KR100640716B1 - Precast concrete block for cantilever retaining wall and construction method using the same - Google Patents

Abstract

A reversed T-shape precast concrete retaining wall block and a construction method using the same are provided to easily construct the block and to improve the stability by integrally connecting a wall part and a base plate in a fixing connection method. A reversed T-shape precast concrete retaining wall block includes a leveling concrete(400) poured at both sides of the upper part of the ground between excavated landfill grooves(2) at the same predetermined depth as the wall and manufactured in a precast method; first and second base parts(100a,100b) separated from each other as long as the wall width at the upper part of the leveling concrete, wherein base plate PS steel wire holes(120) of the width direction correspond to each other at predetermined intervals; a wall part(200) made of precast concrete, wherein a connection unit surface-contacted with the first and second base parts is formed with wall PS steel wire holes communicated with the base plate PS steel wire holes; and PS steel wires mounted at the fixing hole to pass through the base plate and wall PS steel wire holes. A connection device(230) is further included to mutually connect the walls at the connection unit.

Description

Precast concrete block for cantilever retaining wall and construction method using the same

1 is a perspective view illustrating a conventional general precast subwall retaining wall.

Fig. 2 is a perspective view showing a precast subwall retaining wall disclosed in Korean Utility Model Registration No. 20-0404658.

3 is a cross-sectional view showing an inverted T-type precast retaining wall block according to the present invention.

4 is a perspective view showing an inverted T-type precast retaining wall block according to the present invention.

5A to 5E are construction views showing a construction method of an inverted T-type precast retaining wall block according to the present invention.

* Explanation of symbols for main parts of the drawings

1: excavation ground 2: landfill home

100: base plate 100a, 100b: first and second base plate

110, 120: base plate PS steel wire hole 200: wall portion

210: wall PS steel wire hole 230: connection means

231, 232: connection groove 233, 234: wall connection material

235: coupler 236: connecting groove filler

300: PS steel wire 310: anchorage

320: filling material 330: anchor filler

400: leveling concrete

The present invention relates to an inverted T-type retaining wall block and a construction method of the retaining wall design most used in detail, which is manufactured as a precast retaining wall block in the factory in which the connection of the wall part and the foundation part in the field is integrally constructed by a fixed connection method. A precast inverted-T retaining wall block and its construction method are provided.

In general, retaining wall construction such as slopes of roads and railways, slopes of park areas, river embankments, coastal roads, and slopes of residential areas has been mainly constructed with cast-in-place concrete (hereinafter referred to as 'RC retaining walls'). In other words, the retaining wall construction has been constructed as a site wet construction in which reinforcing bars and formwork are installed and concrete is poured. In this way, the inverted T-type retaining wall was most used as the retaining wall.

Typical construction methods of RC retaining wall go through the process of ground excavation, foundation concrete placement, reinforcing steel reinforcement, body concrete placement, and backfilling. In addition, when the height of the wall portion is high, it may occur that the concrete pouring of the body cannot be poured at once. As described above, the conventional RC retaining wall construction directly performs all the work in the field, and thus has the following problems.

Conventional RC retaining wall construction should perform the reinforcement work of the reinforcement with reference to the reinforcement of the RC retaining wall in the site, and after installing the formwork, the concrete is poured. At this time, the curing period of about 7 days or more is required to maintain the strength for the concrete, and after the curing is completed, the formwork is dismantled. Accordingly, the conventional RC retaining wall construction has a problem in economical and constructability because it takes several steps of construction process and a long construction period. In addition, due to the construction method as described above, there is a high possibility of civil complaints due to long-term vehicle traffic blocking and securing a detour road, and there is a disadvantage in terms of stability since there is a problem of exposure to danger for a long time.

Due to these problems, the use of precast concrete retaining walls (hereinafter referred to as 'PC retaining walls') is gradually increasing in consideration of constructionability, economic feasibility, and the possibility of civil complaints. The PC retaining wall is very effective in construction because the retaining wall block is manufactured at the factory and only assembled at the site, and the possibility of civil complaints can be minimized.

Conventionally, the oldest precast subwall retaining wall is shown in FIG. The conventional precast subwall retaining wall is constructed by installing precast concrete blocks manufactured in a factory in the field, and precast concrete retaining wall block wall parts 20a, 20b, 20c, 20d, and 20e are assembled in horizontal and vertical directions. It installs, and the support body 30 which has a kind of sub-wall function is installed inclined between a wall part and a base plate. However, this method has a disadvantage in that it is not excellent in workability compared to the RC concrete because it is installed a plurality of supports 30 on the entire rear wall separately as shown in FIG.

In order to improve this problem, the Korean Utility Model Registration No. 20-0404658 has disclosed a new PC retaining wall as shown in FIG. The PC retaining wall 10 according to the registration utility model forms a rectangular U-shaped shear groove 11a on the upper surface of the precast rectangular base plate 11, and the precast panel wall portion (11) in the shear groove 11a. The lower part of the 12 is installed to be inserted, and the sub-wall part 13 for supporting the lower part of the wall part 12 is installed on the rear surface of the shear groove 11a of the base plate 11.

However, in the above method, when a subwall retaining wall is required and construction and site conditions match, some commercially available subwall PC retaining walls may be used. However, when the site and construction conditions are different as follows, use is limited.

That is, the subwall retaining wall cannot add the activity blocking wall most commonly used in RC retaining wall if the retaining wall to be installed is unstable to the activity. Accordingly, it is necessary to secure safety for activities by increasing the basic cross section, which is not a desirable method in terms of economic feasibility. In general, subwall retaining walls are retaining walls that can be used in high retaining walls with a retaining wall height of 7-8 m or more. This is because the sub-wall retaining wall is disadvantageous in terms of economy in the inverted T-shaped retaining wall which is most commonly used. Therefore, the above-mentioned conventional design can be said to be uneconomical in terms of economics for use in a low-height retaining wall.

In addition, when looking at the structural aspect, the hinge connection method of simply inserting and fixing the precast panel-shaped wall portion 12 into the shear groove 11a formed on the upper surface of the base plate 11 has the greatest moment in the retaining wall. In view of the fact that the part to be connected to the base portion and the wall portion has a disadvantage that is structurally undesirable.

The present invention is to solve the problems as described above, the object of the present invention is to install the wall part and the base plate by precast concrete block method, but the connection between the wall part and the base plate that the greatest moment is generated It is an object of the present invention to provide an inverted T-type precast retaining wall block and a construction method thereof that are easy to install, and have excellent structural safety and economy by integrally installing a hinged connection instead of a hinged connection.

Another object of the present invention is to provide a precast concrete retaining wall block capable of installing a shear key, and a construction method thereof, in order to increase resistance to activities not seen in the conventional precast retaining wall.

In order to achieve the above object, the present invention is an inverted T-type precast concrete retaining wall block, in which the site is placed on both sides of the ground or precast by assembling construction with the recessed grooves interposed a predetermined depth by the width of the retaining wall wall. Leveling concrete; First and second base plates which are made of precast concrete separated in both sides and are spaced apart from each other by the width of the wall on the leveling concrete, and the base plate PS steel wire holes in the width direction correspond to each other at predetermined intervals; A wall portion formed of precast concrete and having a lower portion embedded in the buried groove in a vertical direction, and having a connection portion in which the first and second base plates are interviewed, a wall PS steel wire hole communicating with the base plate PS steel hole; And a PS steel wire which is penetrated by the base plate PS steel wire hole and the wall PS steel wire hole and is tensioned.

In addition, the inverted T-type precast concrete retaining wall block construction method according to the present invention is to dig the ground on which the retaining wall is to be installed, and to form a wall recessed groove to a predetermined depth by the width of the retaining wall wall, and then leveling concrete on site A first step of assembling construction; Precast concrete separated on both sides inside the first and second base plate formed in the width direction base plate PS steel wire hole corresponding to each other at predetermined intervals spaced apart by the wall gap on the leveling concrete with the buried groove between A second step of installing; Installed in such a way that the bottom portion is embedded in the buried groove by penetrating the wall portion formed with the wall PS steel wire hole between the first and second base plates at a position where the first and second base plates are interviewed. A third step of doing; And a fourth step of penetrating and tensioning the PS steel wire in the base plate PS steel wire hole and the wall PS steel wire hole, and then fixing it in the anchorage.

Hereinafter, an inverted T-type precast concrete retaining wall block according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a cross-sectional view showing an inverted T-shaped precast retaining wall block according to the present invention, Figure 4 is a perspective view showing an inverted T-shaped precast retaining wall block according to the present invention, Figures 5a to 5e is in accordance with the present invention It is a construction trial drawing showing the construction method of an inverted T type precast retaining wall block.

Inverted T-type precast retaining wall block according to the present invention as shown in Figure 3 is the PS steel wire 300 after the precast concrete wall 200 is inserted into the ground to a predetermined position through the precast concrete base plate 100 It is a retaining wall block that integrates the base plate and the wall using.

The base plate 100 is manufactured by dividing into a first base plate 100a and a second base plate 100b on the basis of the point where the precast concrete wall 200 penetrates, and the first base plate ( Inside the 100a) and the second base plate 100b, the base plate PS steel wire holes 110 and 120 in the width direction are formed to correspond to each other at predetermined intervals. The overall cross-sectional shape of the base plate 100 is manufactured in a shape in which the upper surface thereof is made smaller in thickness toward both ends with respect to the wall part 200. This was determined in consideration of the structural aspects and the influence of drainage on the base plate, but is not limited to the shape.

The first base plate 100a and the second base plate 100b manufactured as described above are transferred to the site and installed on the leveling concrete upper part 400. The leveling concrete 400 is to be placed on the ground on which the retaining wall is to be constructed or to be assembled and manufactured by precast. After forming 2), it is cast or assembled on both sides in the upper part of the ground on which the retaining wall is to be installed with the buried groove 2 therebetween.

The wall portion 200 is made of precast concrete and is installed between the first base plate (100a) and the second base plate (100b), that is, a predetermined depth buried in the buried groove 20 in a vertical direction, A wall PS steel wire hole 210 communicating with the base plate PS steel wire holes 110 and 120 is formed at a position where the first and second base plates 100 a and 100 b are interviewed. The overall cross-sectional shape of the wall portion 200 is formed in a shape in which the lower end portion inserted into the base plate 100 is formed in a straight line and narrows gradually from the lower portion to the upper portion.

In this case, the wall part 200 may be manufactured in the unit by manufacturing the block unit divided into the upper and lower parts in multiple stages in consideration of transportation, and for this purpose, each of the upper and lower ends corresponding to each other ) To form a portion 221 and the iron (222) 222 to be assembled to each other. In addition, the wall portion 200 is the yaw portion 223 and the iron at positions respectively corresponding to the left and right side of the wall portion 200 to reinforce the longitudinal connection between the walls, respectively. It is preferable to form a portion 224 to be assembled to each other to function as a shear key. At this time, it is preferable to further include a separate connecting means 230 for reinforcing the connection portion in the adjacent surface interconnected between the wall blocks.

The connection means 230 is a connection groove (231, 232 of Fig. 5d) is formed to correspond to the adjacent surface between the wall blocks, as shown in Figure 5e, one end is already embedded in the wall and the other end is the connection groove Wall couplers 233 and 234 formed to partially protrude into 231 and 232 and couplers 235 for connecting the wall connectors 233 and 234 from both sides, and the coupler 235 after the coupler 235 is connected. Consists of a connection groove filling material 236 is poured into.

The PS steel wire 300 is a wall PS steel wire hole formed in the base plate PS steel wire holes (110, 120) and the wall portion 200 formed in the first base plate (100a) and the second base plate (100b) ( After being penetrated by the 210 and tensioned, it is fixed to the fixing unit 310 formed on the outer surfaces of the first base plate 100a and the second base plate 100b. At this time, the layout of the PS steel wire 300 is determined in consideration of the height of the retaining wall and the thickness of the base plate, and the spacing and the number of installation stages (one or two stages) in the longitudinal direction of the retaining wall.

At this time, more preferably, after tensioning the PS steel wire 300, the base plate PS steel wire holes 110, 120 and the wall PS steel wire hole 210 inside the mortar to integrate the hole and the steel wire, etc. Filling the filler 320 to fill the inside of the hole, the fixing unit 310 is embedded in the ground and finished by filling the filler 330, such as mortar or epoxy to prevent corrosion.

The present invention constituted as described above by integrally constructing the connection of the base plate 100 and the wall portion 200 is generated by the fixed connection method using the PS steel wire 300 instead of the conventional hinge connection method is generated the greatest moment In addition, construction is easy and structural safety can be increased. In addition, a part of the penetrating wall portion 200 serves as an activity blocking wall of the retaining wall, so that it can effectively respond to the activity of the retaining wall.

Hereinafter, an inverted T-type precast concrete retaining wall block construction method according to an embodiment of the present invention will be described in detail with reference to FIGS. 5A to 5E.

FIG. 5A shows the process of placing the trench 1 and the leveling concrete 400 of the ground on which the retaining wall is to be installed. First, the trench is to be excavated (1) on the ground on which the retaining wall is to be installed, and the wall is filled with a predetermined depth by the width of the retaining wall. After the groove 2 is formed, the leveling concrete 400 is cast or assembled on site.

5B illustrates a step of installing the base plate 100, with the first base plate 100a and the second base plate 100b interposed between the wall filling groove 2 on the leveling concrete 400. Install at a distance from the wall. At this time, the first base plate (100a) and the second base plate (100b) is installed so as to communicate with each other while confirming the position of the base plate PS steel wire holes (110, 120) formed therein.

5C illustrates a step of installing the wall part 200. The wall part 200 penetrates between the first base plate 100a and the second base plate 100b so that a lower end thereof is embedded in the buried groove 2. 200). At this time, the wall PS steel wire hole 210 formed in the wall portion 200 is installed while adjusting to match the position of the base plate PS steel wire holes (110, 120).

Figure 5d shows the PS steel wire tension step, and when the base plate 100 and the wall portion 200 is completed by the above, the base plate PS steel wire holes 110 and 120 of the base plate 100 and The PS steel wire 300 penetrates the wall PS steel wire hole 210 of the wall part 200. Thereafter, the PS steel wire 300 is tensioned and fixed to the fixing unit 310 formed on the outer surface of the wall. At this time, more preferably, after tensioning the PS steel wire 300, the base plate PS steel wire holes 110, 120 and the wall PS steel wire hole 210 inside the mortar to integrate the hole and the steel wire, etc. Fill the filler 320 to fill the inside of the hole. In addition, the fixing unit 310 is finished by pouring a filler 330, such as mortar or epoxy, to prevent corrosion is buried in the ground. The detail A of FIG. 5D shows the details of the fixing unit 310, and the detail B shows the details of the PS steel wire 300 passing through the wall part 200 and the base part 100.

FIG. 5E illustrates a step of installing connecting means for reinforcing the joint surface between precast concretes. Detail A of FIG. 5E shows detail of height connection between walls, and detail B shows detail of retaining wall longitudinal connection between walls. It is. Meanwhile, detail C of FIG. 5E illustrates a shear key shape for the longitudinal connection of the wall part 100. When the base part 100 and the wall part 200 are integrated by the above steps, the joint surface between the precast retaining wall blocks is fixed to each other using a separate connection means. In this case, the longitudinal retaining wall joining surface is preferably subjected to waterproofing 500 such as epoxy resin.

After that, the PC retaining wall installation is completed through the above series of tasks, and the back retaining work and the surrounding restoration work are performed to complete the PC retaining wall work.

On the other hand, the present invention described above has been described with respect to specific embodiments, of course, various modifications are possible without departing from the scope of the invention. That is, the present invention is not limited to the above-described embodiments and the accompanying drawings, and it is common in the art that various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

According to the present invention as described above, the wall portion and the base plate is installed by assembling the precast concrete block method, but the connection between the wall portion and the base plate that generates the greatest moment in a fixed connection method rather than the conventional hinge connection method By integrated construction, the construction is easy and has the effect of excellent structural safety and economic efficiency.

In addition, unlike the conventional precast retaining wall, the present invention has an advantage in that an installation of a shear key that can increase the resistance to activity is possible.

Claims (5)

In the inverted-T precast concrete retaining wall block, A leveling concrete that is casted on both sides of the ground or manufactured by precast and assembled in the upper part of the ground with a buried groove that is excavated a predetermined depth by the width of the retaining wall wall; First and second base plates which are made of precast concrete separated in both sides and are spaced apart from each other by the width of the wall on the leveling concrete, and the base plate PS steel wire holes in the width direction correspond to each other at predetermined intervals; A wall portion formed of precast concrete and having a lower portion embedded in the buried groove in a vertical direction, and having a connection portion in which the first and second base plates are interviewed, a wall PS steel wire hole communicating with the base plate PS steel hole; And Inverted T-type precast concrete retaining wall block, characterized in that it comprises a PS steel wire penetrated in the base plate PS steel wire hole and the wall PS steel wire hole and then fixed to the anchorage The method of claim 1, The wall portion The yaw part and the iron part are respectively formed at positions corresponding to the top, bottom, or left and right ends, respectively, and are assembled and fitted together. The connection part further includes connecting means for interconnecting the walls. Inverted T-type precast concrete retaining wall block, characterized in that The method of claim 2, The connecting means includes a connecting groove formed to correspond to the adjacent surface between the wall blocks, one end is already embedded in the wall and the other end is a wall connecting member formed to partially protrude into the connecting groove, couplers for connecting the wall connecting members from both sides; Inverted T-type precast concrete retaining wall block, characterized in that it comprises a connecting groove filling material which is poured into the connecting groove after the coupler is fastened. In the construction method of the inverted T-shaped precast concrete retaining wall block, A first step of digging the ground on which the retaining wall is to be installed, forming a wall recessed groove with a predetermined depth by the width of the retaining wall wall, and then placing or assembling the leveling concrete on the top; Precast concrete separated on both sides inside the first and second base plate formed in the width direction base plate PS steel wire hole corresponding to each other at predetermined intervals spaced apart by the wall gap on the leveling concrete with the buried groove between A second step of installing; The bottom portion is embedded in the buried groove by passing a wall portion formed with the wall PS steel wire hole between the first and the second base plate at a position where the first and second base plates are in contact with each other. A third step of installing; And Inverted T-type precast concrete retaining wall block construction method comprising the step of penetrating and tensioning the PS steel wire in the base plate PS steel wire hole and the wall PS steel wire hole, and then fixed to the anchorage The method according to claim 4, Inverted T-type precast concrete retaining wall block construction method further comprises a fifth step of interconnecting the left, right or upper and lower ends of the wall using a connecting means to reinforce the junction of the wall portion

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