KR20220013346A - Permanent beam bonding structure that is joined to the core part during reverse rudder construction, permanent beam installation method using this and removal method of temporary members for joining - Google Patents

Abstract

The present invention provides a permanent beam joint structure joined to a core part during top-down construction, a permanent beam installation method with the same applied thereto, and a method of removing a temporary member for joining with respect to the permanent beam joint structure. The structure comprises: temporary columns erected adjacent to the core part to be installed later; temporary beams installed on the temporary columns; a permanent beam installed between the temporary beams toward the core part and fixed to the core part; and a beam joint part which connects the temporary and permanent beams to each other by joining the temporary and permanent beams together. Structural stability of the structure can be secured by integrally constructing the columns and the beams of the steel structure installed during building construction and the trailing core part. In addition, dismantlement of the temporary column temporally constructed to support the beam connected to the column can be easy, thereby increasing workability.

Description

PERMANENT BEAM BONDING STRUCTURE THAT IS JOINED TO THE CORE PART DURING REVERSE RUDDER CONSTRUCTION, PERMANENT BEAM INSTALLATION METHOD USING THIS AND REMOVAL METHOD OF TEMPORARY MEMBERS FOR JOINING}

The present invention relates to a permanent beam joint structure joined to a core part during reverse construction, a permanent beam installation method to which the same is applied, and a temporary temporary member removal method for joining, and more particularly, to columns and beams of steel structures installed during building construction The structural stability of the structure can be secured by integrally constructing the core part, and the permanent beam joined to the core part during reverse construction, which can improve work easiness by making it easy to dismantle temporary columns to support the beams connected to the columns. It relates to a joint structure, a method for installing a permanent beam to which it is applied, and a method for removing temporary members for joining.

In general, when constructing a building, the Open Cut method, which builds the structure after excavation is completed without a temporary retaining wall, or the installation of a horizontal earth pressure support temporary material (strut and Earth Anchor) after pre-construction of an external underground wall (temporary retaining wall or underground continuous wall) After excavation is completed, the top-down construction method can be constructed in a direction from the top to the bottom, unlike the straight drilling method, which starts from the lower layer and proceeds in the order of the upper layer by repeating the excavation and excavation work.

Here, the top-down method refers to the construction of the external underground wall (temporary retaining wall or continuous underground wall), the underground column, and the cast-in-place pile supporting the column before excavation work, and then the basement slab and excavation work are carried out step by step from top to bottom. It is a construction method that supports earth pressure by repeatedly forming underground structures. This construction method can be stably applied to large-scale excavation, deep excavation, or downtown areas with many adjacent buildings, which are difficult to plan with the conventional drilling method. Therefore, it can be said that it is an all-weather construction method that can be installed even in rain and snow.

In addition, the top-down method can be advantageous in terms of shortening the construction period because the underground construction and the above-ground construction can be carried out in parallel. This is because it can proceed concurrently with the ground floor. In addition, the above-ground structure can be divided into core leading simultaneous casting, outer perimeter leading (or core trailing) depending on the construction method, but the columns, the core, and the floor slab must be constructed simultaneously or sequentially.

On the other hand, at this time, the core part constitutes a concrete pouring part of a rectangular structure such as a staircase room, an elevator room, and a facility facility in the construction of a building, and serves as a load-bearing structure of the building. It constitutes a structure in which the vertical columns, girders and beams composed of the structure are integrated together by embedding a part of the steel structure inside the core part.

However, in general, when constructing a building, it is necessary to install a permanent girder (beam) in the adjacent permanent column part before constructing the core part. couldn't Therefore, a temporary column is installed around the core part, and a temporary beam connected to the temporary column is installed first, and then a girder connected to an adjacent permanent column is installed. Because it can be cast.

On the other hand, referring to FIGS. 1 and 2 , before the core part 10 is constructed, a temporary post 20 is installed in the periphery where the core part 10 is to be installed, and the temporary post 20 and the temporary post 20 are installed. ) and construct a temporary beam connecting between Here, as the intermediate member, as shown in Fig. 1, the temporary column reinforcement T-bar 30 and the stud bolt 40 are used, or as shown in Fig. 2, a stud bolt is applied to the temporary column. can be connected right away.

After that, a permanent beam (or a permanent girder) that is extended and connected to the permanent column is installed on one side of the temporary column, and a T-shaped reinforcing T-bar is constructed on the core part of the other side of the temporary column where the permanent beam is installed to make it permanent. A method of constructing the beam so that it is partially buried inside the core part is being used.

On the other hand, unlike the temporary pillar, the part where the temporary beam is installed is not buried in the core wall (core part). For this reason, as shown in FIG. 3, the formwork is installed so that the concrete protrudes from the core wall to some extent, and the studs 40 are connected to the temporary beams 50, and then the studs 40 are connected to the protruding concrete. Thus, the core wall 10 and the temporary beam 50 can be integrated.

However, in this case, it is very difficult to work, and there is a inconvenience of having to separately manufacture the formwork for small parts, and there is a problem that a separate fireproof work must be performed when the temporary beam is left as it is after construction.

According to the above, only when both ends of the permanent beam are supported and fixed by the permanent column or core part, the slab to be poured on the upper end of the permanent beam is stably installed, and structural stability can be secured as a whole.

On the other hand, as shown in FIG. 4, the temporary beam can be cut and cut after construction, and at this time, the temporary pillar 20 can also be cut and cut after the core wall 10 is hardened.

Looking at this, the worker has to cut welding in the upward direction depending on the installation location of the temporary beam. As the worker is exposed to a hazardous environment due to sparks generated during the upward welding cutting process, the temporary beam is installed to prevent such a safety accident. The temporary beam remaining after removal is installed with a formwork at a position slightly protruding from the core part, and a stud is connected to one end of the temporary beam facing the core part, and concrete is poured as much as the temporary beam protrudes, thereby integrating the temporary beam and the core part.

As described above, the conventional permanent beam installation and temporary member removal work has a problem in that the construction period and construction cost increase as a separate formwork has to be manufactured to match the size of the temporary beam protruding from the core part, and also, if the temporary beam If the beam is not integrated with the core, a separate fire-resistance operation must be performed for the remaining temporary beams, so there is a problem in that additional work and construction costs are incurred due to this additional operation.

Korean Patent Publication No. 10-1162971 (2012.07.09.)

According to the present invention, it is possible to secure the integrity of the permanent beam and the core part by integrally constructing the columns and beams and the trailing core part of the steel structure installed at the time of building construction, and at the same time, it is possible to reduce the air and construction cost, and for the remaining temporary beams Since there is no need for separate fire-resistance work, it is possible to eliminate additional construction costs and construction costs due to additional work. An object of the present invention is to provide a permanent beam joint structure that is joined to the core part during reverse construction, which can reduce construction costs by doing so, a permanent beam installation method using the same, and a temporary temporary member removal method for joining.

According to one aspect of the present invention, the present invention, and the temporary pillars erected adjacent to the core portion installed in the trailing; and temporary beams installed on the temporary pillars; a permanent beam installed between the temporary beams toward the core part and fixed to the core part; and a beam joint part connecting the temporary beam and the permanent beam to each other by joining the temporary beam and the permanent beam to each other.

According to another embodiment of the present invention, I-beam or H-beam may be applied to the temporary beam.

According to another embodiment of the present invention, an I-beam or an H-beam may be applied to the permanent beam.

According to another embodiment of the present invention, the beam joint portion is respectively fastened to a connecting member coupled to both sides of the permanent beam facing the temporary beams, and to the end side of the connecting member and the temporary beam facing each other, A first fastening means for removably coupling the connecting member and the temporary beam to each other, the upper surface of the connecting member, the upper surface of the temporary beam, and the lower surface of the connecting member and the lower surface of the temporary beam are detachable from each other It may be configured to include a second fastening means for fastening.

According to another embodiment of the present invention, the beam joint portion, a connecting member each coupled to both sides of the permanent beam facing the temporary beam, and the connecting member facing each other and each fastened to the end side of the temporary beam, A first fastening means for removably coupling the connecting member and the temporary beam to each other, a second fastening means for removably coupling the lower end surface of the connecting member and the lower end surface of the temporary beam to each other, and the upper end of the connecting member It may be configured to include an insertion coupling member that is fitted in the space between the side surface and the upper side of the temporary beam to connect the upper side of the connecting member and the upper side of the temporary beam with each other.

According to another embodiment of the present invention, the beam joint portion is formed at the ends of the temporary beams, and the connecting members are respectively coupled to both sides of the permanent beams, and the connecting members are located at a set separation distance from both ends of the permanent beams. It may be provided to protrude from the upper surface of the slab, and to be exposed from the slab on the upper side of the temporary beam and the permanent beam, and may include a slab shielding member that exposes the connecting member when removed.

According to another embodiment of the present invention, the connecting member may be formed integrally with the temporary beam.

According to another embodiment of the present invention, the permanent beam is formed extending from the permanent pillar in the direction of the core portion, the permanent beam body portion to which the beam joint is coupled to both sides, and one end is joined to the end of the permanent beam body portion, The other end may be configured to include a permanent beam extension part that is embedded and fixed in the interior of the core part.

According to another embodiment of the present invention, the present invention is a temporary pillar erected adjacent to the core portion is installed later and; and temporary beams installed on the temporary pillars; A permanent beam body part installed between the temporary beams toward the core part and fixed to the core part, extending from the permanent pillar in the direction of the core part, and coupled to the beam joint part on both sides, and one end of the permanent beam body a permanent beam joined to the end of the part and including a permanent beam extension part at the other end of which is embedded and fixed in the interior of the core part; In the permanent beam joint structure joined to the core part during reverse construction, characterized in that it comprises; step; installing temporary beams on the temporary pillars; a permanent beam installation step of locating the permanent beam body across the temporary beam and connecting the permanent beam body and the temporary beam to each other through the beam joint; and a core part installation step of installing one end of the extension part of the permanent beam in the main body of the permanent beam and fixing the other end of the extension part of the permanent beam to the core part to integrate the permanent beam and the core part. .

According to another embodiment of the present invention, the permanent beam installation step includes the steps of joining and coupling the connecting members on both sides of the permanent beam body, respectively, and first fastening the connecting member facing each other and the end side of the temporary beam The steps of detachably coupling each other through means, and the upper surface of the connecting member, the upper surface of the temporary beam, and the lower surface of the connecting member and the lower surface of the temporary beam to be detachably connected to each other through a second fastening means. It may be configured including the step of combining.

According to another embodiment of the present invention, the permanent beam installation step includes the steps of joining and coupling the connecting members on both sides of the permanent beam body, respectively, and first fastening the connecting member facing each other and the end side of the temporary beam Removably coupling each other through means, the steps of detachably coupling the lower end surface of the connecting member and the lower end surface of the temporary beam to each other through a second fastening means, the upper side of the connecting member and the temporary beam It may be configured to include the step of connecting the upper side of the connecting member and the upper side of the temporary beam to each other by fitting the insertion coupling member in the spaced apart space between the upper side of the beam.

According to another embodiment of the present invention, the permanent beam installation step includes the steps of bonding and coupling the connecting members on both sides of the permanent beam body, respectively, and the temporary beam and the permanent beam are formed to protrude from the slab on the upper side of the slab. When removed after formation, it may be configured to include the step of installing a slab shielding member to expose the connection member.

According to another embodiment of the present invention, the present invention is a temporary pillar erected adjacent to the core portion is installed later and; and temporary beams installed on the temporary pillars; a permanent beam installed between the temporary beams toward the core part; In order to remove the temporary member from the permanent beam joint structure joined to the core part during reverse construction, characterized in that it comprises; removing the temporary beam from the permanent beam by dismantling the beam joint; It characterized in that it comprises; removing the temporary pillars.

On the other hand, since the description of the technology disclosed in this specification is merely an embodiment for structural or functional description, the scope of the disclosed technology should not be construed as being limited by the embodiment described in the text. That is, since the embodiment may have various changes and may have various forms, it should be understood that the scope of the disclosed technology includes equivalents capable of realizing the technical idea. In addition, since the object or effect presented in the disclosed technology does not mean that a specific embodiment should include all of them or only such effects, it should not be understood that the scope of the disclosed technology is limited thereby.

In addition, the meaning of the terms described in the present invention should be understood as follows. Terms such as “first” and “second” are for distinguishing one component from another, and the scope of rights should not be limited by these terms. For example, a first component may be termed a second component, and similarly a second component may be termed a first component.

Furthermore, when it is mentioned that a certain element is "connected" to another element, it may be directly connected to the other element, but it should be understood that other elements may exist in between. On the other hand, when it is mentioned that a certain element is "directly connected" to another element, it should be understood that the other element does not exist in the middle. On the other hand, other expressions describing the relationship between elements, that is, "between" and "between" or "neighboring to" and "directly adjacent to", etc., should be interpreted similarly.

The singular expression is to be understood to include the plural expression unless the context clearly dictates otherwise, and terms such as "comprises" or "have" refer to the specified feature, number, step, action, component, part or these It is intended to indicate that a combination exists, and it should be understood that it does not preclude the possibility of the existence or addition of one or more other features or numbers, steps, operations, components, parts, or combinations thereof.

According to the present invention, the permanent beam joint structure joined to the core part during reverse construction, the permanent beam installation method and the temporary member removal method for joining are integrally constructed with the columns and beams of the steel structure installed during building construction and the trailing core part Thus, it is possible to secure the structural stability of the structure, and it is possible to improve the ease of work by making it easy to dismantle a temporary column that is erected to support the beam connected to the column.

In addition, it is possible to secure the integrity of the permanent beam and the core part by integrally constructing the columns and beams and the trailing core part of the steel structure installed during building construction, and at the same time save time and construction costs. Since there is no need for fireproof work, additional work and construction costs can be eliminated, and the temporary columns and beams installed around the core can be easily removed to shorten the construction period and secure the safety of the working environment. It is possible to reduce the cost.

In addition, in order to construct a building, it is possible to integrate with the core wall followed by a permanent column constructed as a basis and a permanent beam installed from the permanent column to secure structural stability, simplifying the core opening, and at the same time simplifying the core opening with Cheolgol beam The junction between the RC walls can be deleted, and the temporary columns and beams that are installed to support the permanent beams can be easily removed, reducing the manpower input due to the removal of the temporary columns and the temporary beams, and the temporary columns after installing the permanent beams and permanent beams. And by removing the temporary beam, it is possible to omit the fire-resistance and insulation work of the temporary beam.

1 to 3 are views showing the structures of temporary columns and temporary beams installed with respect to the core wall.
4 is a view showing a case in which a temporary beam and a part of a temporary column are cut after the construction of the temporary beam.
5 is a view showing a permanent beam joint structure to be joined to the core portion during reverse rudder construction according to an embodiment of the present invention.
6 is a view showing a beam joint in the permanent beam joint structure joined to the core part during reverse rudder construction according to an embodiment of the present invention.
7 is a view showing another embodiment of the beam joint in the permanent beam joint structure joined to the core part during reverse rudder construction according to an embodiment of the present invention.
8 is a view showing another embodiment of the beam joint in the permanent beam joint structure joined to the core part during reverse rudder construction according to an embodiment of the present invention.
9 is a view showing pictures in the field to which a permanent beam joint structure joined to a core part during reverse rudder construction according to an embodiment of the present invention is applied.

Hereinafter, it will be described in more detail with reference to preferred embodiments to which the present invention pertains.

Referring to FIG. 5 , the permanent beam joint structure (hereinafter referred to as 'permanent beam joint structure') joined to the core part 1 during reverse rudder construction according to an embodiment of the present invention includes temporary columns and temporary beams 2 ), and the permanent beam 100 and the beam joint 200 may be configured.

The temporary pillar is erected adjacent to the core part 1 to be installed later, and in detail, it is spaced apart by a set distance around the core part 1 and can be continuously erected vertically.

Temporary beams (2) are installed on temporary columns, and may be installed horizontally between the temporary neighboring temporary columns that have been erected. Here, the temporary beam (2), I-beam or H-beam may be applied, but it is of course that other members may be applied if the above object and function can be achieved in a preferred embodiment.

The permanent beam 100 is installed between the temporary beams 2 toward the core part 1, and one end is embedded and fixed in the core part 1, and is formed integrally with the core part 1 to form a structure of the building. Structural stability can be ensured. Such a permanent beam 100, I-beam or H-beam can be applied.

On the other hand, the permanent beam 100 is formed extending in the direction of the core part 1 from the permanent beam, and the permanent beam body part 110 to which the beam joint 200 is coupled to both sides, and one end of the permanent beam body part 110 It is bonded to the end of the other end may be configured to include a permanent beam extension 120 is embedded in the interior of the core portion (1).

Here, the permanent beam body part 110 and the permanent beam extension part 120 may be integrally formed, but the permanent beam extension part 120 is separately included to effectively respond to the separation distance from the core part 1 in the field. It is preferable to connect with the permanent beam body part 110 .

Furthermore, the permanent beam extension 120 may be provided with a bonding member such as a T-bar or stud bolt to improve bonding with the core unit 1 at the end embedded in the core unit 1 .

Here, looking at the installation process of the temporary beam (2) and the permanent beam (100) described above, first, the temporary beam (2) is first installed between both temporary columns. Then, the permanent beam body part 110 is installed between the temporary beam 2 and the permanent beam opposite the core part 1 (core wall), and then between the temporary beam 2 and the core part 1, the permanent beam is installed. The extension 120 may be installed.

The beam joint 200 serves to connect the temporary beam 2 and the permanent beam 100 to each other to connect the temporary beam 2 and the permanent beam 100 to each other.

As shown, when the permanent beam 100 and the temporary beam 2 and the beam joint 200 apply an I-beam or an H-beam, one end of the permanent beam body 110 is a web portion of the beam joint 200 . may be welded to, and one side of the temporary beam 2 is jointly coupled to both ends of the beam joint 200, and the permanent beam body part is connected to the web at the other end of the beam joint 200 to which the permanent beam body is joined. A permanent beam extension 120 formed extending from 110 is embedded in the core portion 1 .

Furthermore, the above-described permanent beam 100 and the beam joint 200 may be arranged in a cross-sectional shape that is orthogonal to each other.

The beam joint 200 may be manufactured like the permanent beam 100 , and thus, the permanent beam 100 and the temporary beam 2 to which the beam joint 200 is coupled can be assembled and constructed in the field.

Hereinafter, various embodiments of the above-described beam joint 200 will be described.

6 is a view showing the beam joint 200 according to the first embodiment. Referring to FIG. 6 , the beam joint 200 may include a connecting member 211 , a first fastening means 212 , and a second fastening means 213 .

The connecting member 211 is coupled to both sides of the permanent beam 100 facing the temporary beams 2, respectively. Here, the connecting member 211 is preferably welded to the permanent beam 100 .

The first fastening means 212 may be respectively fastened to the end side surfaces of the connecting member 211 and the temporary beam 2 facing each other to detachably couple the connecting member 211 and the temporary beam 2 to each other. . Here, the first fastening means 212 passes through a contact plate in contact with the front and rear side surfaces of each of the connection member 211 and the temporary beam 2, and the contact plate, the connection member 211 and the temporary beam 2 at the same time. It may be configured to include a fastening bolt to be fastened.

The second fastening means 213 is detachably coupled to the upper surface of the connecting member 211 and the upper surface of the temporary beam 2 and the lower surface of the connecting member 211 and the lower surface of the temporary beam 2 to each other. can do it The second fastening means 213 includes a connecting plate connecting the temporary beam 2 and each of the upper and lower surfaces of the connecting means in contact with and connecting the connecting plate and the temporary beam 2 and the connecting member 211 at the same time. It may be configured to include a fastening bolt that is fastened through. Meanwhile, in the following drawings, reference numeral A denotes a welded portion.

According to the above, in the beam joint 200 according to the first embodiment, the upper flange, the web, and the lower flange of the temporary beam 2 are connected by the second fastening means 213, and the temporary beam 2 is dismantled. When the second fastening means 213 connected to each other is disassembled, the temporary beam 2 may be removed.

7 is a view showing the beam joint 200 according to the second embodiment. Referring to FIG. 7 , the beam joint 200 may include a connecting member 221 , a first fastening means 222 , a second fastening means 223 , and an insertion coupling member 224 . have.

The connecting member 221 is coupled to both sides of the permanent beam 100 facing the temporary beam (2), respectively.

The first fastening means 222 is respectively fastened to the end side surfaces of the connecting member 221 and the temporary beam 2 facing each other to detachably couple the connecting member 221 and the temporary beam 2 to each other. Here, the first fastening means 222 is a contact plate in contact with each side of the connecting member 221 and the temporary beam 2, and the contact plate, the connecting member 221 and the temporary beam 2 are simultaneously penetrated through and fastened. It may be configured to include a fastening bolt.

The second fastening means 223 detachably couples the lower end surface of the connecting member 221 and the lower end surface of the temporary beam 2 to each other. The second fastening means 223 is a connecting plate connecting the temporary beam 2 and the connecting means in contact with each lower surface, and the connecting plate and the temporary beam 2 and the connecting member 221 through and fastened at the same time. It may be configured to include a fastening bolt.

The insertion coupling member 224 is fitted in the spaced space between the upper side of the connecting member 221 and the upper side of the temporary beam 2, and the upper side of the connecting member 221 and the upper side of the temporary beam 2 connect each other

Here, the insertion coupling member 224, a plate having a set thickness can be applied, and is formed in a wedge shape as shown in the figure, and when the temporary beam 2 is installed, when pressed from the upper part, it is fitted in close contact with the spaced space. can be fixed.

On the other hand, when dismantling the temporary beam 2 in the above case, the first fastening means 222 and the second fastening means 223 coupled to the connecting member 221 and the web of the temporary beam 2 and the lower flange are disassembled. Then, since the upper flange is not in a fixedly coupled state, it naturally falls off by its own weight.

8 is a view showing the beam joint 200 according to the third embodiment. Referring to FIG. 8 , the beam joint 200 may include a connecting member 231 and a slab shielding member 233 .

The connecting member 231 is formed at the ends of the temporary beams 2 and coupled to both sides of the permanent beams 100 , respectively. Here, the connecting member 231 may be integrally formed with the temporary beam 2 as shown, and the connecting member 231 rather than the first fastening means 212 and 222 as in FIGS. 6 and 7 described above. And the temporary beam (2) can be installed in the form of an integrated cheolgolbo.

On the other hand, if you want to dismantle in this case, you need to cut the temporary beam 2 through oxygen cutting. have.

When the slab 3 is formed by pouring concrete in the shape of a plate having a set thickness, the slab shielding member 233 prevents concrete from being poured into the space where the slab shielding member 233 is installed, thereby providing a space that can be cut. plays a role in providing

The slab shielding member 233 is positioned at a set distance from both ends of the permanent beam 100 and is provided to protrude from the upper surface of the connecting member 231, the temporary beam 2 and the permanent beam 100 above the When the slab 3 is formed to protrude to be exposed and removed, the connection member 231 is exposed.

Accordingly, when the slab 3 is poured and cured and the slab 3 is formed later, when the temporary beam 2 is to be dismantled, the slab shielding member 233 is removed and then the slab shielding member 233 is located through the space. cutting can be done. In the drawings, reference numeral 232 denotes a cutting line.

As described above, in the slab shielding member 233, when the concrete constituting the slab 3 is poured and cured, the concrete is not poured on the upper side where the permanent beam 100 (connecting member 231) is located. , by cutting the left and right ends set separation distance around the permanent beam 100, the operator can safely remove the temporary beam (2) without cutting in the upward direction.

On the other hand, after installing the erection column (erection column) for the following core part (1) part, the permanent beam 100 can be installed, and also installed between the temporary beam 2 and the core part 1 The core part (1) form accessory (Form accessory) can be configured in the permanent beam 100 part.

Hereinafter, a permanent beam installation method (hereinafter referred to as a 'permanent beam installation method') to which a permanent beam joint structure joined to the core part 1 during reverse rudder construction according to an embodiment of the present invention is applied will be described.

The permanent beam installation method of the present invention is a method of installing the permanent beam 100 in the permanent beam joint structure that is joined to the core part 1 during the reverse rudder construction, first installs a temporary column, and then Install temporary beams (2).

When the temporary column and the temporary beam 2 are installed in this way, the permanent beam body part 110 is positioned across the temporary beam 2, and the permanent beam body part 110 and the temporary beam body part 110 and the temporary beam body part 110 through the beam joint part 200 ( 2) are connected to each other and the permanent beam 100 is installed.

The installation of the permanent beam 100 is possible in various ways according to the embodiments of the various beam joint parts 200, and in one embodiment, the connecting members 211 are respectively bonded to both sides of the permanent beam body part 110 to couple them. , after the connecting member 231 and the end side of the temporary beam 2 facing each other are detachably coupled to each other through the first fastening means 212, the upper surface of the connecting member 211 and the temporary beam (2) It may include a process of detachably coupling the upper surface of the and the lower surface of the connecting member 211 and the lower surface of the temporary beam 2 to each other through the second fastening means 213 .

Alternatively, this permanent beam 100 installation is coupled by bonding the connecting members 221 to both sides of the permanent beam main body 110, respectively, and the end side surfaces of the connecting member 221 and the temporary beam 2 facing each other is detachably coupled to each other through the first fastening means 222 , and then the lower end surface of the connecting member 221 and the lower end surface of the temporary beam 2 are detachably coupled to each other through the second fastening means 223 . and insert the coupling member 224 into the spaced space between the upper side of the connecting member 221 and the upper side of the temporary beam 2 to connect the upper side of the connecting member and the upper side of the temporary beam 2 to each other It may include the process of linking.

Alternatively, this permanent beam 100 installation is formed at the ends of the temporary beams 2 on both sides of the permanent beam main body 110 and connecting the connecting members 231 respectively coupled to both sides of the permanent beam 100, respectively. The slab shielding member (2) and the slab shielding member ( 233) can be installed. At this time, when the slab 3 is formed after curing the concrete, the upper side of the permanent beam 100 may be exposed by removing the slab shielding member 233 .

After that, one end of the permanent beam extension 120 is installed in the permanent beam body part 110, and the other end of the permanent beam extension part 120 is fixed to the core part 1, so that the permanent beam 100 and the core part ( 1) is integrated to install the core part (1). 9 is a photograph showing such a permanent beam joint structure.

Hereinafter, a method of removing a temporary member from a permanent beam joint structure joined to the core part 1 during reverse rudder construction according to an embodiment of the present invention will be described.

First, after installing the permanent beam 100 through the beam joint 200 as described above, unnecessary temporary members must be removed. To this end, the beam joint 200 is dismantled to remove the temporary beam 2 from the permanent beam 100, and then the temporary columns are removed.

At this time, the process of removing the temporary beam 2 by dismantling the beam joint 200 may be performed differently for each embodiment of the beam joint 200 . First, in the case of the embodiment of Fig. 6, the first fastening means 212 and the second fastening means 213 having a detachable structure can be disassembled to dismantle the beam joint 200, and thus the beam joint 200 is dismantled. After that, the temporary beam (2) can be removed.

Next, in the case of the embodiment of Figure 7, after disassembling the first fastening means 222 and the second fastening means 223, and then removing the insertion coupling member 224 to disassemble the beam joint 200, the temporary beam (2) ) can be removed.

Next, in the case of the embodiment of FIG. 8 , after removing the slab shielding member 233 , the temporary beam 2 may be removed from the upper side of the permanent beam 100 through an oxygen cutting method.

Although the above has been described with reference to preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention within the scope without departing from the spirit and scope of the present invention as set forth in the claims below. You can do what you can do.

1: core part 2: temporary beam
3: slab 100: permanent beam
110: permanent beam body part 120: permanent beam extension part
200: beam joint 211: connecting member
212: first fastening means 213: second fastening means
221: connecting member 222: first fastening means
223: second fastening means 224: insertion coupling member
231: connection member 232: cut line
233: slab shielding member

Claims (6)

Temporary pillars erected adjacent to the core to be installed later;
and temporary beams installed on the temporary pillars;
a permanent beam installed between the temporary beams toward the core part and fixed to the core part;
A permanent beam joint structure joined to the core part during reverse construction, comprising a; a beam joint part connecting the temporary beam and the permanent beam to each other by joining the temporary beam and the permanent beam to each other.
The method of claim 1,
The beam joint portion,
Connection members respectively coupled to both sides of the permanent beam facing the temporary beams;
First fastening means respectively fastened to the end side surfaces of the connecting member and the temporary beam facing each other to detachably couple the connecting member and the temporary beam to each other;
Core part during reverse rudder construction, characterized in that it comprises a second fastening means for removably coupling the upper surface of the connecting member and the upper surface of the temporary beam and the lower surface of the connecting member and the lower surface of the temporary beam to each other Permanent beam joint structure to be joined with
The method of claim 1,
The beam joint portion,
Connection members respectively coupled to both sides of the permanent beam facing the temporary beams;
First fastening means respectively fastened to the end side surfaces of the connecting member and the temporary beam facing each other to detachably couple the connecting member and the temporary beam to each other;
a second fastening means for removably coupling the lower end surface of the connecting member and the lower end surface of the temporary beam to each other;
Reverse construction, characterized in that it includes an insertion coupling member that is fitted in the space between the upper side of the connecting member and the upper side of the temporary beam to connect the upper side of the connecting member and the upper side of the temporary beam to each other. A permanent beam joint structure that is joined to the sea core.
The method of claim 1,
The permanent report,
A permanent beam body portion extending from the permanent pillar in the direction of the core portion, and the beam joint portion is coupled to both sides;
One end of the permanent beam is joined to the end of the main body, and the other end is embedded in the core of the permanent beam extension, characterized in that it comprises a permanent beam extension part is joined to the core during reverse construction.
Temporary pillars erected adjacent to the core to be installed later; and temporary beams installed on the temporary pillars; A permanent beam body part installed between the temporary beams toward the core part and fixed to the core part, extending from the permanent column in the direction of the core part, and coupled to the beam joint part on both sides, and one end of the permanent beam body a permanent beam joined to the end of the part and including a permanent beam extension part at the other end of which is embedded and fixed in the interior of the core part; In the permanent beam joint structure joined to the core part during reverse construction comprising a; a beam joint part connecting the temporary beam and the permanent beam to each other by joining the temporary beam and the permanent beam to each other,
installing the temporary pillar;
installing temporary beams on the temporary pillars;
a permanent beam installation step of locating the permanent beam body across the temporary beam and connecting the permanent beam body and the temporary beam to each other through the beam joint;
and a core part installation step of installing one end of the extension part of the permanent beam in the main body of the permanent beam and fixing the other end of the extension part of the permanent beam to the core part to integrate the permanent beam and the core part. A permanent beam installation method using a permanent beam joint structure that is joined to the core during reverse rudder construction.
6. The method of claim 5,
The permanent beam installation stage is
bonding the connecting members to both sides of the permanent beam body, respectively;
Removably coupling the connecting member facing each other and the end side of the temporary beam to each other through a first fastening means;
Reverse hitting construction, characterized in that it comprises the step of removably coupling the upper surface of the connecting member and the upper surface of the temporary beam and the lower surface of the connecting member and the lower surface of the temporary beam to each other through a second fastening means. A permanent beam installation method using a permanent beam joint structure that is joined to the sea core.

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