KR101457620B1 - Rahmen structure production method using pile - Google Patents

Abstract

The present invention relates to: a method for manufacturing a precast Rahmen structure integrated in a longitudinal direction by using piles, wherein more fast construction can be implemented using precast wall members and segments and the cross sections of a box structure can be optimized; and a Rahmen structure manufactured using the same. If a load is applied to the precast Rahmen structure integrated in a longitudinal direction, a bending moment is intactly transmitted to the wall segment and the transmitted moment is compensated by the resistance of the wall segment and the pile from the ground surface to the lower part ground.

Description

(RAHMEN STRUCTURE PRODUCTION METHOD USING PILE) BACKGROUND OF THE INVENTION 1. Field of the Invention < RTI ID = 0.0 >

The present invention relates to a method of making a longitudinal integral precast ramen structure using a file. More specifically, the present invention relates to a method of manufacturing a longitudinally integral pre-cast ramen structure using a file, which can be constructed more quickly by using a file, a precast wall and a top plate segment, and can be manufactured by optimizing a section of the ramen structure.

Figure 1A shows a perspective view of a conventional raymen structure.

That is, the bottom plate segment 10 is installed on the ground,

Two wall segment segments (20) are provided so as to extend upwardly on the bottom plate segments,

And the step of installing the top plate segments 30 between the tops of the two wall sections is repeated to connect and connect the ramen structures in the longitudinal direction.

The upper plate segment 30 is connected to the precast upper plate 32 in the longitudinal direction and the upper plate concrete 33 is installed on the upper surface of the precast upper plate 32. [ And the prestress is introduced by using the tension member 31 in the transverse direction.

At this time, the bottom plate concrete (11) between the top plate concrete (33) and the bottom plate segment (10) is adopted as a spot installation method so that the workability can be ensured and the integrity of the segments can be ensured.

As a result, pre-cast segments are used, which makes it possible to construct a raymen structure with high quality control.

In this case, since the bottom plate segment 10 is manufactured using the pre-cast method, it is possible to reduce the space used for the installation, but there is also an effective method for solving such a problem, The need for

1B is a perspective view of a conventional alternate integral ramen bridge.

That is, the continuous slab 40 including the bottom slab 41 extending in the throttle direction to be disposed between the alternate upper surfaces and the connecting slab 42 extending in the throttle direction by the concrete pushed integrally with the bottom slab, ; And

(50) hingedly connected to the ground while supporting the continuous slab (40) and constructed in the ground by a pile (60)

Such that the integrated bottom plate slab 41 and the connecting slab 42 behave as a single continuous structure with a connecting slab 42 on the alternating (50) 50) is formed on the basis of the cantilever structure.

It can be seen that the size of the cross section of the alternation 50 can be reduced by constructing the alternation 50 by using the pile 60, which is advantageous for the related construction and alternate construction.

However, in order to connect the shift 50 to the file 60, there is a problem in that it is necessary to construct the shift in a field installation manner. Since the shift 50 is hinged to the continuous slab 40, The load acting on the continuous slab 40 is not transferred to the alternation 50, so that it is difficult to optimize the cross section of the continuous slab 40. Therefore, there is a limitation in that the slab 40 is manufactured in a synthetic bottom plate method.

Therefore, there are many limitations in applying the alternate integral ramen bridge construction method to the ramen structure like the present invention.

Accordingly, in the production of a ramen structure for strengthening both wall segments and top plate segments, the bending moment of the right corner portion is more effectively transmitted to the two wall segments and the files of the ground in order to minimize the tidal space, It is a technical object to solve the problem of providing a method of manufacturing a longitudinally integral precast rheme structure using a file that is structurally simple and can quickly produce a rheme structure.

According to an aspect of the present invention,

First, both wall segments are made of precast, and both wall segments are inserted into the first installed files in the ground, so that they are stronger so that the bending moment is transferred directly to the file from both wall segments.

Furthermore, both wall segments can be structurally integrated with each other in the longitudinal direction so that they can act integrally with the pile together with the surrounding earth pressure, so that the pile can more effectively resist the bending moment transmitted from the two wall segments, . ≪ / RTI >

Thus, the present invention makes it possible to construct the rheme structure more quickly by using the pre-cast method even in a site where it is difficult to secure a ground turf space for the construction of both wall segments.

Second, the upper wall segment and the upper wall segment are connected to each other, and the upper wall segment and the upper wall concrete are integrally formed with the upper wall segment and the upper wall concrete, Connecting reinforcing bars are connected to each other to effectively resist the bending moment generated in the right corner.

Third, the top plate segment allows the prestress to be introduced by the first torsion arranged in the transverse direction, and the additional prestress can be introduced in the lateral direction by the second torsion material after the right corner concrete and the top plate concrete are poured and cured. Composite beam shapes using steel were also made available.

Since the raymen structure using the file according to the present invention can minimize the space for the construction of the two wall segments and optimize the cross section, it is possible to construct, transport and construct both walls segments quickly and quickly .

In addition, since it is advantageous to distribute the bending moment by using the pile for the construction of the ramen structure, it is possible to construct the ramen structure by maximizing the width in the transverse direction, thereby enabling more economical construction. In addition, since the rudder structure can be effectively reinforced with the rudder, it is possible to construct the structure more efficiently.

Thus, in the raymen structure according to the present invention, the top plate segment and the two-wall segment are manufactured by the pre-cast method, and combined with the in-situ concrete method such as the top plate concrete, the right column concrete and the filling material, So that it is possible to construct a more economical and efficient raymen structure.

1A is a perspective view of a conventional raymen structure,
1B is a construction cross-sectional view of a conventional alternate integral ramen bridge,
FIGS. 2A, 2B, 2C, and 2D are flowcharts of a method for producing a raymen structure using a file according to the present invention,
Fig. 3 is a diagram showing the bending moments of a ramen structure using a file of the present invention,
4 is a perspective view of a ramen structure using a file 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 order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

[Method of Manufacturing Longitudinal Integrated Precast Raman Structure 100 Using File 110]

FIGS. 2A to 2D are flowcharts showing a method of manufacturing a longitudinally-combined precast ramen structure using a file according to the present invention.

First, the longitudinal integral precast ramen structure 100 of the present invention includes a file 110, a wall segment 120, and a top plate segment 130.

2A, after securing a minimum space T for the construction of the longitudinally integral pre-cast ramen structure 100, the file 110 is moved in the longitudinal direction of the longitudinally-combined precast ramen structure Direction). That is, they are installed in such a manner that they are spaced apart from each other in the longitudinal direction but facing each other in the lateral direction.

That is, in the construction of a longitudinally integral pre-cast ramen structure to be installed, for example, across a river, it is practically very difficult to secure a terewater space for construction of both wall segments by disturbance

In this case, the file 110 can be a steel pipe file, a PHC file, an H-shaped steel material, or the like. After forming a perforation hole in the ground with a perforator, the pile 110 is inserted so that the tofu protrudes from the surface of the ground It will be constructed.

The head of the file 110 is kept at a constant height by cutting the head so as to have the same protruding height.

Next, the pre-casting method is used to install the wall segments 120 in a manner such that the wall segments 120 are inserted into the head of the pile 110, and the wall segments 120 are connected to each other in the longitudinal direction.

As shown in FIG. 2B, the wall segment 120 is formed in a T-shaped cross section and the lower portion 122 is integrally formed with the upper portion of the wall segment 120 to reduce weight. A hollow block S1 having an internal partition wall 123 formed therein is formed in the form of a hollow block body so that a file insertion hole 124 can be inserted.

That is, the upper portion 121 of the wall segment 120 has a vertical wall portion 121b formed to have a constant width w1 on the upper backside so that the top plate segment 121 can be supported and supported by the top plate segment 130 And a vertical column portion 121c extending integrally downward from the central bottom portion of the horizontal top plate portion 121a at the central portion of the vertical wall portion 121b to form the horizontal upper plate portion 121a, the vertical wall portion 121b, 121c so that the longitudinal horizontal section aa is formed as a T-shaped section.

Further, the lower portion 122 of the wall segment 120 is formed integrally with the upper portion 121 of the wall segment 120,

The width w2 of the vertical wall portion 121b and the vertical column portion 121c is maintained,

The longitudinal hollows S1 are formed separately by the inner partition wall 123,

It can be seen that a hollow block body is formed between the inner barrier ribs 123 to form a file insertion hole 124 therebetween.

The upper side of the file insertion hole 124 is closed so that the top of the file 110 is inserted to support the upper surface of the file 110. The lower side of the file insertion hole 124 is in the form of an opened hole and is positioned directly under the vertical column 121c, (123) is positioned.

The file insertion hole 124 is set to be positioned at the center of the lower portion 122 and the file insertion hole 124 is formed between the two inner partition walls 123 and the vertical column portion 121c ) Is located directly below.

This is because the load transferred from the vertical post 121c is transferred to the pile 110 as it is to improve the bending moment transfer efficiency and the remaining portion is formed to have an optimum cross section for weight reduction.

The longitudinal hollows S1 on both sides of the file insertion groove 124 in the lower portion 122 formed by the inner partition 123 are formed in the longitudinal hollows 121 formed in the lower portion 122 of the adjacent wall segments 120. [ (S1).

The upper side 121 side of the longitudinally adjacent wall segments 120 are connected to each other by shear keys and shear grooves,

The lower side 122 side is completely structurally integrated in the longitudinal direction by the filling material 126 such as mortar injected into the longitudinal hollow S1 communicating with each other.

At this time, it is preferable to arrange the connecting reinforcing bars 125 inside the communicating longitudinal hollows S1 to ensure sufficient structural integrity.

Accordingly, the wall segments 120 connected to each other in the longitudinal direction can be integrated with each other so that problems such as uneven settlement do not occur.

Furthermore, this structural integration behavior plays a very important role in allowing the wall segment 120 to integrally resist the bending moment due to the load together with the pile 110.

The head of the file 110 inserted into the file insertion hole 124 is set to contact the upper bottom surface of the file insertion hole 124 and is also integrated with the wall segment 120 by the filler 126.

The filling material 126 may be injected through the injection hole 127 formed in the lower part.

This makes it possible to fully utilize the resistive performance against the earth pressure acting on the periphery by the file 110 and the two wall segments 120 acting as a longitudinally integrated structure, thereby optimizing the cross section of the two wall segments 120, It is possible to minimize the ter- mination space for the segment.

Next, as shown in FIG. 2C, the top plate segments 130 are manufactured in a pre-casting manner so that both ends are mounted on the inner upper surface A of the two wall segments 120 that are constructed to be laterally spaced from each other.

More specifically a lateral extension length L between the two wall segments 120. A prestressed beam structure with a cross section that is sufficiently resistant to bending moment action by such transverse extension length .

An upper slab plate 131 having an extended length to be installed between the inner upper surface of the wall segment 120; (Or I-shaped) I-shaped cross-section member composed of a rectangular parallelepiped concave portion 132 formed to extend downward at the bottom surface of the upper slab plate 131 and having an extended length of the upper slab plate 131 Beam type is used.

At this time, both end portions are formed so as to form the longitudinal reinforcing spheres 133 formed by the extended cross-sectional portions so as to serve as the hook portions.

This is to ensure a sufficient rigidity while minimizing the weight, and thus, in the construction of a longitudinally integral pre-cast rail structure with a long transverse length, the top plate segments sharing the largest load as the flexural members are optimized sections So that it is possible to improve the workability and economical efficiency in the transportation and construction of the top plate segment 130.

2d, the primary tension member 134 may be disposed in the upper portion of the upper segment 130, preferably in the form of a rectangular parallelepiped concave portion 132, by the sheath for the primary tension member, So that it is fixed after the tension on the side surface.

In addition, the sheath 135 for the secondary tension member is formed in the upper plate segment 130 in addition to the sheath for the primary tension member so that the secondary tension member 136 can be inserted into the sheath 315 for the secondary tension member later do.

The sheath 135 for secondary tension material is connected to the right corner sheath 137 disposed in the right corner forming space S2 to be described later so that the secondary tension member 136 is moved from the right corner forming space S2 to the secondary So that it can be inserted into the sheath 135 for tensioning.

This top plate segment 130 is mounted (mounted) on the inner upper surface A of the two wall segments 120 such that both end bottoms are simply supported.

This is to make it possible to secure the right corner forming space S2 while minimizing the lateral extension length of the top plate segment 130. [

That is, the right angled portion B is secured not by the top plate segment 130 but through the separate right angled concrete 140. In order to prevent the formation space of the right angled concrete 140 from being interrupted So that the top plate segments 130 are simply supported on the inner upper surface A of the two wall segments 120.

In the right corner forming space S2, the two wall segments 120, the top plate segments 130, and the top plate concrete 150 to be described later are connected and synthesized so that they are strong at the right corner B together.

In this right corner forming space S2, the upper plate connecting bar 138 of the upper plate segment 130 is extended.

At least one of the upper plate connection reinforcing bars 138 protrudes from the inside of the upper plate segment 130 to the end face to extend into the right corner forming space S2.

The upper plate connection reinforcing bars 138 are connected to the lower reinforcing bars 128 so that both the wall segments 120 and the upper plate segments 130 are structurally integrated with each other.

The right-angled reinforcing bar 128 protrudes from the top surface of the two wall segments 120 to the right corner forming space S2 and is bent and extended to the top of the top plate segment 130.

At this time, the upper plate connection reinforcing bars 138 and the right reinforcing bars 128 are connected to each other in the right corner forming space S2.

The right-angled reinforcing bars 128 are bent upward at the upper portion of the upper plate segment 130 and then embedded in the upper-plate concrete 150 to be inserted later. Finally, the upper plate concrete 150 is inserted into the right- So that the upper plate segment 120 and the upper plate segment 130 can be coupled to each other.

The upper plate segment 130 and the upper plate segment 130 are fixed to each other by a predetermined thickness so that the upper plate segment 130 and the two wall segments 120 are tightened by the left and right concrete 140, .

At this time, on the upper surface of the upper plate segment 130, it is preferable to form a shear reinforcement in the form of an inverted C shape in order to secure the adhesion performance of the upper plate concrete 130.

At this time, the right corner portion sheath 137 is installed before the right corner concrete 140 is formed. The right corner portion sheath 137 is connected to the sheath 135 for the secondary tension material so as to be embedded in the right corner concrete .

The second tension member 136 is inserted into the sheath 137 for the right corner portion and the sheath 135 for the second tension member to tighten the second tension member 136, The second prestress can be introduced into the top plate segment 130 by fixing at both ends of the concrete 140 or the top plate concrete 150 to effectively cope with a live load acting on the rear framing structure.

Although not shown in this figure, the top plate segment 130 may be formed in the form of a pre-cast beam so that both end portions of the steel beam are mounted on the inner upper surface A of the two-wall segments 120. This may be employed for construction of longitudinal integral precast ramen structures with longer transverse widths.

As shown in FIG. 3, when the final top plate segment 130 is completed, the ground around the wall segment 120 of the present invention is closed through a back-up. When a load is applied to the longitudinal integral pre-cast longitudinal integral pre-cast ramen structure 100 of the present invention, the bending moment is transmitted to the wall segment 120 as it is, and the moment transmitted from the ground surface to the lower ground, (120) and the file (110).

[Longitudinal directional integral pre-cast longitudinal direction integral precast rastructure structure (100) using a file)

4 shows a front view of a longitudinal integral precast longitudinal longitudinal integral precast ramen structure 100 using the final finished file 110. [

For the sake of safety, depending on the lateral length of the top plate segment 130, the middle column segment 200 is further provided between the wall segments 120 for the purpose of separating the vehicle, and the upper end is connected to the bottom of the top plate segment 130 And the lower end is supported on the ground.

It is preferable that the intermediate column segment 200 is manufactured by a precast method. However, the present invention is not limited thereto. It is also possible to manufacture the intermediate column segment 200 directly on site by using formwork and concrete. In the case of FIG. 3, It can be seen that the intermediate column segment 200 is installed.

It will be understood by those skilled in the art that the foregoing description of the present invention is for illustrative purposes only and that those of ordinary skill in the art can readily understand that various changes and modifications may be made without departing from the spirit or essential characteristics 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 defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: Longitudinally integrated precast raymene structure
110: File
120: Wall segment
121: upper part of the wall segment
121a, 121b, and 121c: a horizontal upper plate portion, a vertical wall portion,
122: bottom of wall segment 123: internal partition
124: File insertion hole 125: Reinforcing bar
126: filling material 127: injection hole
128: Reinforcing bars
130: Top segment
131: upper slab plate 132: abdomen
133: longitudinal reinforcing member 134: primary tension member
135: Sheath for secondary tension material 136: Secondary tension material
137: Right Angle Sheath 138: Reinforced Steel Connection
140: Right Angle Concrete 150: Top Plate Concrete
200: intermediate column segment S1: longitudinal hollow
S2: right corner forming space A: inner upper surface

Claims (5)

The piles 110 are spaced apart from each other in the longitudinal direction so as to be opposed to each other in the lateral direction,
The upper portion 121 is formed in a T-shaped section and the lower portion 122 is formed integrally with the upper portion. The lower portion 122 is integrally formed with the upper portion 121 in the longitudinal direction The piles 110 are inserted into the file insertion holes 124 in the form of a hollow block body having the hollow S1 formed therein so that the wall segments 120 constructed to face each other in the lateral direction are constructed to be adjacent to each other in the longitudinal direction ,
The longitudinal hollow S1 provided with the connecting reinforcing bar 125 and the file insertion hole 124 in which the pile 110 is inserted are formed in the lower portion 122 of the wall segment 120 adjacent to each other in the longitudinal direction, (116) are injected and integrated with each other in the longitudinal direction,
The upper wall segment (130) is mounted on the inner upper surface (A) of the two wall segments (120) installed to face each other in the lateral direction so as to support both ends of the upper wall segment (130) 120 is extended from the top surface of the top plate segment 130 to the top plate connecting reinforcing bar 138 extending from the end surface of the top plate segment 130, S2) and a top plate concrete (150) placed on top of the top plate segment (130) to cure both the top and bottom segments and the top plate segment (130)
So that the bending moments transmitted to the two wall segments integrated in the longitudinal direction are transmitted to the ground via the pile,
The upper portion 121 of the wall segment 120 includes a vertical wall portion 121b formed on an upper back surface of the horizontal upper plate portion 121a and a horizontal upper plate portion 121b formed on a central portion of the rear wall of the vertical wall portion, 121a by a vertical pillar 121c integrally extending downward from a central bottom portion of the vertical wall 121a and a vertical horizontal portion aa by the vertical wall portion 121b, Shaped cross-section,
The file insertion hole 124 is formed such that the top of the file 110 is inserted so that the top of the file 110 is inserted and the upper surface thereof is closed and the bottom of the file insertion hole 124 is in the form of an opened hole and positioned directly under the vertical post 121c, So that the barrier ribs (123) are positioned in the longitudinal direction. The method according to claim 1,
The lower portion 122 of the wall segment 120 is integrally formed with the upper portion 121 of the wall segment 120 and maintains the width by the vertical wall portion 121b and the vertical column portion 121c, And a hollow hole S1 is formed by the inner partition wall 123. The inner partition wall 123 is formed in a hollow block shape in which a file insertion hole 124 is formed. A method for manufacturing a longitudinally integrated precast raymen structure using a file. The method according to claim 1,
The top plate segments (130)
A longitudinal reinforcing ball 133 formed of an enlarged cross-section is formed at both ends so as to serve as a spiral portion. The longitudinal reinforcing ball 133 is formed in the shape of a beam having an extension length so as to be installed between the inner upper surfaces of both wall segments 120 Wherein the prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated prefabricated The method of claim 3,
The first tension member 134 is disposed in the abdomen portion 132 of the top plate segment 130 by sheath for the first tension member so that the first tension member 134 is fixed after being tensed at both end surfaces of the top plate segment 130,
The sheath 135 for the secondary tension member may be formed in the upper plate segment 130 in addition to the sheath for the primary tension member so that the secondary tension member 136 can be inserted into the sheath 315 for the secondary tension member,
The sheath 135 for the secondary tension member is connected to the right corner sheath 137 disposed in the right corner forming space S2 to be described later so that the secondary tension member 136 is moved from the right corner forming space S2 to a secondary tension So that it can be inserted into the refilling sheath 135,
The secondary tension member 136 is inserted into the right corner sheath 137 and the sheath 135 for the secondary tension member to tighten the secondary tension member 136 and the both ends of the right corner concrete 140 or the top plate concrete 150 And the second prestress is introduced into the top plate segment (130), so that the secondary prestress is introduced into the top plate segment (130). delete

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