KR100809886B1 - Coping form system and method for constructing bridge pier using thereof - Google Patents

Abstract

The present invention is for forming a coping foam system with a forced formwork member forming the upper concrete structure of the pier structure, easy to install and dismantle the forced formwork, the installation work of the upper concrete structure of the bridge pier of the long bridge is safe and fast The present invention relates to a coping foam system made of a forced formwork member and a method of constructing a pier using the same.

Coping foam system according to an embodiment of the present invention, the pin support member arranged to penetrate the pillar on top of the pier pillar, brackets and height adjustment means mounted on both ends of each pin support member, the height adjustment means A lower base frame that can be fastened to interlock with each other, a bottom plate member disposed on the lower base frame, an inclined surface formwork member installed to form a lower inclined surface on the bottom plate member, and a skeleton formed in the inclined surface formwork member Reinforcement, and characterized in that it comprises a plurality of side forced formwork members forming the front, rear, left and right sides to form the outer wall of the upper concrete structure.

Pier, Force Formwork, H Beam Coping Foam System

Description

 Pier coping foam system and method for constructing bridge using the same {COPING FORM SYSTEM AND METHOD FOR CONSTRUCTING BRIDGE PIER USING THEREOF}

1 is a perspective view showing a general pier structure,

FIG. 2 is an installation perspective view of a conventional coping foam system for forming an upper portion of the pier structure shown in FIG. 1; FIG.

3 is a view showing the side of FIG.

4 shows the removal of the coping foam system after curing of concrete;

5 is a view showing an installation state of a support pin member for supporting a coping foam system according to an embodiment of the present invention to form a piercing upper concrete structure,

Figure 6 is a perspective view showing a lower base frame constituting the coping foam system according to an embodiment of the present invention

FIG. 7 is a view for explaining a process of installing the lower base frame shown in FIG. 6 in a pillar of a piers provided with the support pin member shown in FIG. 5;

FIG. 8 is a perspective view for explaining a process of installing a lower base frame shown in FIG. 6 in a pillar of a piers provided with a supporting pin member shown in FIG. 5;

9 is a side view of a state in which the lower base frame shown in FIG. 6 is installed on the support pin member shown in FIG. 5;

10 is a view showing a state in which the inclined surface formwork member for forming the inclined surface of the coping foam system for forming the upper concrete structure of the piers on the lower base frame,

11 is a cross-sectional view of the coping foam system of the upper concrete structure of the piers installed;

FIG. 12 is a side view of FIG. 11 illustrating a state in which a coping foam system is dismantled after forming an upper concrete structure of a pier; FIG.

13 is a flowchart illustrating a method of installing a coping foam system according to an embodiment of the present invention;

14 is a flowchart illustrating a method of installing a piers using a coping foam system according to an embodiment of the present invention.

<Description of Symbols for Major Parts of Drawings>

100 coping foam system 110 lower base frame

120, 130: H beam 140: transverse connecting member

The present invention relates to a coping form system (Coping Form System) consisting of a steel formwork member having a new assembly structure and a method for constructing a piers using the same. More specifically, to form a coping foam system with a forced form member forming the upper concrete structure of the pier structure, it is easy to install and dismantle the forced form member is safe to install the concrete structure of the pier upper concrete structure of the long bridge bridge It relates to a coping foam system consisting of a forced formwork member that can be made quickly and quickly and a method for constructing a pier using the same.

As shown in FIG. 1, in general, the upper concrete structure 9 of the bridge during the construction of an elevated road or a long bridge forms a foundation base 1 of a bridge on the ground, and a pillar 2 on the foundation base 1. After the construction of the pillars, the T-shaped upper structure of the main column (또는) or the pi (π) -shaped upper reinforced concrete structure (9) is formed.

In order to form the upper concrete structure 9, a coping foam system (hereinafter referred to simply as a coping foam system) composed of an assembly of steel formwork members is manufactured in advance under the piers, and thus the pillars of the piers 2 It is installed at the top of the. Here, the steel formwork member means that the member for forming the form is made of steel or steel such as metal, and the plurality of steel formwork members are made of various types of panels such as squares. Thus, the plurality of forced formwork members can be assembled to form lower, inclined surfaces, front, rear, left and right sides.
Then, after the reinforcement (8) work in the coping foam system, it is constructed using the site concrete casting method to complete the upper reinforced concrete structure (9) through the concrete pouring and curing process.

In order to form the upper concrete structure 9 of the conventional piers as shown in Figs. 2 to 4, first, after the concrete base is placed and cured, the upper concrete The coping foam system is prefabricated in a large vacant lot in the form of upper concrete using steel formwork to form the structure 9. At this time, temporary construction is performed at the same time to install a handrail, a support, a fall prevention net, a work scaffold, a fence, and the like for aerial work.

The coping product system manufactured by the forced form member according to the shape of the pier upper concrete structure 9 is fixed to the upper end of the pillar 2 of the pier using a crane (not shown) such as a crane.

Then, the work of installing the reinforcing bars according to the shape of the upper concrete structure is performed so that the reinforcing bars can be integrally connected from the column 2 in the fixedly installed coping foam system.

After the installation work of the reinforcing bars 8 to form the upper concrete structure 9 of the piers, the concrete must be poured into the coping foam system to cure, and then the coping foam system must be dismantled. Here, as a method of disassembling the coping foam system, as shown in Figure 4, the coping foam by the crane by loosening a fastening mechanism such as a plurality of bolt nuts are fastened to the middle portion of the coping foam system consisting of the assembly of the forced form member The system is separated from left to right and removed sequentially.

On the other hand, the assembly of the respective steel formwork members constituting the coping foam system is separated from the front, rear, left and right sides, inclined portion, and the bottom portion, and the method of separating the bottom member, respectively, is conventionally used.

In the conventional coping foam system installation and dismantling method as described above, the coping foam system according to the shape of the upper concrete structure (9) in the floor with a large space in advance to put on the pier where the pillar of the piers, There is no choice but to work within the reinforcement, but the reinforcing work in the space defined by the coping foam system is a very difficult and time-consuming since it is a work performed in a narrow space.

In addition, the installation of the coping foam system assembled in a predetermined shape at the bottom by the crane to the upper end of the pillar (2) of the piers is required to use a number of cranes, which is one of the difficult tasks.

On the other hand, after curing the upper concrete structure, even the process of removing the coping foam system is very difficult to dismantle all the fastening mechanisms formed with a complicated structure, as well as the lower part of the coping foam system and the part which is out of reach of humans. It is very difficult to dismantle the fastening mechanism.

The present invention has been made to solve the problems of the prior art, an object of the present invention is a coping foam system which is a forced form member for forming the upper concrete structure of the pier as easy to install and dismantle the upper concrete structure of the pier It is to provide a coping foam system that can be easily formed.

Another object of the present invention is to facilitate the installation and dismantling of the coping foam system by improving the structure of the bottom floor structure among the components constituting the coping foam system, which is a forced form member for forming the angular upper concrete structure. It is for.

In order to achieve the object of the present invention, the coping foam system for forming the upper concrete structure of the pier according to an embodiment of the present invention,

Pin support members arranged to pierce the column at the top of the pier column to intersect with a "+",

A bracket mounted on both ends of each pin support member, and height adjustment means fixedly installed on the bracket,

A lower base frame which can be fastened so that a pair of H beams having transverse connecting members alternately installed on the height adjusting means engage with each other;

A bottom plate member disposed on the lower base frame,

Sloped forced formwork member installed to form a lower inclined surface according to the shape of the upper concrete structure of the pier on the bottom plate member,

Reinforcing bars forming a skeleton of the upper concrete structure in the inclined surface formwork member,

To form the outer wall of the upper concrete structure is characterized in that it comprises a plurality of side forced formwork members formed in contact with the inclined surface formwork form and the bottom plate member to form the front, rear, left and right sides.

Coping foam system according to an embodiment of the present invention,

The H beam constituting the lower base frame is joined to a step portion formed at the other end of the lateral connecting member and a joint for connecting the upper wing and the lower wing to join one end surface of the lateral connecting member. The jaws are alternately formed,

Since the transverse connecting member is a rectangular steel member having a predetermined width, and a nut part capable of joining a plurality of bolts is formed at one end face, it is joined to the joint formed at the H beam, and the jaw part formed at the H beam is connected to the other end face. It is preferable that the structure is combined.

Coping foam system according to an embodiment of the present invention,

The lower base frame has a pair of H beams and a joint portion and a fastening portion are alternately formed, and one end surface of the transverse connecting member is joined to each of the joint portions using bolts, and is fastened to each other with a pillar therebetween. It is possible to be fixed to the height adjustment unit fixed to the pin support member penetrating the pillar is preferably fixed by inserting the pin into the fastening portion and the jaw.

Construction method for installing the coping foam system for forming the upper concrete structure of the piers in another embodiment of the present invention,

Installing a pin support member arranged on the top of the pier column to intersect with the "+" through the column,

Fixing the brackets mounted on both ends of the pin support members and the height adjusting means fixedly installed on the brackets,

Fixing a lower base frame to the height adjustment means to which the pair of H beams on which the lateral connecting members are alternately installed on the height adjustment means can be fastened to engage each other;

Placing a bottom plate member disposed on the lower base frame,

Installing an inclined surface forced form member installed to form a lower inclined surface according to the shape of the upper concrete structure of the pier on the bottom plate member;

Installing reinforcing bars forming the skeleton of the upper concrete structure in the inclined surface formwork member;

And forming a plurality of side forced formwork members formed in contact with the inclined surface formwork formwork and the bottom plate member to form an outer wall of the upper concrete structure to form front, rear, left, and right sides.

Method for constructing a piers according to another embodiment of the present invention,

Installing the lower base of the piers and the pillars using a forced formwork member,

Installing a pin support member arranged to intersect “+” through the column on top of the column for the construction of the upper structure of the piers,

Fixing the brackets mounted on both ends of the pin support members and the height adjusting means fixedly installed on the brackets,

Fixing a lower base frame to the height adjustment means to which the pair of H beams on which the lateral connecting members are alternately installed on the height adjustment means can be fastened to engage each other;

Placing a bottom plate member disposed on the lower base frame,

Installing an inclined surface forced form member installed to form a lower inclined surface according to the shape of the upper concrete structure of the pier on the bottom plate member;

Installing reinforcing bars forming the skeleton of the upper concrete structure in the inclined surface formwork member;

Installing a plurality of side forced formwork members formed in contact with the sloped formwork formwork member and the bottom plate member to form an outer wall of the upper concrete structure to form front, rear, left, and right sides;

Pouring and curing concrete in the coping foam system;

Releasing the fastening mechanism of the dismantling line formed at the center of the coping foam system, and removing the pin inserted into the fastening portion of the lower base frame; and

And sequentially removing the front and rear portions of the coping foam system.

(Example)

Hereinafter, a coping foam system according to a preferred embodiment of the present invention will be described in detail with reference to FIGS. 5 and 12.

5 is a view showing the installation state of the support pin member 11 for supporting the coping foam system 100 according to an embodiment of the present invention to form the upper concrete structure (9) of the piers, Figure 6 FIG. 7 is a perspective view illustrating a lower base frame 110 constituting a coping foam system according to an exemplary embodiment of the present invention, and FIG. 7 is a pillar 2 of a pier in which a supporting pin member 11 shown in FIG. 5 is installed. FIG. 8 is a view for explaining a process of installing the lower base frame 110, and FIG. 8 illustrates a process of installing the lower base frame shown in FIG. 9 is a side view of a state in which the lower base frame shown in FIG. 6 is installed on the support pin member shown in FIG. 5, and FIG. 10 is a view for forming an upper concrete structure of a pier on the lower base frame. FIG. 11 is a view illustrating a state in which a formwork base member is installed, and FIG. 11 is a cross-sectional view of a coping foam system installed in an upper concrete structure of a pier, and FIG. 12 is a side view of FIG. 11 after forming an upper concrete structure of a pier, The figure which shows the state which disassembles a coping foam system.

Coping form system (Coping Form System: 100) made of a steel formwork according to an embodiment of the present invention, as shown in Figures 2 to 4, a plurality of steel formwork members to form the upper concrete structure 9 of the piers This is an assembly formed by combining a fastening mechanism such as a bolt nut to a predetermined shape, and refers to a system for placing an upper concrete structure of a pier in the coping foam system 100.

The coping foam system 100 is for forming the upper concrete structure 9 of the piers, as already described in the prior art, made of a plurality of forced formwork members. In other words, the coping foam system 100 is composed of a lower base frame 110, a plurality of side forced formwork members, a lower or inclined surface formwork form member, the plurality of side forced formwork member is a bolt nut of a certain size It is made by fastening fasteners such as

Coping foam system structure 100 according to an embodiment of the present invention facilitates the formation of the upper concrete structure (9) of the piers, and after disassembly of the coping foam system structure (100) after forming the upper concrete structure (9) It is to simplify.

It is made of a structure for facilitating the installation and disassembly of the coping foam system 100 according to an embodiment of the present invention.

An installation process of the coping foam system 100 according to an embodiment of the present invention will be described in detail below with reference to FIGS. 5 to 12.

The pier upper concrete structure 9 is composed of one main T-shaped superstructure or two main pi-shaped upper reinforced concrete structures, as already described above in the prior art. Piers support tops of bridges or overpasses (not shown).

The conventional coping foam system 10 shown in FIGS. 1 and 3 can be used to form one main T-shaped superstructure, but the two main pi-shaped upper reinforced concrete structures may be used. There is a disadvantage in forming very difficult.

Therefore, the coping foam system according to an embodiment of the present invention can be sequentially installed in accordance with the reinforcing work process for forming the upper concrete structure (9), and also has the advantage that can be easily dismantled sequentially when dismantling. .

In FIG. 5, in order to form the upper concrete structure 9 of the piers, a walkway band 2a is provided on the upper outer surface of the pillar 2 to provide a workspace for workers to work. This auxiliary work bench 2a is installed in the lower part of the pin support member 11 which is the height which a worker can install the bracket 13 with. The two pin supporting members 11 are installed to penetrate the inside of the column 2 so as to intersect in a "+" shape.

Brackets 13 are provided at both ends of the pin support member 11 to be firmly fixed. On the bracket 13, a height adjusting means 15 capable of adjusting the height, such as a jockey, is fixed to the bracket 13.

A pair of lower portions of the coping foam system 100 with the pillars 2 interposed therebetween on the height adjusting means 15 provided at both ends of the pin support members 11 intersected with “+” and installed at the upper ends of the pillars of the piers. The base frame 110 is fixedly coupled to each other.

The lower base frame 110 is made of a pair of F-shaped steel structure, as shown in detail in Figure 6, are combined with each other to form a "目" shape. By installing the bottom plate member 5 on the lower base frame 110, the lower base frame 110 of the coping foam system 100 is formed, on which the work space for forming the upper concrete structure 9 of the piers is formed. And a reinforcing operation is made over this space, and a plurality of side forced formwork members are connected to form a side to form the coping foam system 100.

Hereinafter, the structure of the lower base frame 100 will be described in detail with reference to FIG. 6.

In FIG. 6, the lower base frame 110 is largely comprised of H beams 120 and 130 and a lateral connecting member 140. The H beams 120 and 130 are formed in the same shape as the general H beams, but may be formed in a “c” shape if necessary. Each of the H beams 120 and 130 is referred to as the upper wing 161 in the state where the H beam is laid, and the lower wide surface is referred to as the lower wing 165. The upper wing 161 and the lower wing 165 of the H beams that are lying are integrally connected by the upright portion 163 of the center. As shown in detail in FIGS. 6 and 8, the H beams 120 and 130 forming the lower base frame connect the ends of the upper wing 161 and the lower wing 165, respectively. A plurality of joining portions 121 and 131 and fastening portions 123 and 133 for joining are alternately formed. The joining portions 121 and 131 are portions for joining and fixing one end surface of the lateral connecting member 140 and include a plurality of holes for joining using a fastening mechanism such as a bolt in the drawing. However, without forming a hole, but can also be formed by joining, such as by welding, in consideration of transportation, H beams (120, 130) and the horizontal connecting member 140 is used to separate the bolts at right angles. It is preferable to tighten.

In addition, the fastening portions 123 and 133 are formed with a jaw portion 127 which can be engaged with the stepped portion 126 formed at the other end of the transverse connecting member 140, and in the center of the jaw portion 127. A hole is formed.

Horizontal connecting member 140 is made of a substantially rectangular force, one end surface is formed with a plurality of nuts horizontally so as to be fixedly bonded to the joints 121, 131 of the H beams (120, 130), On the other end, the lower portion is cut and a stepped portion 126 is formed, and the stepped portion 126 is formed with a hole into which the pin 125 can be inserted vertically, so that the fastening portion 123 of the H beam is formed. 133 has a structure that can be fastened by a fastening mechanism 125 such as a jaw portion and a pin formed.

Accordingly, one end surface of the lateral connecting member 140 is fixed at right angles to the junction portion 121 of the H beam 120, and the lateral connecting member 140 is also connected to the other junction portion 121 formed after the fastening portion 123. One end of is fixed and consists of an approximately F shape.

In addition, one end surface of the lateral connecting member 140 is also fixed to the junction portion 131 of the H beam 130 paired with the H beam 120 at right angles. Accordingly, the H beam 120 and the H beam 130 are disposed to face each other and, when fastened to each other, are combined as shown in FIG. 8 to form a “目” shape structure.

One end of the lateral connecting member 140 is fixedly bonded to the joints 121 and 131 of the H beams 120 and 130 by a fastening mechanism such as a bolt, which may be joined by welding or the like as necessary. Considering the usability in transportation and other sites, it is preferable to join with a bolt or the like and detachably join as shown in FIG.

As described above, the lower base frame 110 is installed and fixed to a bracket installed at the upper end of the pillar 2 shown in FIG. 5. Accordingly, the lower base frame 110 is installed on the bracket while the pillar is inserted in the middle to be fixed to form the lower base structure 110 of the stable coping foam system 100.

In other words, as shown in FIG. 7, the lower base structure 110 first installs the H beam 120 to which the two lateral connecting members 140 on the left side are joined to the bracket, and then faces H opposite thereto. By placing the beam 130 on the H beam 120, and inserting the fastening mechanism 125, it can be simply fixed installation. In addition, when dismantling the lower base structure 110, the F-shaped structures may be separated from each other simply by removing the fastening mechanism 125 such as a pin.

Here, in view of the installation and disassembly of the lower base frame 110, compared with the conventional technology, in the prior art, installation and disassembly was possible by tightening or removing at least 30 to 100 bolt nuts. The lower base frame 110 of the coping foam system 100 according to the embodiment of the present invention may be simply separated by removing approximately 4 to 10 pins. Therefore, the installation and dismantling work of the coping foam system 100 is much simpler, so there is an advantage that the working time can be shortened. On the other hand, the lower base frame 110 has been described to form a "目" structure by fastening a pair of F-shaped structure for the sake of simplicity, this is just to explain the description, H beams 120, 130 By joining more transverse connecting members 140 to the fastening to each other can be made of a ladder-like structure.

As shown in FIG. 8, various types of bottom plate members 5 are provided on the lower base frame 110 to facilitate work. As can be seen in the side view of FIG. 9, when the lower base frame 110 is installed at the upper end of the pillar 2 of the pier, it can be seen that sufficient space for forming the upper concrete structure 9 of the pier is secured. In this space, safety facilities such as safety railings for safety may be installed.

Reinforcing work and installation of a forced formwork member for forming a concrete structure of a pier on the lower base frame 110 are performed by placing a rebar, forced formwork, etc. on the lower base frame 110 by a crane, and using a crane or the like. It is understood that there is no difference from the work performed in a wide place as in the conventional work because the work is performed. The process of forming the upper concrete structure 9 of the piers by the coping foam system 100 will be briefly described below with reference to FIGS. 10 to 12.

In FIG. 10, in order to form a lower inclined surface of the upper concrete structure 9 of the piers, the inclined surface formwork members 150 are inclined on the lower base frame 110. At this time, the copper bar 151 for maintaining the inclined surface formwork member 150 in accordance with the inclination is provided. When the inclined surface formwork member 150 is installed, the reinforcing bar forming work for forming the upper concrete structure 9 of the pier is performed as shown in FIG.

Here, comparing the coping foam system 100 according to the embodiment of the present invention with the coping foam system of the prior art shown in Figures 1 to 4, in the prior art to form the upper concrete structure 9 of the piers In order to assemble the coping foam system consisting of a forced formwork member from the bottom to place the assembled coping foam system 100 at the top of the column of piers at once. At this time, in order to put the assembled coping foam system 100 at the same time, not only a plurality of cranes must be used at the same time, but also the assembled coping foam system must be accurately installed on a bracket installed on the column of the pier. Reinforcing bars inside a foam system is a difficult task because of limited space.

On the other hand, the coping foam system 100 made of a forced form member to form the upper concrete structure 9 of the piers according to the embodiment of the present invention is easy to install and dismantle as described above on the column top of the piers The frame 110 is installed to secure sufficient space, and after the reinforcing work is performed in the same order as the general formwork installation work, a plurality of side forced formwork members are connected and assembled to form a coping foam system, thereby making the work simple and easy. The advantage is that you can.

In other words, as shown in FIG. 11, in order to form the upper concrete structure 9 of the pier, the lower base frame 110, which is easily assembled and dismantled, is first installed on the upper part of the pillar 20 of the pier. To form a stable working space, and inclinedly install the inclined surface formwork member 150 in accordance with the lower inclined surface of the upper concrete structure 9 of the piers in the working space, and a plurality of clubs 151 to maintain the inclined surface Is installed.

Next, as shown in FIG. 12, the reinforcing bar 6 is performed on the inclined surface formwork member 150 for forming the lower inclined surface, and the side forced formwork member 160 for forming the front, rear, left, and right sides is assembled and installed. After the concrete is poured by the curing can form the upper concrete structure (9) of the piers.

The coping foam system 100 according to the embodiment of the present invention for forming the upper concrete structure 9 of the piers is classified, the lower base frame 110, the inclined surface formwork member 150 and a plurality of side forced formwork Member 160.

The inclined surface formwork member 150 and the plurality of side forced formwork members 160 are manufactured in a predetermined size on the lower base frame 110 described above, and the inclined surface formwork formwork member 150 and the plurality of side portions are manufactured. By connecting and fastening the forced formwork member 160 by connecting means such as bolts / nuts, it is possible to simply form a coping foam system in the same shape as the shape of the upper structure of the piers. Since the connection fastening using the inclined plane formwork member 150 and the plurality of side forced formwork members 160 is already known, a detailed description thereof will be omitted. However, as shown in FIG. 12, the steel formwork member constituting the coping foam system 100 is assembled and fastened so that a fastening line is formed at the center thereof. The fastening line formed at the center is intended to facilitate dismantling the coping foam system 100 after forming the upper concrete structure of the pier.

Therefore, the appearance of the coping foam system 100 completed according to an embodiment of the present invention has a shape as shown in FIG. It can be seen that the appearance that the coping foam system 100 is completed has the same structure as that of the conventional FIG. 1. By pouring concrete into the coping foam system 100 and curing, the upper concrete structure of the piers is completed by separating and dismantling the coping foam system 100.

After curing of the concrete structure 9, the coping foam system 100 can be dismantled as shown in FIG. 12. That is, after releasing the fastening member on the fastening line formed at the center of the left and right sides, the pin member 125 which fastens the lower base frame 110 is removed to separate the entire coping foam system 100 from the left and right to dismantle. can do.

The difference between the dismantling method of the coping foam system in the prior art shown in FIG. 4 and the dismantling method of the coping foam system according to the embodiment of the present invention will be briefly described.

In the coping foam system of the prior art, a fastening line for dismantling is formed in the center of the pier upper concrete structure, as shown in FIG. By releasing the fastening mechanism fastened along the fastening line formed in the center, it can be seen that the conventional coping foam system is separated from side to side. Here, the disassembly of the coping foam system in the prior art can be constructed only in a T-pier with one pillar, and the coping foam system can not be used in two or more pi (π) pier. It can be seen that it takes a lot of time to dismantle the fastening mechanism formed on the lower base frame.

On the other hand, in the coping foam system according to the embodiment of the present invention, since the fastening line for dismantling is formed at the center of the left and right sides, and the coping foam system is separated into the front part and the rear part, one main T-shaped pier having one column Or it can be seen that it is also applicable to the piers of two or more pi (π) shape.

In addition, the coping foam system according to an embodiment of the present invention is that the lower base frame constituting the coping foam system can be easily removed by removing 4-10 pins, so that it does not take much time to dismantle the fastening mechanism. Can be.

On the other hand, the vertical balance of the formwork upon separation of the coping foam system shown in FIG. 12 indicates that using the "balance lug" invented by the applicant, the dismantled coping foam system can be dismantled in balance. Able to know.

(Example 2-pier construction method)

Hereinafter, a method of installing and releasing a coping foam system 100 according to an exemplary embodiment of the present invention and further, a method of installing a bridge piers will be described in detail with reference to FIGS. 13 and 14. FIG. 13 is a flowchart illustrating a method of constructing an upper concrete structure of a bridge using a coping foam system 100 for constructing an upper concrete structure of a bridge, and FIG. 14 is a flowchart illustrating a method of constructing a bridge of a bridge.

The construction method for installing the coping foam system for forming the upper concrete structure of the pier is performed in the following order.

As shown in Fig. 5, a pin supporting member arranged to intersect “+” through the column at the upper part of the piers pillar under construction (step S110).

Then, the brackets mounted on both ends of the pin support members and the height adjusting means fixedly installed on the brackets are fixedly installed (step S 120).

A pair of lower base frames 110 are fabricated by bonding a plurality of lateral connecting members 140 to the joints of the H beams 120 as shown in FIGS. 5 and 8, and the lower base frames 110. ) Is fixed on the height adjusting means. At this time, the pair of lower base frames 110 is simply fixed by inserting a pin into the fastening portion with the pier between (step S 130).

As shown in FIG. 9, the bottom plate member 5 disposed on the lower base frame 110 is placed to form a space for manufacturing the upper concrete structure (step S140).

As shown in Fig. 10, on the bottom plate member, an inclined surface formwork member is installed to form a lower inclined surface according to the shape of the upper concrete structure of the piers (step S150).

As shown in FIG. 11, reinforcing bars forming the skeleton of the upper concrete structure are installed in the inclined surface formwork (step S160).

As shown in Figure 11, to form the outer wall of the upper concrete structure coping foam system by installing a plurality of side forced formwork members formed in contact with the inclined surface formwork form and the bottom plate member forming a front, rear, left and right sides. It installs (step S170). The concrete is then poured and cured into the coping foam system, and the coping foam system is dismantled to construct the upper concrete structure of the piers.

14 is a flowchart showing a method of constructing a bridge pier.

In the method of constructing a bridge pier according to an embodiment of the present invention, first, a lower base of the bridge is installed using a forced form member, and a pillar is installed (step S210).

Then, as shown in Fig. 5, a pin supporting member arranged to intersect “+” through the column at the top of the pier pillar under construction (step S220).

Then, the brackets mounted on both ends of the pin support members and the height adjusting means fixedly installed on the brackets are fixedly installed (step S 230).

6 to 8, a plurality of lower base frames 110 are manufactured by joining a plurality of lateral connecting members 140 to the joints of the H beams 120 as shown in FIGS. It is fixed to the height adjusting means. At this time, the pair of lower base frames 110 are simply fixed by inserting a pin into the fastening portion with the pier interposed therebetween (step S 240).

As shown in FIG. 9, the bottom plate member 5 disposed on the lower base frame 110 is placed to form a space for manufacturing the upper concrete structure (step S 250).

As shown in FIG. 10, on the bottom plate member, an inclined surface forced form member provided to form a lower inclined surface according to the shape of the upper concrete structure of the piers is installed (step S260).

As shown in FIG. 11, reinforcing bars forming a skeleton of the upper concrete structure are installed in the inclined surface formwork (step S 270).

As shown in Figure 11, to form the outer wall of the upper concrete structure coping foam system by installing a plurality of side forced formwork members formed in contact with the inclined surface formwork form and the bottom plate member forming a front, rear, left and right sides. Install (step S280).

Thereafter, the concrete is poured and cured in the coping foam system (step S290).

As shown in FIG. 12, the coping foam system releases the fastening mechanism of the dismantling line formed at the center of both sides, and removes the pin inserted in the fastening portion of the lower base frame (step S 300).

The coping foam system is separated into the front part and the rear part by releasing the fastening mechanism in step S300, and the pier is completed by sequentially removing the front part and the rear part (step S310).

According to the embodiment of the present invention, it is possible to provide a coping foam system that can be easily assembled and dismantled to facilitate the formation of the upper concrete structure of the piers.

According to an embodiment of the present invention, the coping foam system can be easily installed and dismantled by improving the structure of the lower floor structure among the components constituting the coping foam system, which is a forced formwork for forming the upper concrete structure of the piers. There is an advantage.

It is to be understood that the present invention is not limited to the above-described preferred embodiments but can be carried out in various ways without departing from the spirit and scope of the present invention. If you can easily understand. If the implementation by such improvement, change, substitution or addition falls within the scope of the appended claims below, the technical spirit is also regarded as belonging to the present invention.

Claims (5)

In a coping foam system for forming a pier upper concrete structure, Pin support members arranged to pierce the column at the top of the pier column to intersect with a "+", Brackets mounted on both ends of the pin support member and the height adjusting means is fixedly installed on the bracket, A lower base frame which can be fastened so that a pair of H beams having transverse connecting members alternately installed on the height adjusting means engage with each other; A bottom plate member disposed on the lower base frame, Sloped forced formwork member installed to form a lower inclined surface according to the shape of the upper concrete structure of the pier on the bottom plate member, Reinforcing bars forming a skeleton of the upper concrete structure in the inclined surface formwork member; A plurality of side forced formwork members formed in contact with the inclined surface formwork form and the bottom plate member to form the outer wall of the upper concrete structure to form the front, rear, left and right sides Coping foam system comprising a. According to claim 1, H beam constituting the lower base frame is connected to the other end of the lateral connecting member and the connecting portion for connecting one end surface of the lateral connecting member by connecting the upper wing and the lower wing The jaws that can be fastened to the formed step portion are alternately formed, The transverse connecting member is a rectangular forcing member having a predetermined width, and a nut part capable of joining a plurality of bolts is formed at one end face, and thus is joined to the joint formed at the H beam, and the jaw part formed at the H beam at the other end face. Coping foam system, characterized in that the structure consists of a combined. According to claim 2, wherein the lower base frame is a pair of H beams and the junction portion and the fastening portion is formed alternately, one end surface of the transverse connecting member is joined to each of the junction portion using a bolt, Coupling foam system, characterized in that the fastening to each other with a gap between, and fixedly installed on the height adjustment means fixed to the pin support member penetrating the pillar by inserting the pin into the fastening portion and the jaw. In the construction method for installing the coping foam system for forming the upper concrete structure of the pier, Installing a pin support member arranged on the top of the pier column to intersect with the "+" through the column, Fixing the brackets mounted on both ends of the pin support members and the height adjusting means fixedly installed on the brackets, Fixing a lower base frame to the height adjustment means to which the pair of H beams on which the lateral connecting members are alternately installed on the height adjustment means can be fastened to engage each other; Placing a bottom plate member disposed on the lower base frame, Installing an inclined surface forced form member installed to form a lower inclined surface according to the shape of the upper concrete structure of the pier on the bottom plate member; Installing reinforcing bars forming the skeleton of the upper concrete structure in the inclined surface formwork member; and Installing a plurality of side forced formwork members formed in contact with the inclined surface formwork form and the bottom plate member to form the outer wall of the upper concrete structure to form the front, rear, left and right sides Construction method for installing a coping foam system comprising a. In the method of constructing the bridge piers, Installing the lower base of the piers and the pillars using a forced formwork member, Installing a pin support member arranged to intersect “+” through the column on top of the column for the construction of the upper structure of the piers, Fixing the brackets mounted on both ends of the pin support members and the height adjusting means fixedly installed on the brackets, Fixing a lower base frame to the height adjustment means to which the pair of H beams on which the lateral connecting members are alternately installed on the height adjustment means can be fastened to engage each other; Placing a bottom plate member disposed on the lower base frame, Installing an inclined surface forced form member installed to form a lower inclined surface according to the shape of the upper concrete structure of the pier on the bottom plate member; Installing reinforcing bars forming the skeleton of the upper concrete structure in the inclined surface formwork member; Installing a plurality of side forced formwork members formed in contact with the sloped formwork formwork member and the bottom surface member to form an outer wall of the upper concrete structure and forming front, rear, left, and right sides; Pouring and curing concrete in the coping foam system, Releasing the fastening mechanism of the dismantling line formed at the center of the coping foam system, and removing the pin inserted into the fastening portion of the lower base frame; and Sequentially removing the front and rear portions of the coping foam system Construction method for installing a bridge pier, characterized in that it comprises a.

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