KR101041363B1 - Rahmen structure construction method - Google Patents

Abstract

The present invention relates to a method for constructing a long span ramen structure and to a method for constructing a ramen structure in which a ramen structure can be connected to each other in a prefabricated manner, and the construction of the long span ramen structure is more structurally possible.

To this end, the central portion of the precast slab of the ramen structure is formed such that the central bending moment reducing portion protrudes upwards, and the central bending moment reducing portion is a structural member having a U-shaped cross section as a whole, and upwardly extending upwardly vertically spaced apart from each other. It consists of an upper horizontal portion connecting the upper portion and the upper vertical portion.

Ramen Structure, Long Span

Description

Long-term ramen structure construction method {RAHMEN STRUCTURE CONSTRUCTION METHOD}

The present invention relates to a method for constructing a long-term ramen structure. More specifically, it relates to a method for constructing a ramen structure that can be connected to each other in a prefabricated manner in a prefabricated manner, and in which the construction of a ramen structure can be performed more structurally.

Figure 1a shows an example of a conventional ramen structure 10 in a perspective view.

The ramen structure 10 includes a slab formed integrally with the bottom plate 13 and the bottom plate 12 and the upper surface of both ends of the bottom plate 12, which are installed to extend in a vertical direction to the bottom plate 13 and the center top surface of the bottom plate. 11).

The bottom plate 13 is made of a reinforced concrete structure of a rectangular parallelepiped form using the formwork to dig the ground, and also the bottom plate portion 12 is also made of a reinforced concrete structure having a predetermined height (H) using the formwork. .

Furthermore, the slab 11 is also installed between the bottom plate wall portion 12, the copper bar on the ground and the formwork is installed on the copper bar to be constructed as a reinforced concrete structure.

The slab 11 has a predetermined thickness (t) as shown in the AA cross-sectional view and the cross-sectional shape is square so as to have a predetermined length (l) and thickness (t) in the longitudinal direction and extend in the longitudinal and transverse directions. It can be seen that the cross-sectional shape is formed as a rectangular member as a whole.

At this time, in the case of the slab formwork to form a haunche 20 to be inclined downward from the inner end of the slab to extend to the upper connection portion of the point wall portion, which is to generate a bending parent (-M1) in the haunche 20 Therefore, to secure the rigidity for this.

The haunting portion is formed to be inclined in a straight shape so as to be formed to a predetermined thickness, and a corner portion including the haunching portion may be referred to as a right angle portion.

Such a ramen structure 10 can be said to be an efficient and economical bridge in a relatively short space (approximately 10-15m) since construction is easy because the slab is directly constructed without using a girder for bridges.

In this case, in order to construct the ramen structure in the long span, the extension length (longitudinal direction) of the slab 11 should be larger, and as the extension length of the slab becomes longer, the self weight of the slab increases, thereby increasing the thickness of the cross section. I need to.

However, when the thickness of the slab increases, the geometry of the bridge is reduced, so there is a problem in that it is impossible to construct the ramen structure in the long time when the geometry is restricted.

In addition, even if there is no restriction on the mold space, the slab weight increases as the thickness of the slab increases, so if the slab and bottom wall parts and the bottom plate need to be designed to resist such weight, they must be manufactured to an excessive size. There was a problem that it is very vulnerable to its aesthetics and usability.

Figures 1b, 1c and 1d in particular are installed on the upper surface of the wall unit 20 installed on the base 10 in a precast longitudinal unit 30 to be in contact with each other in the transverse direction, the precast longitudinal unit An end of the precast longitudinal unit 30 is installed at an end portion of the precast longitudinal unit 30 so that the end portion of each precast longitudinal unit 30 passes upward and downward. It is constructed in such a way as to harden, but the longitudinal tension member of each precast longitudinal unit 30 is further installed so that it is fixed after tension on both end faces of the precast longitudinal unit so that the prestress is introduced to the construction more construction The method of constructing the structure is introduced.

In other words, it can be seen that the construction of the wall unit 20, the longitudinal unit 30 in the pre-cats method for the construction of the ramen structure.

However, the ramen structure structure has a problem in that it is difficult to construct a ramen structure between long and long when the bending parent moment does not control because the bending parent moment occurs in the right corner portion, the wall of each precast longitudinal unit 30 In order to harden the unit 20 and the PC steel, the through-hole 31 formed in the precast longitudinal unit 30 is relatively precisely corresponding to the position of the PC steel installed so as to extend upwardly in the wall unit 20. In fact, when working in the field, the position of each other does not match with each other, so it may not only reduce the constructability,

Furthermore, when the precast longitudinal unit 20 is manufactured to have a long span in the longitudinal direction, there is a problem that resistance to buckling and torsion is inevitably lowered when the prestress is introduced and constructed by the longitudinal tension member.

Accordingly, the present invention allows the construction of the ramen structure in a prefabricated manner to enable constructability and shortening of air, and to make the ramen structure consist of a precast wall part and a precast slab. It is a technical problem to solve the provision of a method for economically providing a prefabricated ramen structure between long and long, so that the connection between the precast wall part and the precast slab is also configured efficiently and economically.

The present invention to achieve the above object

First, it is basically composed of the foundation, precast wall and precast slab, but prefabricated to each other,

Second, the central bending moment reducing part was installed at the center of the precast slab to offset the deflection of the precast slab by using the earth pressure acting on the precast slab. Further installation was made to improve the resistance against deflection of the precast slab.

Third, the structurally fragile corner part in the ramen structure is reinforced with steel, but the corner part steel is formed to be embedded at both ends of the precast slab to have structural efficiency in connecting the corner part with the precast wall part.

Fourth, the precast wall part and the right angled part of the precast slab are connected to each other by a stepped connection part to have structural efficiency.

Fifth, the precast wall portion and the base portion are connected to each other in a hinged state so that excessive bending moments are not generated to increase structural efficiency.

According to the present invention, the construction of the ramen structure can be prefabricated to enable construction quality and shortening of air, and the construction of the ramen structure can be performed between long and long spans.

An embodiment of the present invention described above and shown in the drawings should not be construed as limiting the technical idea of the present invention. The protection scope of the present invention is limited only by the matters described in the claims, and those skilled in the art can change and change the technical idea of the present invention in various forms. Accordingly, such improvements and modifications are within the scope of the present invention as long as they are obvious to those skilled in the art.

BRIEF DESCRIPTION OF THE DRAWINGS In order to describe the present invention more clearly and easily, the following describes the best embodiments of the present invention in detail with reference to the accompanying drawings. Is not limited to the embodiments described below.

First, as shown in FIG. 2A, the foundation 100 is installed.

The foundation portion 100 may be referred to as a structure for supporting the precast wall portion 200 and the slab 300 from the bottom as a base of the ramen structure.

The base portion 100 is installed spaced apart to face each other, but is also installed to extend in the transverse direction and can also be installed in the field casting method by formwork and concrete pouring, it may be installed in a precast method.

In the present invention, since the ramen structure is installed in a prefabricated manner, it is preferably installed in a precast method. However, the foundation part 100 may be installed in a site casting method in the field conditions in consideration of the destroyed ground and the road direction gradient. It may be preferable, and in the present invention, it is based on the case of installing in a precast manner.

The base part 100 installed in the precast method is a reinforced concrete structure of a spherical shape, which is pre-fabricated in a factory or the like, and is installed on the ground or cut ground A to be connected in the longitudinal direction.

In the case of the base portion 100 installed to be connected in the longitudinal direction it is necessary to connect to each other, this connection is very effective in the uneven settlement of the cracked ground (A).

In this connection method, the present invention allows the protruding block 110 to be further formed on the connection parts of the base part 100 so that the protruding blocks are connected to each other by a connecting member 120 including a steel bar and a fastening nut.

In the case of FIG. 2A, the protruding block 110 is installed on the upper surface and the side surface of the protruding block 110, and is connected to each other by, for example, a fastening nut using a connecting member 120 including the protruding block 110 and the steel bar of the adjacent base part 100. You can do that.

The protruding block 110 may be previously formed integrally at the time of fabrication of the foundation portion 100, or may be attached separately using anchor bolts, if necessary.

In order to connect the lower end of the precast wall portion 200, which will be described later, to the hinged state in the form of a shear key, the upper surface of the foundation 100 may have various shapes such as FIGS. 2B and 3A to 3E. Will handle

In the case of Figure 3a it can be seen that the front end groove 130 is formed on the upper surface of the base portion 100 so that the lower end of the precast wall portion 200 to be described later is inserted into the shear groove 130. Thus, the base part 100 has a lower end of the precast wall part 200 because it is not structurally fixed. Therefore, it can be seen that the bending moment M is not generated, and only a part of the shear force V due to the shear groove is generated. It can be seen that.

In general, the side of the precast wall 200 in the ramen structure is backfilled to generate a horizontal earth pressure, which can be referred to as the shear force (V) by the shear groove 130 to be able to resist such horizontal earth pressure. And, accordingly, when the precast wall portion 200 is installed so as to be self-supporting to the base portion 100, it is to ensure the safety for conduction in construction and the like.

That is, the lower end of the precast wall portion 200 is installed in the shear groove 130 to be connected in a hinged state.

In the case of FIG. 3B, the shear groove 240 is formed on the bottom surface of the lower end of the precast wall part 200 to be described later, and the protruding shear key 140 is formed on the upper surface of the foundation part 100. By the bottom of the precast wall portion 200 is shown to be able to be structurally installed in a hinged state.

In the case of FIG. 3C, the lower end of the precast wall part 200, which is not in the shape of the shear grooves 130 and 240 and the shear key 140 described above, is formed as the expansion flange part 250 and is directly supported on the upper surface of the base part 100. For example, if necessary, the expansion flange 250 is fixed to the foundation 100 by using the anchor 260, and the anchor is removed when construction of the ramen structure is completed later.

In the case of Figure 3d based on the expansion flange 250 and the anchor 260 according to Figure 3c, as shown in Figure 3a precast wall portion 200 by the shear groove 130 formed on the upper surface of the base portion 100 ) Is to be further engaged with the lower end.

In the case of Figure 3e based on the expansion flange 250 and the anchor 260 according to Figure 3c, the shear groove 240 as shown in Figure 3b to be formed on the bottom bottom surface of the precast wall portion 200, the foundation This is the case where the protruding shear key 140 is further formed on the upper portion of the part 100.

The precast wall part 200 is a wall structure that is installed to be connected to each other in the longitudinal direction, and has a predetermined extension length in the longitudinal direction.

Thus, when the installation of the base portion 100 is completed, as shown in FIG. 2b, the precast wall portion 200 is installed so that it can stand on its own.

The precast wall part 200 is a wall structure that is installed to be connected to each other in the longitudinal direction, and has a predetermined extension length in the longitudinal direction.

Accordingly, the precast wall portion 200 has a vertical body portion thickness between the vertical body portion 210 and the vertical body portion side, the height of which extends upwardly on the upper surface of the base portion 100 to the right angle entry height H only. The panel portion 220 is formed to have a thickness d smaller than (D).

The precast wall portion 200 is installed in the longitudinal direction in succession to the base portion 100, the vertical body portion 210 and the vertical body portion to connect the precast wall portion 200 to each other 210 will be connected.

Accordingly, the vertical body portion 210 and the vertical body portion 210 adjacent to each other may be pressed and connected to each other using a connecting member 120 including a steel rod so that the vertical body portion 210 and the vertical body portion 210 are continuously installed in the longitudinal direction.

In addition, the panel 220 has a horizontal block 230 is further installed between the vertical body portion 210 to facilitate the reinforcement of the precast wall 200, in particular the thickness (d) of the panel 220 To optimize it.

The horizontal block 230 may be formed at a time integrally when manufacturing the precast wall portion 200, it may be formed separately.

The precast wall portion 200 by the vertical body portion 210 and the panel portion 220 has a function to allow the panel portion 220 to act as a two-way slab by the horizontal block 230, and the position and What is necessary is just to determine the number according to the height of the precast wall part 200.

The height of the precast wall portion 200 is to extend only to the entry height (H) of the right angle portion 310, as shown in Figure 2c of the right angle portion of the completed ramen structure, which is to form a connection portion of the members in the right angle portion Because of the large bending moment (-M2) due to the nature of the in order to prevent the connection portion is located in the right corner.

The right angle 310 is formed by the precast slab 300, not the precast wall portion 200 as shown in FIG.

The precast slab 300 is composed of a slab plate 320 between the right angle portion 310 and the right angle portion on the upper surface of the precast wall portion 200, it can be referred to as a reinforced concrete structure of the U-shape as a whole.

Since the right angle part 310 is a portion where the bending parent moment (-M2) is largely generated in the ramen structure, the right angle steel material 400 is further formed therein, thereby greatly improving the bending rigidity.

The slab plate 320 is formed between the right angled part 310. The slab plate 320 is also formed such that the central bending moment reduction part 500 protrudes upward to increase the bending rigidity.

At this time, the central bending moment reduction portion 500 is a structural member having a cross-section as a whole, the upper horizontal portion connecting the upper vertical portion 510 and the upper vertical portion 510 extending upwardly spaced apart from each other. It consists of a part 520.

The side of the upper vertical portion 510 of the central bending moment reducing portion 500 is later covered to generate a earth pressure (P).

The earth pressure (P) can be seen that the bending parent moment (-M3) is generated based on the upper surface of the slab plate 320, this bending constant moment (-M3) is the bending that occurs in the slab plate 320 eventually The positive moment (+ M1) is to offset the role.

Therefore, it can be seen that the bending constant moment generated even by increasing the length of the slab plate 320 can be offset, thereby reducing the bending parent moment (-M2) generated in the right corner 310 together. do.

Next, between the lower end of the upper vertical portion 510, the horizontal tension member 530 to be fixed after the tension between the lower portion of the upper vertical portion 510 is installed.

After the tension of the horizontal tension member 530, the additional bending parent moment (-M4) is generated between the lower ends of the upper vertical portion 510 by arbitrarily adjusting the width and size of the central bending moment reduction part 500. Since it is not easy to do so, it can be used as a means for easily adjusting it.

At this time, the saddle 540 is further installed between the bottom surface of the upper horizontal portion 520 and the horizontal tension member 530 installed to enhance the effect of the bending parent moment (-M4) by the horizontal tension member 530. There will be.

That is, the compression prestress can easily raise the central bending moment reduction part 500 upward by the saddle, thereby facilitating the generation of additional bending parent moment (-M4) by the horizontal tension member 530. .

The precast slab 300 and the precast slab 300 to be integrated with each other by the connecting member 120 in the longitudinal direction.

Furthermore, looking at the connection form of the lower end of the right angle portion 310 and the upper end of the precast wall portion 200,

First, the upper end of the precast wall portion 200 is to be formed stepped (B), it is installed so that the lower end of the right corner portion is supported on the upper surface (B).

The reason for this installation is that when the lower end of the precast slab 300 is eccentrically supported on the upper surface B of the precast wall body 200, the bending positive moment (+ M5) is generated. Since the bending positive moment (+ M5) serves to offset the bending parent moment (-M2) by the right angle part, the ramen structure according to the present invention is relatively easy to manufacture and install the precast slab 300 between the long sections. It can be seen that.

Next, in the stepped portion, the precast wall portion 200 and the precast slab 300 are connected to each other by a connecting member 120 including a steel rod, so that the precast wall portion 200 and the precast slab 300 are mutually connected. To be integrated.

As such, when the installation of the precast slab 300 is completed, as shown in FIG. 2D, the covering of the precast wall part 200 and / or the upper part of the precast slab 300 may be applied to cover the construction of the ramen-type structure. To help.

1A, 1B, 1C and 1D show examples of conventional ramen structures.

Figures 2a, 2b, 2c and 2d is a work flow diagram of the prefabricated ramen structure construction method according to the present invention.

3A, 3B, 3C, 3D and 3E are connection diagrams of the base portion of the present invention and the bottom of the precast wall portion.

<Description of the symbols for the main parts of the drawings>

100: base part 110: protrusion block

120: connector 200: precast wall portion

210: vertical body portion 220: panel portion

230: vertical connection block 240: horizontal block

300: precast slab 310: right corner

320: slab plate 400: right angle steel

Claims (5)

Install the base 100, After installing the lower end of the precast wall portion 200 on the upper surface of the base portion, the precast slab 300 is assembled and installed on the upper portion of the precast wall portion 200, but the ramen bridge is installed to be embedded in the ground. In the method, While fixing the precast slab 300 consisting of a slab plate 320 between the right angle portion 310 and the right angle portion on the upper surface of the precast wall 200 to be connected to each other in the transverse direction, but inside the right angle portion To ensure that the right angle steel 400 is purchased, The central portion of the precast slab 300 is formed so that the central bending moment reducing portion 500 protrudes upwards, the central bending moment reducing portion 500 is spaced apart from each other as a structural member having a cross-section as a whole Method of constructing a long-term ramen structure between the protruding upper vertical portion (510) and the upper vertical portion (520) connecting the upper vertical portion (510) to each other. According to claim 1, wherein the horizontal tension member 530 to be fixed after the tension between the upper vertical portion 510 is further installed, the saddle (between the bottom of the upper horizontal portion 520 and the horizontal tension member 530 installed) The construction method of the long-term ramen structure to include an additional step 540). The longitudinal connection of the precast wall portion 200 according to claim 1. The vertical body part 210 and the vertical body part 210 of the precast wall part 200 may be connected to each other using the connecting member 120 including the steel bar, and the panel part 220 of the precast slab 300. ) Between the vertical body portion 210 and the horizontal block 230 is a long-term ramen structure construction method to be further installed. The method of claim 3, Connection of the precast slab 300 to the upper surface of the precast wall portion 200 is installed so as to step up the upper surface of the vertical body portion 210 constituting the precast wall portion 200, the precast slab 300 After the lower end of the right angle portion 310 of the) to be supported by the stepped portion (B), the long piece between the precast wall portion 200 and the precast slab 300 is connected to each other by a connecting member 120 including a steel rod How to construct a ramen structure. According to claim 4, The base portion 100 is to be installed in a cast-in-place or precast method, when the precast method is installed, the protruding block 110 to the base connection parts in order to connect the base parts to each other Method for constructing a long-term ramen structure to be formed so that the protruding blocks are connected to each other by a connecting member (120) including a steel bar to be connected to the base in the transverse direction.

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