so as to cover the fixing unit 30 again. After injecting the rust preventive agent 49 through the injection hole 41 and blocking the injection hole 41 with the lid 45, the retensioning operation of the tension member 20 is completed. If the tension member 20 is to be stretched again in order to increase the bonding force between the retaining wall segments 10 in the future, the above-described process may be repeated. That is, according to the configuration of the present embodiment, even after a long time after the completion of the construction, since the tension member 20 is kept in a state where corrosion is prevented by the rust inhibitors 29 and 49, the coupling force between the retaining wall segments 10 is weakened. At any time, the tension member 20 may be tensioned again to increase the bonding force between the retaining wall segments 10.

In the above-described embodiment, an embodiment having a fixing plate, a wedge segment, and a wedge plate having a threaded portion as the fixing unit 30 has been described. However, the technical idea of the present invention is necessarily the fixing plate, the wedge segment, and the screw unit. It is not limited to the embodiment with the wedge plate formed.

In addition, the shape of the retaining wall segment 10 is not limited to the shape shown in FIGS. 2 to 6 (English letter “L” shape). For example, as shown in FIG. 9, an English letter “T” shape retaining wall is shown. It is a matter of course that the retaining wall using the segments 10a can also be applied for the practice of the present invention. In this retaining wall segment 10a, portions having substantially the same or similar functions as those described with reference to FIGS. 2 to 6 are denoted by the same reference numerals and detailed description thereof will be omitted.

In addition, in the embodiment described with reference to FIGS. 2 to 8, as a rust preventive means for preventing rust on the tension member, a tube 25 filled with a rust preventive material was used, but is not limited thereto.

For example, as the anti-rust means, as shown in FIG. 10, a coating member 125 which is coated and attached to the outer circumference of the tension member 20 may be used. Since the covering member 125 is made of an epoxy material, it prevents the tension member 20 from contacting with air and prevents the tension member 20 from rusting, and when the tension member 20 is restrained, Stretched together in a state attached to the tension member 20 is to prevent rust in the tension member 20 even after the tension member 20 is re-tensioned.

Although preferred embodiments of the present invention have been described above, the technical spirit of the present invention is not limited to the described embodiments, and various forms of precast concrete are introduced within a range that does not contradict the technical spirit of the present invention. It will be apparent to those skilled in the art that the retaining wall can be implemented.

1 is a view showing an example of a conventional precast concrete retaining wall.

Figure 2 is a view for explaining a precast concrete retaining wall introduced tension in accordance with an embodiment of the present invention.

3 is a cross-sectional view taken along line III-III shown in FIG. 2;

4 is a cross-sectional view taken along the line IV-IV shown in FIG. 2;

FIG. 5 is a view showing the segments of some of the retaining wall segments shown in FIG. 2 in a separated state; FIG.

FIG. 6 is a cross sectional view taken along the line VI-VI shown in FIG. 5; FIG.

7 and 8 are views for explaining the re-tension process of the tension member.

Figure 9 is a view for explaining a precast concrete retaining wall introduced tension in accordance with another embodiment of the present invention.

10 is a view showing another example of the rust preventing means for preventing rust on the tension member.

** Explanation of symbols for the main parts of the drawing **

10: retaining wall segment 11: tension material through hole

12: bottom portion 13: wall portion

20: tension member 25: tube

29: antirust agent 30: fixing unit

40: cap member 49: antirust agent

Claims (4)

It is manufactured by using reinforced concrete as a material, and several are connected to each other to form a long retaining wall in one direction. The retaining wall extends from a bottom portion and a bottom portion having a tension member through hole in a longitudinal direction, and extends from the bottom portion. A retaining wall segment including a wall surface portion having a tension material through hole of the retaining wall segment; A tension member inserted into the tension member through hole of the retaining wall segment; A fixing part provided in each of the retaining wall segments positioned at both ends of the retaining wall in the lengthwise direction of the retaining wall segment in a state in which the tension member is tensioned to apply the compressive force to the retaining wall segments; Antirust means consisting of a tube to be covered on the outer periphery of the tension member, and a rust inhibitor filled in the inside of the tube, to prevent rust on the tension member; And And a cap member which is covered with the fixing unit, and has a cap member filled therein for preventing rust of an end portion of the tension member near the fixing unit. A plurality of protrusions are formed on one side wall of each retaining wall segment, and a plurality of grooves are formed on the other side of the retaining wall segments, each of which includes a plurality of protrusions formed on another retaining wall segment adjacent to the retaining wall segment. When the compressive force applied to the retaining wall segments is weakened, the precast concrete having a tension force configured to re-tension the tension prevented by the rust preventive means to reinforce the compressive force applied to the retaining wall segments. Retaining wall. delete delete It is manufactured by using reinforced concrete as a material, and several are connected to each other to form a long retaining wall in one direction. The retaining wall extends from a bottom portion and a bottom portion having a tension member through hole in a longitudinal direction, and extends from the bottom portion. A retaining wall segment including a wall surface portion having a tension material through hole of the retaining wall segment; A tension member inserted into the tension member through hole of the retaining wall segment; A fixing part provided in each of the retaining wall segments positioned at both ends of the retaining wall in the lengthwise direction of the retaining wall segment in a state in which the tension member is tensioned to apply the compressive force to the retaining wall segments; Antirust means made of a coating member of the epoxy material coated on the outer periphery of the tension member, to prevent rust on the tension member; And And a cap member which is covered with the fixing unit, and has a cap member filled therein for preventing rust of an end portion of the tension member near the fixing unit. A plurality of protrusions are formed on one side wall of each retaining wall segment, and a plurality of grooves are formed on the other side of the retaining wall segments, each of which includes a plurality of protrusions formed on another retaining wall segment adjacent to the retaining wall segment. When the compressive force applied to the retaining wall segments is weakened, the precast concrete having a tension force configured to re-tension the tension prevented by the rust preventive means to reinforce the compressive force applied to the retaining wall segments. Retaining wall.

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