KR101319517B1 - Rahmen structure with concrete hinge and the construction method therefor - Google Patents

Abstract

PURPOSE: A concrete hinge type rahmen structure and a construction method thereof are provided to minimize the size of a foundation part and not to separately use a subsidiary material for the hinge structure, thereby being advantageous to quality control and maintenance and ensuring economical efficiency. CONSTITUTION: A concrete hinge type rahmen structure includes a foundation part, a wall part, and a top plate. The foundation part is arranged so that a spherical surface concave groove (111) and a horizontal upper surface portion (112) of a concrete spherical surface concave portion (110) are exposed to the upper surface. The wall part is formed by the bottom end of the upper wall integrally formed with a concrete spherical surface convex portion (120) in which a spherical surface convex portion and a horizontal lower surface portion are formed. The spherical surface convex portion is inserted into the spherical surface concave groove and is connected by a hinge so as to be rotatable. [Reference numerals] (AA) Form oil

Description

RAHMEN STRUCTURE WITH CONCRETE HINGE AND THE CONSTRUCTION METHOD THEREFOR}

The present invention relates to a concrete hinge type ramen structure and a construction method thereof. More specifically, the present invention relates to a ramen structure hinged to each other and a construction method thereof.

Figure 1a shows a comparison of the matters of bending moment and conduction according to the connection conditions between the base portion and the wall portion in the conventional ramen bridge (ramen structure).

First, when the foundation part and the wall part of the ramen bridge are rigid together, the wall part is integrated with the foundation part, so the wall part is not inverted against the horizontal load during the construction process.

Since the bending moment transmitted from the wall portion is transmitted to the foundation as it is, the size of the foundation is inevitably increased. Thus, when the foundation becomes large, the excavation space for the foundation construction must be sufficiently secured. However, due to site conditions, it is often difficult to secure enough excavation space, causing construction cost increase factors such as the need to construct a pile on the foundation.

Accordingly, when the foundation part and the wall part of the ramen bridge are hinged to each other, the bending moment is not transmitted to the foundation part, thereby minimizing the size of the foundation part.

However, when using the hinge there is a disadvantage that there is a risk that the horizontal force is applied when the wall portion is installed on the foundation.

In order to prevent such a fall, a case where the foundation part and the wall part of the ramen bridge are connected to each other in a semi-hinge manner is also introduced. This semi-hinge method is a hinged connection, but the bending moment is limited to the base portion to optimize the size of the base portion.

The configuration of this semi-hinge can be seen in Figure 1b.

That is, the upper surface is formed of a steel sheet curved downward and the upper surface of the base formwork not shown using a pedestal 50 to the separator plate 40 formed with the joint steel bar hole 41 so that the joint steel bar 30 can penetrate. To set the foundation concrete and to expose the upper surface of the separator plate, to set the joint steel bar 30, to set the wall formwork and then to the wall concrete,

It can be seen that the foundation part and the wall part are constructed with site-cast concrete at the site, but the base part and the wall part are hinged to each other by a semi-hinge method using a separating plate and a joint steel bar.

Although the semi-hinge method has the advantage that there is no fear of conduction, but the hinge method, but the separation plate 40 and the joint steel bar 30 is made of steel, so the durability is degraded over time, easy quality and maintenance There is a problem that the economy may be somewhat reduced because it may not be, and additional materials for the semi-hinge is required.

Therefore, the present invention is to connect the base and the wall portion of the ramen structure to the hinge structure to each other, but it is possible to prevent the fall, but do not need to use additional materials for connecting a separate hinge, it is possible to secure enough economic feasibility but also easy to work To solve the problem of providing a concrete hinge-type ramen structure and its construction method can be reduced.

To achieve the above object,

First, the foundation of the ramen structure, for example, should be constructed with site-casting concrete, so that the concrete spherical concave part is buried in advance in the foundation when the foundation is constructed so that the concrete spherical concave part can be installed together.

Second, the spherical concave convex part is made of a concrete block shape formed on the spherical concave groove, but the spherical concave concave part is to be used as a match-casting formwork before being installed in the foundation.

That is, the concrete spherical concave portion as a bottom formwork (match-casting) to be used to produce a concrete spherical convex portion.

In this case, the concrete spherical convex part is used to replace the lower end of the wall part when constructing the wall part, so that the wall part of the present invention has a concrete spherical convex part formed at the bottom part, and the concrete spherical convex part is manufactured from the concrete spherical concave part in a match-casting method. Therefore, the concrete spherical concave part can be hinged correctly.

At this time, the concrete spherical convex part is rotated (hinge connection) in the concrete spherical concave part, and the spherical concave part and the concave part may be damaged by the rotation of the concrete spherical concave part and the convex part. The unit is to use the ultra-high performance concrete (UHPC) to prevent the breakage caused by the rotation, etc., while enabling the role of the hinge by the rotation function.

Third, the concrete spherical concave portion and the spherical convex portion should prevent the conduction occurs when the hinge is connected. Accordingly, the concrete spherical convex part is sufficiently inserted into the spherical concave groove of the concrete spherical concave part, and the horizontal bottom part is formed together with the concrete spherical convex part to secure the construction safety.

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In accordance with the present invention, the foundation part and the wall part are connected to the concrete hinge structure, so that the size of the foundation part can be minimized, but the subsidiary materials using steel materials are not used to connect to the hinge structure. You can do it.

In addition, the concrete spherical convex part is made of the concrete spherical concave part as a match-casting formwork, so the precision of the hinge connection is very high, so it is very advantageous to prevent the fall when constructing the wall part. Breakage can be prevented, and made of ultra high performance concrete (UHPC), the friction coefficient is small enough to secure the hinge performance when rotating the wall.

Figure 1a is a comparison table for the bending moment degree, conduction in the ramen bridge constructed in the rigidity, hinge, semi-hinge method in the conventional ramen bridge,
Figure 1b is a perspective view of the configuration of the semi-hinge used in the semi-hinge ramen bridge,
2 is a perspective view of the operation of the hinge structure of the present invention,
3a and 3b is a perspective view of the production of the concrete spherical concave portion and the concrete spherical convex portion of the present invention,
Figures 4a, 4b and 4c is a construction sequence diagram of the concrete hinge type ramen structure of the present invention (Example 1),
5a, 5b and 5c is a construction sequence diagram of the concrete hinge type ramen structure of the present invention (Example 2),
6 is another perspective view (Example 3) of the concrete hinge type ramen structure of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

Concrete hinge of the present invention (100)

2 is a perspective view of the action of the concrete hinge 100 of the present invention.

The concrete hinge 100 is a hinge (Hinge) made of concrete installed in the connection portion between the base portion 210 and the wall portion 220 in the ramen structure 200.

First, the base portion 210 is constructed by, for example, a site pouring concrete method. In other words, using the foundation formwork (not shown) to construct the base portion 210 of the bottom plate shape having a predetermined thickness, but not shown after breaking the ground on which the ramen structure should be installed, but the foundation formwork is installed in advance The internal reinforcing bar is placed inside the formwork of the foundation, but the upper surface of the concrete spherical recess 110 of the present invention is set to be exposed.

The concrete spherical concave portion 110 is made of a concrete block body, the spherical concave groove 111 is formed in the center of the upper surface, the spherical concave groove 111 can be seen that the horizontal upper surface portion 112 is formed. have.

The concrete spherical concave portion 110 is to be set on the base formwork upper surface by using a pedestal 113 that is manufactured in advance.

Accordingly, it can be seen that the foundation 210 of the present invention can be formed so that the upper surface thereof is exposed while the concrete spherical recess 110 is embedded by placing the foundation concrete C1 in the foundation formwork.

Hence, the wall portion 220 is hinged to the concrete spherical recess 110.

It can be seen that the concrete spherical convex portion 120 is formed at the lower end of the wall portion 220 so as to be hinged to the concrete spherical concave portion 110.

In this case, the concrete spherical convex part 120 is also made of a concrete block body, and the spherical convex part 121 is formed on the bottom surface, and the spherical convex part 121 is found to be formed of the horizontal bottom part 122. have.

Thus, the spherical convex portion 121 is inserted into the spherical concave groove 111, so that it can be seen that the wall portion 220 is hinged to each other to the base portion 210.

In this case, the horizontal bottom portion 122 is inserted into the spherical concave groove 111 so that the spherical convex portion 121 does not come into contact with the horizontal upper surface portion 112 and rotates, thereby preventing excessive rotation of the base portion 210. In the construction of the wall portion 220, it is possible to prevent the phenomenon that is conducted.

Furthermore, when the concrete spherical convex part 120 is inserted into the concrete spherical concave part 110 and rotated, the concrete spherical concave part 110 may be damaged. Hence, the hinge 40 made of the steel material as shown in FIG. 1B may be used as the contact surface, but the steel material is expensive and vulnerable to corrosion.

Accordingly, the present invention is to produce the concrete spherical convex portion 120 to the concrete spherical concave portion 110 using ultra high performance concrete (hereinafter, abbreviated as "UHPC").

The ultra-high-performance concrete has the advantage that the surface can be formed very smooth because the compressive strength is very high and workability is very high, it is very useful in the hinge portion of the heavy wall portion as in the present invention. Such a concrete having a compressive strength of at least 100 MPa is referred to as an ultrahigh performance concrete, and the fabrication of a UHSC structure (Ultra High Strength Concrete, Ultra High Strength Concrete Structure) using the UHPC has already been disclosed in a patent (10-2011-67761) Lt; / RTI >

Furthermore, since the concrete spherical convex portion 120 on the concrete spherical concave portion 110 is all molded from concrete, the spherical convex portion 121 is spherical concave groove 111 rotates with each other unless the shapes are precisely manufactured to be connected to each other. The problem may occur such that the contact surface is broken.

Therefore, the present invention uses the concrete spherical concave portion 110 as a match-casting form to produce a concrete spherical convex portion 120 so that the concrete spherical convex portion 120 is accurately connected to the concrete spherical concave portion 110. do.

[Manufacture of Concrete Spherical Concave Part (110) and Concrete Spherical Convex Part (120)]

3A and 3B illustrate a manufacturing flow chart of the concrete spherical concave portion 110 and the concrete spherical convex portion 120 of the present invention, which eventually uses the concrete spherical concave portion 110 as a match-casting formwork. By making the convex portion 120 is to ensure that the male and female accurately connected for the hinge connection without breaking each other.

As will be described later, the concrete spherical concave portion and the concrete spherical convex portion of the present invention are prepared in advance and prepared in the state of construction of the concrete spherical concave portion at the time of construction of the foundation, the concrete wall convex portion integrally formed at the bottom of the wall and the wall on the foundation We will build wealth.

First, the concrete spherical concave portion 110 is factory fabricated using steel formwork in advance because it serves as a match-casting formwork as described above. It may be formed so as to connect the hinge while supporting the wall portion in the shape, but in consideration of the size of the wall portion and the like to produce a concrete block.

In the present invention, it is made of a concrete block body, but the spherical concave groove 111 is formed in the center of the upper surface, the spherical concave groove 111 is to be formed as a horizontal upper surface portion 112.

Thus, as shown in Figure 3a, the steel formwork for concrete spherical concave part (A) is produced by pouring UHPC to the steel spherical formwork for concrete spherical concave part (A) and cured when the steel formwork for concrete spherical concave part (A) demolded spherical concave groove ( 111, the spherical concave convex portion 110 is formed around the horizontal upper surface portion 112.

Next, the concrete spherical concave portion 110 in order to produce the concrete spherical convex portion 120 in the state set upside down to use the concrete spherical concave portion 110 prepared as shown in Figure 3b as a match-casting formwork. ) Set the steel formwork (B) for the concrete spherical convex part on the upper surface.

That is, a release agent is applied to the surface of the spherical concave groove 111 and the horizontal upper surface 112 of the concrete spherical concave portion 110 that is upside down, and the steel formwork for the concrete spherical convex portion 110 outside the spherical concave convex portion 110 (B). ) Is installed vertically, and after curing UHPC and cured again, the concrete spherical convex part 120 formed by demolding the steel formwork for concrete spherical convex part B is separated from the concrete spherical concave part 110.

Therefore, the concrete spherical concave portion and the concrete spherical convex portion of the present invention are prepared in advance and used when the foundation portion 210 and the wall portion 220 are constructed.

Therefore, it can be seen that the concrete spherical convex part 120 is manufactured using the concrete spherical concave part 110 to enable precise male and female connection.

At this time, if the wall portion 220 is constructed in a precast concrete method, the concrete spherical convex portion 120 may be manufactured to be integrated at the lower end of the upper wall portion 221 in advance, and then the wall portion may be installed at the base portion.

If the wall portion 220 is constructed in the form of cast-in-place concrete, after placing the concrete spherical convex portion 120 in the longitudinal direction in the foundation part in advance, setting the wall formwork and pouring the wall portion concrete, the final wall portion Concrete spherical convex portion 120 is to be formed integrally at the lower end.

[Construction method of ramen structure using concrete hinge method]

Example 1

Example 1 is a method using the wall portion produced by the precast concrete method in the concrete hinge method of the ramen structure construction method of the present invention.

Figures 4a to 4c is a flow chart of the construction method of the ramen structure of the concrete hinge method according to the first embodiment of the present invention.

First, the ramen structure 200 of the present invention may be constructed as a ramen bridge, an underground driveway, a box structure. The present invention will be described based on the box structure, but the box structure is installed in a longitudinal direction in a continuous direction.

The box structure ramen structure 200 is composed of a base portion 210, the wall portion 220 and the top plate 230, the base portion 210 is cast-in-place concrete, the wall portion 220 is precast, The upper plate 230 is constructed by mixing precast and on-site concrete.

In this case, the foundation 210 is first constructed, the wall 220 is installed, and the upper plate 230 is constructed.

That is, after installing the foundation formwork (not shown) in order to construct the foundation portion 210 by breaking the ground for the construction of the ramen structure 200 as shown in Figure 4a and the foundation internal reinforcement inside the foundation formwork I'm going to go to work.

At this time, the concrete form spherical concave portion 110 is installed on the upper surface of the base formwork so that the spherical concave groove 111 and the horizontal upper surface portion 112 of the concrete spherical concave portion 110 are exposed.

To this end, it is preferable that the bottom of the concrete spherical recess 110 is first installed with a pedestal 113 so as to be positioned at a predetermined height from the upper surface of the base formwork, and the concrete spherical recess 110 is fixed to the pedestal 113. .

The pedestal 113 may be made of reinforcing bars or the like of a truss structure, and may be integrally manufactured when the concrete spherical recess 110 is manufactured.

Next, the foundation portion 210 is poured by laying the foundation concrete C1. Therefore, when the foundation 210 is completed as a constant plate structure, it can be seen that the concrete spherical recess 110 of the present invention is exposed to the site only when the wall part is installed.

Next, as shown in FIG. 4B, the wall part 220 manufactured by the precast concrete method is installed on the base part 210.

It can be seen that the concrete spherical convex portion 120 described above is formed at the lower end of the wall portion 220, and the concrete spherical convex portion 120 is integrally formed at the lower end of the wall upper portion 221.

That is, when manufacturing the wall upper part 221 in advance in the factory, the concrete spherical convex part 120 is set on the wall formwork at the lower end and the concrete is poured to form the concrete spherical convex part 120 and the wall upper part 221 integrally. It is carried in the field as it is to be installed in the base portion 210.

The spherical convex part 121 of the concrete spherical convex part 120 located at the lower end of the wall part 220 is inserted into the spherical concave groove 111 of the concrete spherical concave part 110 so that the hinge part is connected to the wall part 220. Will be constructed.

Next, a precast top plate 231 is installed between the wall parts as shown in FIG. 4C, and the top plate concrete C2 is poured on the precast top plate 231 to construct the final top plate 230.

[Example 2]

Example 2 is a method of using the wall portion in the concrete casting method construction method of the concrete hinge method of the present invention produced in the field cast concrete method.

5a to 5c is a flow chart of the construction method of the ramen structure of the concrete hinge method according to the second embodiment of the present invention.

First, the ramen structure 200 of the present invention according to the second embodiment can also be constructed as a ramen bridge, an underground roadway, a box structure. The same is true.

The ramen structure 200, which is also the box structure, is composed of a foundation portion 210, a wall portion 220, and a top plate 230, so that the foundation portion 210 is cast-in-place concrete, a wall portion 220, and a top plate 230. ) Will be mixed with precast or cast-in-place concrete.

At this time, the foundation 210 is installed first, and the wall 220 is installed, and the upper plate 230 is constructed.

First, as shown in FIG. 5a, a foundation formwork (not shown) is installed in order to construct the foundation portion 210 by breaking the ground for constructing the ramen structure 200, and then the foundation internal reinforcement is formed inside the foundation formwork. You will also be coughed.

At this time, as shown in Example 1, the spherical concave groove 111 and the horizontal upper surface 112 of the concrete spherical concave portion 110 is installed on the upper surface of the base formwork concave portion 110. Is placed to expose.

To this end, it is preferable that the bottom of the concrete spherical recess 110 is first installed with a pedestal 113 so as to be positioned at a predetermined height from the upper surface of the base formwork, and the concrete spherical recess 110 is fixed to the pedestal 113. .

The pedestal 113 may be made of reinforcing bars or the like of a truss structure, and may be integrally manufactured when the concrete spherical recess 110 is manufactured.

In the second embodiment, since the wall portion 220 is constructed in a cast-in-place method, the concrete spherical concave portion 110 is also continuously installed in the longitudinal direction. Of course, the concrete spherical concave portion 110 is manufactured in a limited size so that a plurality of continuous in the longitudinal direction.

Next, the foundation portion 210 is poured by laying the foundation concrete C1. When the base portion 210 is completed as a constant plate structure, it can be seen that the concrete spherical concave portion 110 of the present invention is continuously exposed in the longitudinal direction when the wall portion is installed.

Next, as shown in FIG. 5b, the wall portion 220 manufactured by the in-situ concrete method is constructed on the foundation 210.

At this time, while installing the wall formwork, the pre-fabricated concrete spherical convex part 120 is set in the lower part of the wall formwork, and the reinforcement is placed and the concrete part C2 is poured into the wall part 220 in the longitudinal direction. It can be constructed in succession.

Of course, both the base portion and the wall portion will have a longitudinal extension length that is constructed once in a possible range, whereby construction joints may occur in every longitudinal direction.

Accordingly, it can be seen that the concrete spherical convex portion 120 is formed at the lower end of the final wall portion 220, and the concrete spherical convex portion 120 is integrally formed at the lower end of the wall upper portion 221.

That is, it can be seen that the concrete spherical convex portion 120 is integrally formed at the lower end while constructing the wall portion 221 at the site.

Thus, in Example 2, the spherical convex part 121 of the concrete spherical convex part 120 located at the lower end of the wall part 220 is inserted into the spherical concave groove 111 of the concrete spherical concave part 110 to be connected to the hinge. The wall portion 220 will be constructed.

Next, as shown in FIG. 5C, a precast top plate 231 is installed between the wall parts, and the top plate concrete C2 is poured on the precast top plate 231 to construct the final top plate 230.

[Example 3]

In Embodiment 3, in the construction method of the concrete hinge-type ramen structure of the present invention, the foundation is constructed in a cast-in-place concrete method, but the foundation part hinged to the wall part 220 is installed in a precast concrete method, and between precast foundations. In the following, an example of construction in a cast method is shown.

Thus, as shown in Figure 6 it can be said to be an advantageous construction method for the ramen structure having a large separation distance between the two wall parts.

In addition, according to Figure 6, it can be seen that at least two or more wall parts can be formed, which shows that it can be applied when the transverse extension length of the ramen structure is very large,

Using the concrete spherical concave portion 110 and the concrete spherical convex portion 120 to construct the wall portion and the base portion is the same as in the first or second embodiment.

The foregoing description of the present invention is intended for illustration, and it will be understood by those skilled in the art that the present invention may be easily modified in other specific forms without changing the technical spirit or essential features of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is shown by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

100: concrete hinge
110: concrete spherical recess
111: spherical recessed groove 112: horizontal top portion
120: concrete spherical convex portion 121: spherical convex portion
200: ramen structure 210: foundation
220: wall portion 230: top plate

Claims (6)

The spherical concave groove 111 is formed in the center of the upper surface, and the spherical concave groove and the horizontal upper surface of the concrete spherical concave portion 110 having the horizontal upper surface 112 are formed around the spherical concave groove so as to be exposed to the upper surface. Constructed base portion 210; And a spherical convex portion 121 which is inserted into the spherical concave groove 111 and connected to the hinge so as to be rotatable, and is formed on the bottom thereof, and the spherical convex convex concrete block chain formed with a horizontal bottom portion 122 around the spherical convex portion 121. Includes; the wall portion 220 is formed integrally with the lower end of the wall portion 120,
The concrete spherical concave portion 110, the spherical concave groove 111 in the factory to produce a steel formwork for concrete spherical concave portion (A) to be formed as a horizontal upper surface portion 112 to set the top surface to open, ultra high performance After pouring concrete (UHPC), pre-fabricate by demolding steel formwork (A) for concrete spherical recesses.
The concrete spherical convex part 120, the concrete spherical concave part 110 on the side of the concrete spherical concave part 110 in the state in which the up and down is set in order to use the pre-made concrete spherical concave part 110 as a match-casting formwork. The steel formwork (B) is set, the super-high-performance concrete (UHPC) is poured into the steel formwork (B) for concrete spherical convex parts, and then produced by demolding the steel formwork (B) for concrete spherical convex parts, and the concrete spherical convex part ( 120 is separated from the concrete spherical recess 110, the concrete hinge type ramen structure, characterized in that to be formed integrally on the lower end of the wall. The method of claim 1,
Further comprising a top plate 230 installed on the top of the wall portion,
The concrete spherical recess 110 is a concrete hinge, characterized in that the spherical recess groove and the horizontal upper surface portion is arranged to be exposed to the upper surface of the foundation portion so that the base 113 is further formed in order to set to be embedded in the foundation portion Ramen structure. The method of claim 2,
The upper plate 230 is a concrete hinge method of the ramen structure, characterized in that the construction to be installed in the cast concrete or precast concrete method. The spherical concave groove 111 is formed in the center of the upper surface, and the spherical concave groove and the horizontal upper surface of the concrete spherical concave portion 110 formed with the horizontal upper surface portion 112 are formed around the spherical concave groove. A spherical convex part 121 is installed on the bottom of the spherical convex part 121 and is installed in the spherical concave groove. The spherical convex part 121 is connected to the spherical concave groove. The concrete block chain concrete spherical convex portion 120 is arranged to be inserted into the spherical concave groove 111 of the concrete spherical concave portion 110, the concrete spherical convex portion 120 is located at the lower end of the wall 221 And constructing the wall portion 220 to be integrated,
The concrete spherical concave portion 110, the spherical concave groove 111 in the factory to produce a steel formwork for concrete spherical concave portion (A) to be formed as a horizontal upper surface portion 112 to set the top surface to open, ultra high performance After pouring concrete (UHPC), pre-fabricate by demolding steel formwork (A) for concrete spherical recesses.
The concrete spherical convex part 120, the concrete spherical concave part 110 on the side of the concrete spherical concave part 110 in the state in which the up and down is set in order to use the pre-made concrete spherical concave part 110 as a match-casting formwork. The steel formwork (B) is set, the super-high-performance concrete (UHPC) is poured into the steel formwork (B) for concrete spherical convex parts, and then produced by demolding the steel formwork (B) for concrete spherical convex parts, and the concrete spherical convex part ( 120 is separated from the spherical concave convex part 110 so as to be located at the lower end of the upper wall portion 221 to be integrated, the concrete hinge type ramen structure construction method. delete delete

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