KR102570497B1 - PC abutment wall and concrete foundation hinge joining construction method and structure - Google Patents

Abstract

The present invention minimizes the bending moment acting on the foundation while securing the conduction stability of the PC alternating wall, but the construction method for connecting the PC alternating wall and the foundation so that the construction for the hinge structure is easy and the wall arrangement is simple, and its Provides a linking structure. In the connection construction method between the PC alternating wall and the foundation according to a preferred embodiment of the present invention, (a) a pad seating groove recessed with a predetermined depth (h1) along the width direction on the upper surface of the foundation or a predetermined height (h2) ) and a protruding pad seating protrusion, one end embedded and fixed to the concrete layer of the foundation and the other end having a pad seating groove or a pad seating protrusion rising from the pad seating protrusion and having a shear connector disposed on the ground. ; (b) installing a plate-shaped first elastic pad made of rubber or EVA on the bottom of the pad seating groove or on the upper surface of the pad seating protrusion; (c) installing stirrup reinforcing bars reinforced at regular intervals and longitudinal reinforcing bars reinforced along the circumference of the stirrup reinforcing bars by inserting the shear connector into the upper part of the first elastic pad and walking; (d) The PC alternating wall having a concrete filling groove at the bottom is lifted and its lower end is seated on the upper surface of the first elastic pad, the PC steel bar is inserted into the lower end of the PC alternating wall and the shear connector, and then the steel bar fastening nut is inserted into the PC Screwing both ends of the steel rod; (e) pouring concrete into the concrete filling groove formed at the lower end of the PC alternating wall to synthesize the shear connector, PC steel bar, stirrup reinforcing bar and longitudinal reinforcing bar with concrete; characterized in that the construction is performed.

Description

Hinge connection construction method of PC abutment wall and foundation, its connection structure and ramen bridge {PC abutment wall and concrete foundation hinge joining construction method and structure}

The present invention relates to a connection construction method between a PC (Precast) abutment wall and a foundation of a bridge and a connection structure thereof. It relates to a connection construction method of a PC alternating wall and a foundation and its connection structure.

In general, ramen bridges have a problem in that the size of the foundation increases because the bottom of the wall and the foundation are connected with reinforced concrete, and member forces (axial force, shear force, bending moment) acting on the upper structure and the wall are transmitted to the foundation.

Therefore, a ramen bridge is being developed that can reduce the size of the foundation by separating the connection structure of reinforced concrete, which is the main material connecting the bottom of the wall and the foundation, to induce a behavior similar to that of a hinge device, thereby preventing the transfer of the bending moment among member forces to the foundation.

While these ramen bridges can obtain advantages such as economic feasibility and shortening of the construction period by reducing the size of the foundation, there is a problem in that they are somewhat lacking in safety in terms of construction.

For example, in the case of a hinged ramen bridge in which both the wall and the foundation are made of precast, there is a concern about a fall accident of the wall before the upper structure is integrated with the wall. This is because the overturning stability of the wall was not secured prior to installation and connection of girders during construction.

In addition, due to the rotational displacement of the wall during use, the corner of the lower end of the wall collides with the upper surface of the foundation, resulting in strong stress concentration in the corner of the lower end of the wall, so that breakage easily occurs.

Therefore, it is necessary to find a connection method that has a structure in which the wall is separated from the foundation and secures the conduction stability of the wall.

The background technology of the present invention includes Korea Patent Registration No. 10-1007708 (semi-hinge ramen bridge and its construction method), the same registration number 10-1836326 (ramen structure and its construction method), and the same registration No. 10-2153426 (Connected slab integral type and ramen bridge with minimized foundation size and its construction method) is proposed. These background arts configure a hinge between the wall and the foundation so that the moment is not transmitted to the foundation. However, these background arts do not suggest a solution to the wall conduction problem in the construction stage.

On the other hand, as other technologies that are the background of the present invention, Korea Patent Registration No. 10-1991930 (Ramen Bridge and its construction method) and No. 10-1714159 (Bending moment transmission separation device equipped with a fall prevention device and using the same) Ramen bridge) mentions the problem of wall conduction, but the wall-base is fixed using a coupler during construction to prevent the wall from overturning during construction and construction of the bottom plate hinge. However, the former background technology has the disadvantage of not being able to handle the hinge of the coupler after completion of construction when the back of the wall is piled up, and the construction difficulty is high, and the latter background technology has the disadvantage of poor manufacturability of the hinge device and complicated wall arrangement there is.

Korea Patent Registration No. 10-1007708 Korea Patent Registration No. 10-1836326 Korea Patent Registration No. 10-2153426 Korea Patent Registration No. 10-1991930 Korea Patent Registration No. 10-1714159

The purpose of the present invention is to provide a construction method for connecting a PC alternating wall and a foundation and a connection structure thereof to ensure economic feasibility by minimizing the bending moment acting on the foundation and to secure the conduction stability of the PC alternating wall during construction. there is.

In the connection construction method between the PC alternating wall and the foundation according to a preferred embodiment of the present invention, (a) a pad seating groove recessed with a predetermined depth (h1) along the width direction on the upper surface of the foundation or a predetermined height (h2) ) and a protruding pad seating protrusion, one end embedded and fixed to the concrete layer of the foundation and the other end having a pad seating groove or a pad seating protrusion rising from the pad seating protrusion and having a shear connector disposed on the ground. ; (b) installing a plate-shaped first elastic pad made of rubber or EVA on the bottom of the pad seating groove or on the upper surface of the pad seating protrusion; (c) installing stirrup reinforcing bars reinforced at regular intervals by being inserted into the shear connector above the first elastic pad and longitudinal reinforcing bars reinforced along the inner circumference of the stirrup reinforcing bars; (d) The PC alternating wall having a concrete filling groove at the bottom is lifted and its lower end is seated on the upper surface of the first elastic pad, the PC steel bar is inserted into the lower end of the PC alternating wall and the shear connector, and then the steel bar fastening nut is inserted into the PC Screwing both ends of the steel rod; (e) pouring concrete into the concrete filling groove formed at the lower end of the PC alternating wall to synthesize the shear connector, PC steel bar, stirrup reinforcing bar and longitudinal reinforcing bar into concrete; including, in step (a) , The shear connector is characterized in that it includes a lower support plate buried at a certain depth on the upper surface of the foundation, a vertical connecting plate installed vertically on the lower support plate and having reinforcement holes and steel bar insertion holes penetrated at different positions at regular intervals from each other .

delete

In addition, in the step (d), an outer liner is installed between both ends of the first elastic pad and the vertical inner surface of the pad seating groove, and a waterproof function and a stretch function are provided at the corner where the outer liner material and the first elastic pad meet. It is characterized in that the inner liner having is further installed.

In addition, in the step (d), an outer liner material and an inner liner material having a waterproof function and a stretch function are further installed between the both sides of the pad seating protrusion and the inner surface of the concrete filling groove by interviewing.

In addition, in the step (e), the concrete is characterized in that on-site injection is performed through a cast-in-place injection passage formed in the PC alternating wall and communicating in a vertical direction with the concrete filling groove.

In addition, in the step (d), a wall support ledge formed by a step on both sides is further formed at the lower end of the PC alternating wall, and a second elastic pad is additionally installed between the wall support ledge and the upper surface of the foundation to construct characterized by

In addition, it is characterized in that a second elastic pad is additionally installed and constructed between the lower end of the PC alternating wall and the upper surface of the foundation, respectively.

On the other hand, in the connection structure between the PC alternating wall and the foundation according to an embodiment of the present invention, a foundation having a pad seating groove recessed with a predetermined depth along the width direction is installed on the upper surface, and one end is the concrete layer of the foundation. A shear connector is installed, the other end of which is embedded and fixed at a certain height from the bottom of the pad seating groove, and a first elastic pad made of rubber or EVA in a plate shape is installed on the bottom of the pad seating groove. An outer ordering material is installed between both ends of the first elastic pad and the vertical inner surface of the pad seating groove, and an inner ordering material having a waterproof function and a stretch function is installed at the corner where the outer ordering material and the first elastic pad meet. Stirrup reinforcing bars reinforced at regular intervals by being inserted into the shear connector to the upper part of the elastic pad and longitudinal reinforcing bars reinforced along the inner circumference of the stirrup reinforcing bars are installed, and a PC alternating wall having a concrete filling groove at the bottom is provided 1 It is seated and supported on the upper surface of the elastic pad, and the PC steel bar is inserted into the lower part of the PC abutment wall and the shear connector, and the steel bar fastening nuts are fastened at both ends to be fixed to the PC abutment wall, and the concrete filling groove formed at the bottom of the PC abutment wall It is characterized in that concrete is poured into the shear connector, PC steel bar, stirrup reinforcing bar and longitudinal reinforcing bar are composited with concrete.

Here, at the lower end of the PC alternating wall, wall support formed by the step (S) is further formed on both sides, and a second elastic pad is additionally installed between the wall support and the upper surface of the foundation.

In addition, in the connection structure between the PC alternating wall and the foundation according to another embodiment of the present invention, a foundation having a pad seating protrusion protruding with a predetermined height along the width direction is installed on the upper surface, and one end is the concrete layer of the foundation. A shear connector is installed, the other end of which is embedded and fixed at a certain height from the upper surface of the pad seating protrusion, is installed, a first plate-shaped elastic pad made of rubber or EVA is installed on the upper surface of the pad seating protrusion, and the pad seating protrusion Between the both sides of the pad and the vertical inner surface of the pad seating groove, an outer ordering material and an inner ordering material having waterproof and elastic functions are interviewed and installed, and inserted into the shear connector to the top of the first elastic pad and placed at regular intervals by walking. Stirrup reinforcing bars and longitudinal reinforcing bars reinforced along the circumference of the stirrup reinforcing bars are installed, a PC alternating wall having a concrete filling groove at the bottom is seated and supported on the upper surface of the first elastic pad, and a PC steel bar is installed on the upper surface of the PC alternating wall. After inserting the lower part and the shear connector, the steel bar fastening nuts are fastened at both ends and fixedly installed on the PC alternating wall, and the concrete is poured into the concrete filling groove formed at the lower end of the PC alternating wall, and the shear connector, PC steel bar, stirrup reinforcing bar and longitudinal It is characterized in that the directional rebar is synthesized with concrete.

According to the connection construction method of the PC alternating wall and the foundation and the connection structure thereof of the present invention, the PC alternating wall is connected to the foundation through the PC steel bar and the shear connector and at the same time is transmitted to the foundation because it forms a separate hinge structure through the elastic pad Bending moment can be minimized. Of course, by minimizing the bending moment transmitted to the foundation, it has economic feasibility by reducing the dimensions of the foundation.

In addition, since the PC steel bar is inserted into the PC alternating wall and connected to the foundation-side shear connector, the conduction stability of the wall can be secured. By securing such conduction stability, the construction period of the ramen bridge can be shortened by placing the concrete poured and filled in the lower part of the PC abutment wall and the upper slab and right angle concrete together.

In addition, after installing the elastic pad, the PC alternating wall is seated on the elastic pad, and the PC steel rod is connected to the shear connector to have a hinge structure, so construction is easy.

In addition, it has the advantage of simple and easy installation with a structure in which longitudinal reinforcing bars are placed around the stirrup reinforcing bars through the shear connector before installation of the PC alternating wall.

The following drawings attached to this specification illustrate a preferred embodiment of the present invention, and together with the detailed description of the present invention serve to further understand the technical idea of the present invention, the present invention is limited to those described in the accompanying drawings. It should not be construed as limiting.
1 is a cross-sectional view of a coupled state between a PC alternating wall and a foundation according to a first embodiment of the present invention.
Figure 2 is a perspective view of a hinge device applied to the connection structure between the PC alternating wall and foundation of Figure 1;
Figures 3a to 3d is a construction flow chart for the connection between the PC alternating wall and foundation of Figure 1.
Figure 4 (a), (b), (c) is an exemplary view showing various cross-sectional shapes of the shear connector applied to the present invention.
Figure 5a is a cross-sectional view of a coupled state between the PC alternating wall and the foundation according to the second embodiment of the present invention.
Figure 5b is a perspective view of a hinge device applied to the connection structure between the PC alternating wall and foundation of Figure 5a.
Figure 6a is a cross-sectional view of a coupled state between the PC alternating wall and the foundation according to a third embodiment of the present invention.
Figure 6b is a perspective view of a hinge device applied to the connection structure between the PC alternating wall and foundation of Figure 6a.
7 is an exemplary view of a ramen bridge constructed by applying the connection structure between the PC alternating wall and foundation of the present invention.

Below, the present invention will be described in detail with reference to the embodiments presented in the accompanying drawings, but the presented embodiments are illustrative for a clear understanding of the present invention, and the present invention is not limited thereto.

<First Embodiment>

The connection structure between the foundation and the PC wall according to the first embodiment is shown in FIG. 1, and FIG. 2 is a perspective view of the hinge device applied to the connection structure between the PC alternating wall and the foundation in FIG. The construction method for having a connection structure between the PC alternating wall and the foundation will be sequentially described below.

Foundation construction and installation of shear connectors

First, as shown in FIG. 3A, after pouring and curing the abandoned concrete 7 on the ground 5, the foundation 12 is constructed on the upper surface of the abandoned concrete 7. In the foundation 12, reinforcing bars (not shown) are placed on the concrete layer. The foundation 12 is constructed to have a pad seating groove 121 recessed with a predetermined depth h1 along the width direction on the upper surface. In addition, a shear connector 14 is installed on the foundation 12, one end of which is embedded and fixed to the concrete layer of the foundation 12 and the other end is disposed in the center of the pad seating groove 121 so as to rise from the bottom at a certain height. .

As shown in FIG. 2, the shear connector 14 is vertically installed on the lower support plate 141 and the lower support plate 141, which are buried at a certain depth on the upper surface of the foundation 12, and penetrated at different positions at regular intervals. (142a) and a vertical connecting plate 142 having a steel rod insertion hole (142b). Therefore, the shear connector 14 may have a ⊥-shaped cross-section, an I-shaped cross-section, and a c-shaped cross-section, as shown in (a), (b), and (c) of FIG. 4 .

Installation of the first elastic pad

Then, as shown in FIG. 3B, a plate-shaped first elastic pad 16 made of rubber or EVA is installed on the bottom of the pad seating groove 121. The first elastic pad 16 elastically supports the lower end of the PC alternating wall 30 . Therefore, the first elastic pad 16 partially absorbs the bending moment of the PC abutment wall 30, minimizes the bending moment transmitted to the foundation 12, and simultaneously serves to prevent damage due to surface contact between concrete. .

Reinforcement

Then, as shown in FIGS. 2 and 3B, the stirrup reinforcement 19 is reinforced at regular intervals by inserting it into the shear connector 14 to the top of the first elastic pad 16, hanging or welding, and stirrup reinforcement 19 ) Install the longitudinal reinforcement 20 along the circumference of the reinforcement. As the stirrup reinforcing bar 19 is connected to the shear connector 14, the stirrup reinforcing bar 19 has a structure connected to the foundation 12 via the shear connector 14.

Installation of PC alternating wall (30) and PC steel bar (22)

Then, as shown in FIG. 3c, the PC alternating wall 30 is lifted and its lower end is seated on the upper surface of the first elastic pad 16. The PC alternating wall 30 has a concrete filling groove 301 and a steel bar insertion hole 303 penetrating the concrete filling groove 301 in a right angle direction at the bottom. In addition, the PC alternating wall 30 has a wall steel bar insertion hole 303 penetrated in the thickness direction of the wall 30 at the bottom and a block-out groove for embedding a nut communicating with both sides of the wall steel bar insertion hole 303. (304).

Therefore, the load of the PC alternating wall 30 is transmitted to the base 12 through the first elastic pad 16, and the base 12 supports the PC alternating wall 30 via the first elastic pad 16. do. In addition, the stirrup reinforcing bar 19 and the longitudinal reinforcing bar 20 are located inside the concrete filling groove 301.

Here, an outer ordering material 17 is installed between both ends of the first elastic pad 16 and the vertical inner surface of the pad seating groove 121, and the outer ordering material 17 and the first elastic pad 16 are An inner liner 18 having a waterproof function and a stretch function may be further installed at the meeting corner. In this case, the bottom corner of the PC alternating wall 30 elastically contacts the inner liner 18 to prevent damage, and since the first elastic pad 16 is not exposed to water, durability can be increased.

Then, as shown in FIG. 3D, the PC steel bar 22 is inserted through the steel bar insertion hole 303 for the wall and the steel bar insertion hole 142b for the shear connector, and the lower end of the PC alternating wall 30 and the shear connector 14 are inserted. , The PC steel bar 22 is fixed to the PC alternating wall 30 by screwing the steel bar fastening nuts 24 to both ends of the PC steel bar 22.

Therefore, the PC alternating wall 30 is connected to the foundation 12 via the PC steel bar 22 and the shear connector 14. In this case, when the girder 110 is installed at the top of the PC alternating wall 30 as shown in FIG. is connected to prevent conduction. Therefore, the installation safety of the girder 110 is increased, and the girder 110 can be installed before pouring the concrete 26 to be described later, so that the construction of the ramen bridge 10 can be shortened.

steel composite

Then, as shown in FIG. 1, concrete 26 is poured into the concrete filling groove 301 formed at the lower end of the PC alternating wall 30. The concrete 26 is injected on-site through a cast-in-place injection passage 302 formed in the PC abutment wall 30 and communicating in the vertical direction with the concrete filling groove 301.

Therefore, the shear connector 14, PC steel bar 22, stirrup reinforcing bar 19, and longitudinal reinforcing bar 20 are synthesized with concrete 26.

As a result, the PC alternating wall 30 is separated from the base 12 through the first elastic pad 16 to have a hinge structure, and at the same time, the PC alternating wall 30 connects the PC steel bar 22 and the shear connector 14 It is in a state connected to the base 12 as an intermediary.

In this way, when the PC alternating wall 30 is separated by the first elastic pad 16 but is connected to the foundation 12 through a rigid coupling structure, it is possible to prevent the PC alternating wall 30 from inverting, thereby preventing During the construction of the ramen bridge, the overturning stability of the PC abutment wall 30 is ensured before girder installation.

In addition, when the PC alternating wall 30 is connected and installed to the foundation 12 through this method, and then the slab 100 is constructed as shown in FIG. 7, when the bending moment of the PC alternating wall 30 occurs, the first elastic pad ( 16) is partially absorbed to minimize the bending moment transmitted to the foundation 12, thereby preventing the destruction of the junction between the PC abutment wall 30 and the foundation 12.

Therefore, looking at the connection structure between the PC alternating wall and the foundation made by the method of the first embodiment, as shown in FIG. 12) is installed in the cast concrete 7, one end is embedded and fixed to the concrete layer of the foundation 12, and the other end is raised from the bottom of the pad seating groove 121 at a certain height. The shear connector 14 is installed And, the first elastic pad 16 manufactured in a plate shape made of rubber or EVA is installed on the bottom of the pad seating groove 121, and the both ends of the first elastic pad 16 and the pad seating groove 121 are perpendicular to each other. An outer liner 17 is installed between the inner surfaces, and an inner liner 18 having a waterproof function and a stretch function is installed at the corner where the outer liner 17 and the first elastic pad 16 meet, Stirrup reinforcing bars 19 reinforced at regular intervals by being inserted into the shear connector 14 to the top of the first elastic pad 16 and longitudinal reinforcing bars 20 reinforced along the circumference of the stirrup reinforcing bars 19 ) is installed, the PC alternating wall 30 having a concrete filling groove 301 at the bottom is seated and supported on the upper surface of the first elastic pad 16, and the PC steel bar 22 is the lower end of the PC alternating wall 30 It is inserted into the shear connector 14 and the steel bar fastening nuts 24 are fastened at both ends to be fixed to the PC alternating wall 30, and to the concrete filling groove 301 formed at the lower end of the PC alternating wall 30. Concrete ( 26) is cast to have a structure in which the shear connector 14, PC steel bar 22, stirrup reinforcing bar 19 and longitudinal reinforcing bar 20 are composited with concrete.

<Second Embodiment>

On the other hand, in order to widen the support area of the PC alternating wall 30 in this method, the same method as the first embodiment is performed, but the PC alternating wall 30 is constructed by deforming the lower structure as shown in FIGS. 5a and 5b It can be. That is, at the lower end of the PC alternating wall 30, wall supporting jaws 302 formed by steps S on both sides may be further formed and installed. Of course, a second elastic pad 16a may be additionally installed between the upper surface of the wall support 302 and the base 12, respectively. When the second elastic pads 16a are further installed in this way, the elastic support area increases, so that the bending moment can be further minimized, and thus the span length can be further increased.

Of course, even in the case of the second embodiment, since it has the same connection structure as the first embodiment, the PC alternating wall 30 is connected to the foundation 12 via the PC steel bar 22 and the shear connector 14, so that conduction prevented Therefore, when constructing the ramen bridge 10 in FIG. 7, the installation safety of the girder 110 increases, and the girder 110 can be installed before the concrete 26, which will be described later, can be installed, thereby shortening the construction of the ramen bridge 10. there is.

<Third Embodiment>

In addition, in this method, the pad seating groove 121 is not formed on the foundation 12 as in the first embodiment, but protrudes with a certain height h2 as shown in FIGS. 6A and 6B shown in the third embodiment. It is possible to implement the connection construction of the PC alternating wall 30 and the foundation 12 through the same method as described above by forming the pad seating protrusion 121a.

In this case, the pad seating protrusion 121a is placed into the concrete filling groove 301 formed at the lower end of the PC alternating wall 30, and accordingly, the both sides of the pad seating protrusion 121a and the concrete filling groove 301 Between the inner surfaces, an outer liner 17 and an inner liner 18 having waterproof and elastic functions may be further installed by interviewing each other.

Even in the case of the third embodiment, since it has the same connection structure as the first embodiment, the PC alternating wall 30 is connected to the foundation 12 via the PC steel bar 22 and the shear connector 14 to prevent overturning. . Therefore, as shown in FIG. 7, the installation safety of the girder 110 increases, and the girder 110 can be installed before pouring concrete 26, which will be described later, so that the construction of the ramen bridge 10 can be shortened.

In the present invention, the slab (rigidly coupled girder or composite girder) 100 is installed on the top of the PC alternating walls (30 and 30) facing each other as shown in FIG. It is possible to construct a ramen bridge 10 in which the bending moment is minimized.

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art can make various modifications and variations without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by these variations and modifications, but is limited only by the claims appended below.

12: foundation
14: shear connector
16: first elastic pad
19: stirrup bar
20: longitudinal rebar
22: PC steel bar
30: PC alternating wall

Claims (11)

(a) a pad seating groove 121 recessed with a predetermined depth h1 along the width direction on the upper surface of the base 12 or a pad seating protrusion 121a protruding with a predetermined height h2; and , Foundation 12 having a shear connector 14, one end of which is embedded and fixed to the concrete layer of the foundation 12 and the other end is raised and disposed at a certain height from the pad seating groove 121 or the pad seating protrusion 121a The step of constructing in (5);
(b) installing a plate-shaped first elastic pad 16 made of rubber or EVA on the bottom of the pad seating groove 121 or on the upper surface of the pad seating protrusion 121a;
(c) Stirrup reinforcing bars 19 inserted into the shear connector 14 to the top of the first elastic pad 16 and reinforced at regular intervals by walking, and longitudinal reinforcement along the inner circumference of the stirrup reinforcing bars 19 Installing directional reinforcing bars 20;
(d) The PC alternating wall 30 having the concrete filling groove 301 is lifted up and its lower end is seated on the upper surface of the first elastic pad 16, and the PC steel bar 22 is moved to the PC alternating wall 30 After inserting the lower end and the shear connector 14, screwing the steel bar fastening nuts 24 to both ends of the PC steel bar 22;
(e) Concrete 26 is poured into the concrete filling groove 301 formed at the lower end of the PC alternating wall 30 to shear connector 14, PC steel bar 22, stirrup reinforcing bar 19 and longitudinal reinforcement Including; synthesizing the reinforcing bar 20 into concrete,
In the step (a), the shear connector 14 is vertically installed on the lower support plate 141 and the lower support plate 141 buried at a certain depth on the upper surface of the foundation 12 and penetrated at different positions at regular intervals from each other PC alternating wall and foundation connection construction method, characterized in that it comprises a vertical connecting plate 142 having a reinforcement hole (142a) and a steel bar insertion hole (142b). delete According to claim 1,
In the step (d), an outer liner 17 is installed between both ends of the first elastic pad 16 and the vertical inner surface of the pad seating groove 121, and the outer liner 17 and the first elastic pad 17 are installed. Connection construction method of the PC alternating wall and the foundation, characterized in that the inner liner 18 having a waterproof function and a stretch function is further installed at the corner where the pad 16 meets. According to claim 1,
In the step (d), an outer liner 17 and an inner liner 18 having waterproof and elastic functions are interposed between both sides of the pad seating protrusion 121a and the inner surface of the concrete filling groove 301, respectively. Connection construction method of the PC alternating wall and the foundation, characterized in that further installed. According to claim 1,
In the step (e), the concrete 26 is injected through the cast-in-place injection passage 302 formed in the PC alternating wall 30 and communicating in the vertical direction with the concrete filling groove 301 Characterized in that the on-site injection is performed PC alternating wall and foundation connection construction method. According to claim 1,
In the step (d), the wall supporting jaw 302 formed by the step (S) is further formed on both sides of the lower end of the PC alternating wall 30, and between the wall supporting jaw 302 and the upper surface of the foundation 12 The connection construction method of the PC alternating wall and the foundation, characterized in that the second elastic pad (16a) is additionally installed and constructed. According to claim 4,
Connection construction method of the PC alternating wall and the foundation, characterized in that the second elastic pad (16a) is additionally installed and constructed between the lower end of the PC alternating wall (30) and the upper surface of the foundation (12). A foundation 12 having a pad seating groove 121 recessed with a predetermined depth h1 along the width direction is installed on the upper surface,
A shear connector 14 is installed, one end of which is embedded and fixed to the concrete layer of the foundation 12 and the other end rises from the bottom of the pad seating groove 121 at a certain height and is located,
The first elastic pad 16 manufactured in a plate shape made of rubber or EVA is installed on the bottom of the pad seating groove 121, and the vertical inner surface of both ends of the first elastic pad 16 and the pad seating groove 121 is installed. An outer liner 17 is installed between each of them, and an inner liner 18 having a waterproof function and a stretch function is installed at the corner where the outer liner 17 and the first elastic pad 16 meet,
Stirrup reinforcing bars 19 reinforced at regular intervals by being inserted into the shear connector 14 above the first elastic pad 16 and longitudinal reinforcing bars reinforced along the inner circumference of the stirrup reinforcing bars 19 ( 20) is installed,
The PC alternating wall 30 having a concrete filling groove 301 at the bottom is seated and supported on the upper surface of the first elastic pad 16, and the PC steel bar 22 is connected to the lower end of the PC alternating wall 30 and the shear connector 14 ), and the steel bar fastening nuts 24 are fastened at both ends to be fixed to the PC alternating wall 30,
Concrete (26) is poured into the concrete filling groove (301) formed at the lower end of the PC alternating wall (30), and the shear connector (14), PC steel bar (22), stirrup reinforcing bar (19) and longitudinal reinforcing bar (20) The connection structure of the PC alternating wall and the foundation, characterized in that it is synthesized with this concrete. According to claim 8,
At the lower end of the PC alternating wall 30, wall supporting jaws 302 formed by steps S are further formed on both sides, and between the wall supporting jaw 302 and the upper surface of the foundation 12, second elastic pads ( 16a) is additionally installed, the connection structure of the PC alternating wall and the foundation. A foundation 12 having a pad seating protrusion 121a protruding with a predetermined height h2 along the width direction is installed on the upper surface,
A shear connector 14 is installed, one end of which is embedded and fixed to the concrete layer of the foundation 12 and the other end rises up at a certain height from the upper surface of the pad seating protrusion 121a.
A plate-shaped first elastic pad 16 made of rubber or EVA is installed on the upper surface of the pad seating protrusion 121a, and between both sides of the pad seating protrusion 121a and the vertical inner surface of the pad seating groove 121, respectively. The outer liner 17 and the inner liner 18 having waterproof and elastic functions are interviewed and installed,
Stirrup reinforcing bars 19 and longitudinal reinforcing bars 20 reinforcing along the circumference of the stirrup reinforcing bars 19 inserted into the shear connector 14 to the top of the first elastic pad 16 and reinforcing at regular intervals by walking is installed,
The PC alternating wall 30 having a concrete filling groove 301 at the bottom is seated and supported on the upper surface of the first elastic pad 16, and the PC steel bar 22 is connected to the lower end of the PC alternating wall 30 and the shear connector 14 ) After insertion, the steel bar fastening nuts 24 are fastened at both ends to be fixed to the PC alternating wall 30,
Concrete (26) is poured into the concrete filling groove (301) formed at the lower end of the PC alternating wall (30), and the shear connector (14), PC steel bar (22), stirrup reinforcing bar (19) and longitudinal reinforcing bar (20) The connection structure of the PC alternating wall and the foundation, characterized in that it is synthesized with this concrete. A ramen bridge characterized in that it is constructed by the connection construction method of any one of claims 1 and 3 to 7 and has a structure in which the bottom of the PC alternating wall and the foundation are hingedly connected.

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