KR102155646B1 - FRP Reinforcement PC Deck, Formwork for it and Manufacturing Method of FRP Reinforcement PC Deck using same - Google Patents

Abstract

The present invention relates to an FRP reinforcement PC deck, a mold therefor, and a method for manufacturing an FRP reinforcement PC deck using the same. To this end, the PC deck has a predetermined thickness and allows a shear connector to be provided on a rectangular precast concrete main body having a flat lower portion to be partially exposed to an upper portion, wherein the main body allows a plurality of longitudinal FRP reinforcing bars and transverse FRP reinforcing bars to be arranged. Therefore, the PC deck can secure greater tensile strength and expect corrosion resistance since the plurality of longitudinal FRP reinforcing bars and transverse FRP reinforcing bars are arranged in the main body.

Description

FRP Reinforcement PC Deck, Formwork for it and Manufacturing Method of FRP Reinforcement PC Deck using same}

The present invention relates to a FRP reinforced PC deck, a form therefor, and a method of manufacturing an FRP reinforced PC deck using the same, and more particularly, to a precast concrete body of a rectangular shape having a predetermined thickness and a flat bottom, a shear connector is partially upper It is provided to be exposed to, the main body relates to a FRP reinforced PC deck in which a plurality of longitudinal FRP reinforcement bars and a width direction FRP reinforcement are reinforced, a formwork for the same, and a method of manufacturing an FRP reinforced PC deck using the same.

In general, a bridge is constructed by arranging a girder along the lengthwise direction on the abutment and the upper part of the pier, and forming a floor plate on the upper part of the girder. In forming such a bridge deck, conventionally, a formwork for forming a crossbeam and a deck is installed in advance, reinforcing bars are laid inside the formwork, and then concrete is poured.

However, the conventional formwork method requires the work of skilled workers in the process of manufacturing the formwork, and the process of dismantling the formwork inevitably accompanies the process of dismantling the formwork when the pouring of concrete is completed after the formwork is manufactured. There was a problem that the work efficiency was deteriorated due to excessive cost and cost. In addition, there was a high risk of a disaster occurring due to the material falling to the lower part or the worker's fall during the construction process as well as carrying in the material or performing the transportation work.

In order to solve the problem of the above-described formwork method, in recent years, a precast concrete deck (PC deck) is manufactured in advance so that the dismantling process of the formwork can be omitted, and after transporting it to the site, It was mounted on the top. Subsequently, the construction method of completing the bridge deck by inducing the synthesis of the PC deck and the poured concrete by placing additional reinforcing bars on the top of the mounted PC deck and pouring on-site concrete is being actively carried out.

As a prior document related to this, "Bridge Slab Construction Method and Lattice Bar Deck Type PC Plate" (registered on October 10, 2006, hereinafter referred to as'Prior Technical Document 1') of Korean Patent No. 0635137 has been proposed. There is a bar.

However, the construction method of Prior Art Document 1 causes reflection cracks in the upper cast concrete due to the gap occurring in the adjacent area between the decks, as shown in Fig. 1(a), thereby reducing the durability of the bridge slab. A problem occurred. Accordingly, in manufacturing the end of the PC deck in the width direction, as shown in Fig. 1(b), the inclined portion is formed so that the height is low, so that the cross-sectional area of the concrete placed at the end of the PC deck is relatively high. By doing so, it was manufactured to increase the effective cross-sectional area of the bridge deck.

However, as the height of the slope formed at the end of the PC deck in the width direction is relatively low, the portion of the cross-sectional area of the poured concrete that is not reinforced increases relatively, and the cracks once caused by this increase quickly to the top poured concrete. There was an ongoing problem. In addition, as the adjacent PC decks are interconnected entirely depending on the widthwise reinforcing bars laid on the top, there is a problem that the individual PC decks behave independently due to the construction process or live load after construction, thereby impeding structural stability.

In order to solve this problem, a number of technologies have been proposed in which the reinforcing bars are exposed at the end of the PC deck in the width direction so that mutual interlocking with the exposed reinforcing bars of the adjacent PC deck is made, and at the same time, the poured concrete at the end in the width direction is tensilely reinforced with rebar. There is a bar. As a prior document related to this, there is a "concrete slab casting deck" of Korean Patent No. 1721603 (registered on March 24, 2017, hereinafter referred to as'prior technical document 2').

However, in the process of manufacturing in the factory, Prior Art Document 2 has ineconomy and inefficiency to process the shape of the formwork so that the inclined part is formed at the end in the width direction. In particular, in the process of exposing the reinforcing bar to the end in the width direction, As interference occurred, the reinforcing bar was bent upward, and after curing, the PC deck was transported and brought in to the construction site, and the reinforcing bar at the end was again bent to its original position.

Furthermore, the lengthwise reinforcing bars and the widthwise reinforcing bars disclosed in Prior Art Document 2 sometimes deviated from their correct position due to vibration or pouring load during the concrete pouring process, and in particular, as deflections occurred due to their own weight, effective covering was not secured. There was a case of failure.

However, the biggest limitation of the PC deck disclosed in the prior art documents was the limitation in which corrosion proceeds rapidly as reinforcement is used as a tension member, as shown in FIG. 2, which is directly connected to the shortening of the life of the structure, resulting in reduced durability. There was a problem. As shown in Fig. 2, once a crack is caused in the deck, the crack is transmitted to the reinforcing bar provided inside the deck, and the reinforcing bar exposed to the outside air by the crack is further promoted to oxidize, resulting in a rapid decrease in durability. Furthermore, since the reinforcing bar has a relatively large weight and is easily plastically deformed by an external force, there is an incidental limitation in that manufacturing inefficiency and workability are deteriorated.

The present invention was conceived to solve the above-described problems, and by using FRP reinforcement, as well as securing higher tensile strength, as well as corrosion resistance can be expected, it is possible to extend the overall life of the PC deck to secure durability. , Excellent fracture resistance can be expected, and the overall deck's LCC (Life Cycle Cost) can be reduced, workability and manufacturing efficiency are secured, and the FRP reinforced PC deck that allows reinforcing bars to be placed in place, and a form and It is an object to provide a method of manufacturing an FRP reinforced PC deck using this.

In order to solve the above technical problem, the FRP reinforced PC deck (D) of the present invention has a certain thickness (t), and the shear connector 20 is partially upper part of the precast concrete body 10 of a rectangular shape with a flat lower part. It is provided so as to be exposed, a plurality of longitudinal FRP reinforcing bars 30 and widthwise FRP reinforcing bars 40 are reinforced in the main body 10 of the PC deck (D), the amount of the FRP reinforcing bars 40 in the width direction The end portion is formed with an upward inclined portion 41 to be exposed upward, the upward inclined portion 41 is horizontally extended to the outside to form a reinforcing protrusion 42, and both ends and lengths of the body 10 in the width direction At both ends of the direction, side slopes 50 and end slopes 60 that gradually decrease in height toward the outside so as to increase the effective cross-sectional area of the site concrete TC to be poured on the top are respectively provided.

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On the other hand, in the manufacturing method (M) of the FRP reinforced PC deck (D) of the present invention, a pair of side plates 200 are provided at the ends in the width direction of the rectangular bottom plate 100, and a pair of side plates 200 are provided at the ends in the longitudinal direction. By using the PC deck formwork (A) provided with the end plate 300 of, the side plate 200 of the PC deck formwork (A) has a vertical portion 230 formed at a predetermined height, and the vertical portion ( The upper end of 230) is bent inwardly upward to form an inclined side portion 240, and the upper end of the inclined side portion 240 is bent upward to form a seating portion 250, and at a predetermined interval on the seating portion 250 Reinforcing bar mounting grooves 220 are formed, and reinforcing protrusions 42 horizontally extending outward are mounted in the widthwise FRP reinforcing bars 40 in the width direction in the reinforcing bar mounting grooves 220, respectively. Protrusion mounting step (S11); And a widthwise reinforcing bar height adjustment step (S12) of simultaneously adjusting the height of the plurality of reinforcing bar mounting grooves 220 by adjusting the height of the height adjustment bar 270 provided on the outside of the side plate 200 in the longitudinal direction. Reinforcing bars in the width direction including a step (S10); A longitudinal FRP reinforcing bar arranging step (S20) of arranging the longitudinal FRP reinforcing bars 30 at regular intervals on the top of the widthwise FRP reinforcing bars 40; Body forming step (S30) of pouring concrete to cure the PC deck formwork (A) so that the upper end of the upwardly inclined portion 41 of the widthwise FRP reinforcing bar 40 is exposed (S30); And a deck demoulding step (S40) of demoulding the PC deck (D) by opening the side plate 200.

And the longitudinal FRP reinforcing bar mounting step (S20), reinforcing protrusions 32 formed at both ends of the longitudinal FRP reinforcing bar 30 in the reinforcing bar mounting grooves 320 formed at regular intervals on the upper end of the end plate 300 Each can be mounted.

According to the FRP reinforced PC deck of the present invention by the above-described problem solving means, the formwork therefor, and the manufacturing method of the FRP reinforced PC deck using the same, a plurality of longitudinal FRP reinforcing bars and widthwise FRP reinforcing bars are arranged in the body, so In addition to securing tensile strength, corrosion resistance can be expected.

In addition, depending on the embodiment, the shear connector of the main body can also extend the lifespan by completely replacing the reinforcing bars in the deck by utilizing the FRP reinforced PC deck, and the initial cost can be increased, but the overall deck LCC (Life Cycle Cost) can be reduced.

Furthermore, it is possible to expect the fracture resistance of the deck, and since the weight of the reinforcing bar and the overall weight of the deck can be reduced, the workability of the workers can be improved as well as the efficiency of manufacturing can be expected.

In addition, an upward inclined portion and a reinforcing protrusion are formed so that both ends of the FRP reinforcing bar in the width direction are exposed to the top, so that the FRP reinforcing bar in the width direction can be exposed to the outside to secure sufficient tensile strength.

In addition, side slopes are formed at the ends in the width direction to increase the effective cross-sectional area of the field concrete to prevent reflection cracking, and the longitudinal FRP reinforcement bars can also be exposed to the outside without interference with the formwork. As it can be provided, an effective cross-sectional area can be secured, so reflective cracking and tensile strength can be secured.

On the other hand, according to the formwork for the FRP reinforcement deck, it is possible to secure the ease of demoulding despite the shape of the end of the PC deck by using the hinge portion formed at the bottom of the side plate.

In addition, even if a separate spacer is not provided based on the reinforcing bar mounting grooves formed at regular intervals on the side plate of the formwork, the widthwise FRP reinforcing bar can be provided at the correct position, and it is flowed by vibration or bent by its own weight during the concrete curing process. Can be prevented from occurring.

Furthermore, even if an upward slope and a reinforcing protrusion are formed so that both ends of the FRP reinforcing bar in the width direction are exposed to the top based on the reinforcing bar mounting groove, it is possible to increase productivity by preventing interference with the side plate of the formwork, and upward inward to the side plate of the formwork. By forming the inclined side that is bent in a direction, as well as securing ease of demoulding in relation to the hinge portion, it is possible to efficiently form an inclined surface at the end of the PC deck in the width direction that is completed after curing the concrete.

In addition, rebar mounting grooves are formed at regular intervals at the top of the end plates provided at both ends of the formwork in the longitudinal direction so that both ends of the longitudinal FRP reinforcement bars are respectively mounted, so that it is possible to reinforce in place even if a separate spacer is not provided. In particular, it is possible to more effectively prevent sagging based on the organic bonding relationship with the widthwise FRP reinforcement.

In addition, by forming an inclined side that is bent inward and upward on the end plate of the formwork and forming a hinge, it is possible to secure the ease of demoulding and to efficiently form an inclined surface at the longitudinal end of the PC deck completed after curing of concrete. . In addition, when the fixing tool is bound to both ends of the FRP reinforcing bar in the width direction, there is an advantage that it is possible to prevent sagging more effectively by being locked and fixed to the outside of the reinforcing bar mounting groove.

1 is a cross-sectional view showing an end portion in the width direction of a PC deck according to the prior art.
Figure 2 is an image showing the reinforcement corrosion process of the PC deck according to the prior art.
Figure 3a is a perspective view showing a PC deck according to an embodiment of the present invention.
Figure 3b is a perspective view showing a PC deck according to another embodiment of the present invention.
4 is a (a) width direction end and (b) length of the PC deck according to an embodiment of the present invention
A cross-sectional view showing a direction end.
Figure 5 is a perspective view showing a formwork for a PC deck according to an embodiment of the present invention.
6 is a cross-sectional view showing a method of manufacturing a PC deck according to an embodiment of the present invention.
7 is a cross-sectional view illustrating a method of manufacturing a PC deck according to another embodiment of the present invention in time series.
8 is a cross-sectional view illustrating a method of manufacturing a PC deck using a fixture according to an embodiment of the present invention in time series.
9 is a cross-sectional view showing a method of manufacturing a PC deck using a height adjustment bar according to an embodiment of the present invention.
10 is a block diagram illustrating a method of manufacturing a PC deck according to an embodiment of the present invention in time series.

Hereinafter, the FRP-reinforced PC deck (D) of the present invention, a formwork for the same (A), and a manufacturing method (M) of the FRP-reinforced PC deck using the same will be described in detail with reference to embodiments and drawings.

In the present invention, in defining the'length direction' and the'width direction', based on the shape of the PC deck D, the long axis direction is defined as the'length direction' and the short axis direction is defined as the'width direction'.

Figure 3a shows the overall shape of the PC deck (D) according to an embodiment of the present invention, the body 10 of a rectangular shape made of precast concrete is formed to have a predetermined thickness (t) as a whole, The lower part has a flat shape. The thickness t may be manufactured in a range of 50 to 90 mm, preferably 60 to 65 mm.

On the other hand, the precast concrete body 10 of the rectangular shape is provided so that the shear connector 20 is partially exposed. The shear connector 20 functions to secure flexural stiffness and tensile stiffness, as well as for synthesis with cast-in-place concrete, and may be manufactured in various shapes without being particularly limited in shape.

As an embodiment, as shown in FIG. 6, a pair of lower chords are arranged at the bottom centering on an upper chord, and a pair of corrugated lattice bars are provided to be connected thereto to be manufactured in a truss-type structure. Although not shown in, the upper and lower chords are arranged vertically and may be manufactured in a structure in which they are interconnected with a lattice bar. In addition, the shear connector 20 may be formed of a wavy reinforcing bar, or may be manufactured in a net shape in which vertical and horizontal reinforcing bars are mutually welded, and a plurality of studs are arranged along the length direction. It can also be made.

In addition, a plurality of longitudinal FRP reinforcing bars 30 and widthwise FRP reinforcing bars 40 are arranged in the main body 10 in the longitudinal direction and in the width direction, respectively. At this time, the PC deck (D) of the present invention has an upward inclined portion 41 formed so that both ends of each widthwise FRP reinforcing bar 40 are exposed upward, and the upward inclined portion 41 is horizontally bent outward As a result, the reinforcing protrusion 42 is formed.

FRP (Fiber Reinforced Plastic) reinforcement is composed of fiber filaments with a diameter of 5 to 30 μm and impregnating resin depending on the type of fiber, and as a fiber material, alkali resistant glass fiber (AR-glass) or carbon applicable to the alkaline environment of concrete. It is preferred that fiber (Carbon) is used. The resin serves as a coating agent for adhesion between fibrous filaments and adhesion to concrete, and it is preferable to use epoxy (EP) and three-enbutadiene (SB).

Meanwhile, the main characteristics according to the material of the FRP reinforcing bar are summarized in Table 1 below.

division AR-glass/SB AR-glass/EP Carbon/SB Carbon/EP The tensile strength usually Good Great optimal Concrete attachment usually optimal usually Great When pouring concrete
Intrinsic safety incongruity Great incongruity Great

Such, FRP reinforcement can fundamentally block corrosion of reinforced concrete structures, and can reduce the thickness of the covering, which is advantageous in reducing the cross section and weight reduction of the member. In particular, the weight is only 1/5 to 1/4 compared to the reinforced bar, so it is easy to handle, and there is also an advantage in manpower construction as well as transportation. In addition, it is possible to reduce the weight of the reinforcing bar and further reduce the overall weight of the deck, and it is expected to improve the fracture resistance of the deck.

Since a plurality of longitudinal FRP reinforcing bars 30 and widthwise FRP reinforcing bars 40 are arranged in the main body 10, high tensile strength can be secured compared to general reinforcing bars, and corrosion resistance can be expected. On the other hand, in the case of using FRP reinforcement, the initial cost may be slightly increased compared to the reinforcement of the reinforcement, but the cost associated with maintenance and repair can be reduced by extending the life of the deck, thus reducing the overall Life Cycle Cost (LCC). The effect of being exerted.

Further, depending on the embodiment, the shear connector 20 partially buried in the above-described main body 10 may also be made of FRP reinforcement. Accordingly, the PC deck of the present invention can extend the life as well as secure durability by completely replacing the reinforcement with FRP reinforcement.

On the other hand, as shown in Figure 4 (a), the reinforcing protrusion 42 protrudes outward, and the relationship with the reinforcing protrusion 42 of the exposed widthwise FRP reinforcement 40 of the adjacent PC deck D Since mutual interlocking is performed at, even if the individual PC deck (D) behaves independently due to the live load after construction, it is possible to prevent reflection cracking because it is possible to reinforce the tensile reinforcement of the concrete (TC) placed on the site.

Although not shown in the drawings, the ends of the pair of widthwise reinforcing bars 40 may be interconnected so that the shape of the reinforcing protrusion 42 may be formed to have a'U' shape.

On the other hand, as shown in Figure 3b, the width direction FRP reinforcing bar 40 may be formed so that the end FRP reinforcing bar 40b is bound to both ends of the straight FRP reinforcing bar 40a embedded in the end. At this time, the end FRP reinforcing bar 40b has an upward inclined portion 41 formed on the horizontal portion 43, and the end of the upward inclined portion 41 is horizontally bent outward to form a reinforcing protrusion 42. have.
The horizontal portion 43 of the end FRP reinforcing bar 40b may be fused to the end of the straight FRP reinforcing bar 40a, or may be conveniently extended and bound to each other by a separate binding means 40c such as a coupler.

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In addition, the PC deck (D) of the present invention has a side inclined surface (50) that gradually decreases in height toward the outside so as to increase the effective cross-sectional area of the field concrete (TC) poured on both ends in the width direction of the main body (10) Can be formed.

Further, as shown in (b) of Figure 4, since a larger bending load is generated in the longitudinal direction of the PC deck (D), it is understood that reflective cracks are also caused at both ends of the longitudinal direction. By forming the end inclined surfaces 60 at both ends in the longitudinal direction of the deck D, the effective cross-sectional area of the field concrete TC placed on the upper ends of both ends in the longitudinal direction can also be increased.

Further, an upward inclined portion 31 is formed so that both ends of the longitudinal FRP reinforcing bar 30 arranged longitudinally on the PC deck D are also exposed upward, and the upward inclined portion 31 is horizontally outwardly The reinforcing protrusion 32 may be formed to be bent. Since the reinforcing protrusions 32 of the longitudinal FRP reinforcing bars 30 protrude outward, tensile reinforcement for the space between adjacent decks (D) is possible, so reflective cracking of the field concrete (TC) according to bending load or flow load Can be prevented. In addition, although not shown in the drawings, the ends of the pair of longitudinal FRP reinforcing bars 40 may be interconnected so that the shape of the reinforcing protrusion 42 may be formed to have a'U' shape.

In addition, as shown in Fig. 3b, the longitudinal FRP reinforcing bar 30 may also be formed so that the end FRP reinforcing bars 30b are bound at both ends of the straight FRP reinforcing bar 30a embedded in the end. At this time, the end FRP reinforcing bar 30b also has an upward inclined portion 31 formed on the horizontal portion 33, and the end of the upward inclined portion 31 is horizontally bent outward to form a reinforcing protrusion 32. have. The horizontal portion 33 of the end FRP reinforcing bar 30b may be fused to the end of the straight FRP reinforcing bar 30a or extended in the longitudinal direction by a separate binding means 30c such as a coupler. Furthermore, although not shown in the drawings, a tension member such as a main reinforcing bar may be provided in the body 10 in addition to the longitudinal FRP reinforcing bar 30.

On the other hand, in order to manufacture the above-described PC deck (D), as shown in Fig. 5, the form (A) for the FRP reinforcement deck of the present invention has a shape corresponding to the main body 10 of the PC deck (D). A rectangular bottom plate 100 is provided, a pair of side plates 200 are provided at both ends in the width direction of the bottom plate 100, and a pair of end plates 300 are provided at both ends in the length direction. do.

However, each hinge portion 210 is formed at the lower end of the side plate 200 to be open to the outside when the PC deck D is demolded. The hinge part 210 is provided in a closed state during pouring and curing to accommodate the concrete, and when curing is completed, the hinge part 210 is opened downward to the outside to easily demold the completed PC deck (D). can do. In addition, since the side plate 200 itself can be opened based on the hinge portion 210 provided at the lower end, while securing the degree of freedom of the end shape of the PC deck D, ease of manufacture can be expected.

In addition, reinforcing bar mounting grooves 220 are formed at an upper end of the side plate 200 at regular intervals so that both ends of the plurality of widthwise FRP reinforcing bars 40 arranged in the body 10 are respectively mounted. Each reinforcing bar mounting groove 220 is formed spaced apart by the interval of the FRP reinforcing bar 40 in the width direction to be reinforced, and both ends of the FRP reinforcing bar 40 in the width direction are seated in the rebar mounting grooves 220 in the width direction. Even when the 40 is provided so as to be exposed to the outside in the width direction, the advantage of being able to pour and cure concrete without interfering with the side plate 200 of the formwork (A) is exhibited.

In addition, according to the embodiment, an upward inclined portion 41 is formed to expose both ends of the widthwise FRP reinforcing bar 40 upward, and the upward inclined portion 41 is again horizontally bent to the outside to reinforce a reinforcing protrusion ( Even in the case of forming 42), the reinforcing protrusion 42 may be seated in the reinforcing bar mounting groove 220.

Accordingly, even if a separate spacer is not provided on the bottom plate 100 of the formwork (A), the widthwise FRP reinforcing bar 40 has the effect of being relocated to the correct position, and also flow or self-weight due to vibration applied during the concrete curing process It can prevent bending deformation by

On the other hand, as shown in Figure 6, the side plate 200 of the formwork (A) has a vertical portion 230 is formed at a predetermined height, the upper end of the vertical portion 230 is bent inwardly upward and the inclined side portion 240 ) Can be formed. The inclined side portion 240 is for forming a side inclined surface 50 to secure the effective cross-sectional area of the field concrete (TC) at the end in the width direction of the completed PC deck (D), the lower end of the vertical portion 230 Since the hinge portion 210 is formed, the ease of demoulding can be expected while forming the side inclined surfaces 50 at both ends of the PC deck D in the width direction.

In addition, the upper end of the inclined side portion 240 is bent upward to form the seating portion 250, and since the reinforcing bar mounting groove 220 may be formed in the seating portion 250, while forming the inclined side portion 240 Both ends of the widthwise FRP reinforcing bar 40 can be stably mounted in the reinforcing bar mounting groove 220.

On the other hand, for an embodiment in which the lengthwise FRP reinforcement bar 30 of the PC deck (D) of the present invention is exposed to the outside, the formwork (A) of the present invention is formed on the upper end of the end plate (300). ) Reinforcing bar mounting grooves 320 may be formed at regular intervals so that both ends of the plurality of longitudinal FRP reinforcing bars 30 are mounted respectively.

Since both ends of the longitudinal FRP reinforcing bars 30 are respectively seated in the reinforcing bar mounting grooves 320, the end plate 300 of the formwork (A) even when the longitudinal FRP reinforcing bars 30 are exposed to the outside in the longitudinal direction. The advantage is that concrete can be poured and cured without interference.

In addition, forming an upward inclined portion 31 to expose both ends of the longitudinal FRP reinforcing bar 30 upward, and forming the reinforcing protrusion 32 by horizontally bending the upward inclined portion 31 to the outside again. Even in the case, since the reinforcing protrusion 32 can be seated in the reinforcing bar mounting groove 320, the longitudinal FRP reinforcing bar 30 is in its correct position even if a separate spacer is not provided on the bottom plate 100 of the formwork (A). There is an effect of being laid in.

In addition, when the reinforcing bar mounting grooves 220 and 320 are respectively formed in the side plate 200 and the end plate 300 of the formwork (A), the longitudinal FRP reinforcing bar 30 is in the reinforcing bar mounting groove 320 While seated and reinforced in place, since it is additionally provided below and is additionally supported by a plurality of widthwise FRP reinforcement bars 40, the longitudinal FRP reinforcement bar 30 and the widthwise FRP reinforcement bar 40 mutually reduce the sag load due to their own weight. Can accommodate distributed. Therefore, in the longitudinal direction FRP reinforcing bar 30 and the width direction FRP reinforcing bar 40, there is an advantage that it can be placed in the correct position not only in the vertical direction, but also in the height direction, and thereby in manufacturing the PC deck (D) It is possible to secure a certain coating thickness.

Although the FRP reinforcing bar has excellent corrosion resistance, the thickness of the coating is not important, but it is desirable to secure a coating of a certain thickness for aesthetic reasons and to prevent concrete detachment.

Meanwhile, as shown in FIG. 7, a hinge portion 310 is also formed at the lower end of the end plate 300 of the formwork A so that it can be opened to the outside when the PC deck D is demolded. As a result, since the end plate 300 itself can be opened based on the hinge portion 310 provided at the lower end, the shape of the longitudinal end of the PC deck D can also secure a degree of freedom, and ease of manufacture can be expected. .

In addition, the end plate 300 may have a vertical portion 330 formed at a predetermined height, and an upper end of the vertical portion 330 may be bent inward and upward to form an inclined side portion 340. The inclined side portion 340 is for forming an end inclined surface 60 so that the effective cross-sectional area of the field concrete TC is secured even at the longitudinal end of the finished PC deck D, and at the lower end of the vertical portion 330 Since the hinge portion 310 is formed, it is possible to secure the ease of demoulding while forming end inclined surfaces 60 at both ends of the PC deck (D) in the longitudinal direction.

At this time, the upper end of the inclined side portion 340 is bent upward to form a seating portion 350, and a reinforcing bar mounting groove 320 may be formed in the seating portion 350.

On the other hand, according to the form (A) for the FRP reinforced PC deck of the present invention, as shown in Figure 8, the fasteners 260 are bound to both ends of the widthwise FRP reinforcing bar 40, and the fastener 260 is It is fixed to the outside of the reinforcing bar mounting groove 220 to prevent sagging of the width direction FRP reinforcing bar 40 even under load or self-weight caused by concrete placement.

The fixture 260 may be bound to the widthwise FRP reinforcement 40 in various ways. In one embodiment, a pressure fixing method through fastening of fasteners may be used, and even if a strong load is applied to the widthwise FRP reinforcing bar 40 as the fastener 260 and the widthwise FRP reinforcing bar 40 are firmly bound It becomes possible to prevent sagging. Further, although not shown in the drawing, the fixture 260 may be bound to the longitudinal FRP reinforcement bar 30, and even in this case, the fastener 260 is outside the reinforcing bar mounting groove 320 formed on the end plate 300. It is locked and prevents sagging.

In addition, as shown in FIG. 9, depending on the embodiment, a height adjustment bar 270 may be provided in the length direction to adjust the height of the reinforcing bar mounting groove 220 on the side plate 200. Thereby, since the height of the widthwise FRP reinforcement bar 40 seated in the reinforcing bar mounting groove 220 can be adjusted, there is an advantage that the depth of the widthwise FRP reinforcement bar 40 can be flexibly adjusted according to conditions.

In addition, when the height of the FRP reinforcing bar 40 in the width direction is adjusted by the height adjustment bar 270, the height of the longitudinal FRP reinforcing bar 30 provided at the top can also be adjusted, so the overall depth of the FRP reinforcing bar to be reinforced Can be adjusted.

On the other hand, hereinafter, a method (M) of manufacturing an FRP-reinforced PC deck using the above-described form (A) for an FRP-reinforced PC deck of the present invention will be described. FRP reinforced PC deck manufacturing method (M) of the present invention is provided with a pair of side plates 200 at the width direction end of the rectangular-shaped bottom plate 100, and a pair of end plates 300 at the longitudinal ends Using the provided FRP reinforced PC deck formwork (A), as shown in Figure 10, the width direction FRP reinforcing bar mounting step (S10), the longitudinal FRP reinforcing bar placement step (S20), the body forming step (S30) and the deck It includes a demolding step (S40).

First, in the width direction FRP reinforcing bar mounting step (S10), reinforcing protrusions 42 formed at both ends of the widthwise FRP reinforcing bar 40 in the reinforcing bar mounting grooves 220 formed at regular intervals on the upper end of the side plate 200 It is a step to mount each. Each of the widthwise FRP reinforcing bars 40 is spaced apart by the interval of the reinforcing bar mounting grooves 220.

More specifically, the width direction FRP reinforcement mounting step (S10) may additionally include a reinforcing protrusion mounting step (S11) and a widthwise FRP reinforcement height adjustment step (S12). The reinforcing protrusion mounting step (S11) is a step of mounting the reinforcing protrusions 42 in which the upwardly inclined portions 41 of both ends of the FRP reinforcing bar 40 in the width direction are horizontally bent to the outside in the reinforcing bar mounting groove 220, respectively. , When forming an upward inclined part 41 to expose both ends of the widthwise FRP reinforcing bar 40 upward, and forming the reinforcing protrusion 42 by horizontally bending the upward inclined part 41 to the outside again Also, the reinforcing protrusion 42 may be seated in the reinforcing bar mounting groove 220.

In addition, in the width direction FRP reinforcing bar height adjustment step (S12), by adjusting the height of the height adjustment bar 270 provided in the length direction on the side plate 200 to adjust the height of the reinforcing bar mounting groove 220, the width direction This is a step of adjusting the height of the FRP reinforcing bar 40.

In addition, in the width direction FRP reinforcing bar mounting step (S10), a widthwise FRP reinforcing bar fixing step (S13) in which the fixing tool 260 is bound to the reinforcing protrusion 42 so that it is locked to the outside of the reinforcing bar mounting groove 220 (S13). ) May be additionally included. By the fixture 260, it is possible to prevent sagging of the FRP reinforcing bar 40 in the width direction even under a load or self-weight caused by concrete pouring.

At this time, the fixture 260 may be bound to the widthwise FRP reinforcing bar 40 in various ways. A pressure fixing method through fastening of fasteners may be used.

The longitudinal FRP reinforcing bar placement step (S20) that proceeds after the widthwise FRP reinforcing bar mounting step (S10) is a step of disposing the longitudinal FRP reinforcing bars 30 at regular intervals on the upper portion of the widthwise FRP reinforcing bar 40. . The longitudinal FRP reinforcement bar 30 is usually provided on the top of the widthwise FRP reinforcement bar 40 or is generally bonded to each other, and is provided to be supported by the widthwise FRP reinforcement bar 40, so that the concrete pouring load or its own weight Even if some sagging occurs, the longitudinal FRP reinforcing bar 30 and the width direction FRP reinforcing bar 40 may mutually accommodate the sagging load due to their own weight.

Therefore, in the longitudinal direction FRP reinforcing bar 30 and the width direction FRP reinforcing bar 40, there is an advantage that it can be placed in the correct position not only in the vertical direction, but also in the height direction, and thereby in manufacturing the PC deck (D) It is possible to secure a certain coating thickness.

On the other hand, reinforcing bar mounting grooves 320 formed at regular intervals may also be formed on the top of the end plate 300 of the formwork (A). At this time, in the longitudinal FRP reinforcing bar arrangement step (S20), reinforcing protrusions 32 formed at both ends of the longitudinal FRP reinforcing bar 30 may be mounted in the reinforcing bar mounting grooves 320, respectively.

Thus, when the reinforcing bar mounting grooves 220 and 320 are formed in the side plate 200 and the end plate 300 of the formwork (A), respectively, the longitudinal FRP reinforcing bar 30 is the reinforcing bar mounting groove 320 While being seated on and being reinforced in position, since it is supported by a plurality of widthwise FRP reinforcing bars 40 provided further below, the deflection and flow load of the longitudinal FRP reinforcing bars 30 and the widthwise FRP reinforcing bars 40 Can accommodate mutual distribution.

In addition, the body forming step (S30) that proceeds after the longitudinal FRP reinforcement arrangement step (S20) is a step of pouring concrete into the formwork (A) for the PC deck to cure. After pouring the concrete, it is preferable to induce a homogeneous distribution of the aggregate by applying a constant vibration. However, according to the form (A) of the present invention, since the widthwise FRP reinforcing bar 40 can be fixedly provided by the reinforcing bar mounting groove 220, stable reinforcement is possible without deviating from the original position even in vibration load.

The deck demoulding step (S40) proceeding after the body forming step (S30) opens the side plate 200 to the outside based on the hinge part 210 formed at the lower end of the side plate 200 to open the PC deck (D). This is the step of demoulding. Ease of demoulding can be expected while forming side inclined surfaces 50 at both ends in the width direction of the PC deck D by the hinge part 210.

In addition, according to the embodiment, when the end inclined surface 60 is formed, a hinge portion 310 may be formed at the lower end of the end plate 300, and in this case, the side plate 200 as well as the end plate 300 Also, since it can be opened based on the hinge part 310, more effective demoulding is possible.

The FRP-reinforced PC deck (D) of the present invention described above, the formwork (A) therefor, and the manufacturing method (M) of the FRP-reinforced PC deck using the same, those of ordinary skill in the art to which the present invention pertains the present invention. It will be appreciated that it can be implemented in other specific forms without changing the technical idea or essential features of

Therefore, the embodiments described above are illustrative in all respects and should be understood as not limiting, and the scope of the present invention is indicated by the claims to be described later rather than the detailed description described above, and the meaning of the claims and The scope and all changes or modifications derived from the concept of equivalent should be construed as being included in the scope of the present invention.

D: FRP reinforced PC deck 10: main body
20: shear connector 30: longitudinal FRP reinforcement
40: width direction FRP reinforcing bar 50: side slope
60: end slope
A: PC deck formwork 100: Bottom plate
200: side plate 300: end plate
210,310: hinge portion 220,320: reinforcement bar mounting groove
230,330: vertical part 240,340: inclined side
250,350: seating part 260: fixture
How to make a M:FRP reinforcement deck
S10: The step of mounting the widthwise FRP rebar
S20: Lengthwise FRP rebar placement step
S30: Body formation step
S40: Deck demoulding step

Claims (12)

delete delete delete delete delete delete delete delete delete FRP reinforcement using a PC deck formwork (A) provided with a pair of side plates 200 at the ends in the width direction of the rectangular bottom plate 100 and a pair of end plates 300 at the ends in the longitudinal direction In the manufacturing method (M) of the PC deck (D),
The side plate 200 of the PC deck formwork (A) has a vertical portion 230 formed at a predetermined height, the upper end of the vertical portion 230 is bent inward and upward to form an inclined side portion 240, the The upper end of the inclined side portion 240 is bent upward to form a seating portion 250, a reinforcing bar mounting groove 220 is formed at a predetermined interval in the seating portion 250, and a widthwise direction in the reinforcing rod mounting groove 220 Reinforcing protrusion mounting step (S11) in which the upwardly inclined portions 41 of both ends of the FRP reinforcing bar 40 mount the reinforcing protrusions 42 horizontally extending outward; And a widthwise reinforcing bar height adjustment step (S12) of simultaneously adjusting the height of the plurality of reinforcing bar mounting grooves 220 by adjusting the height of the height adjustment bar 270 provided on the outside of the side plate 200 in the longitudinal direction. Reinforcing bars in the width direction including a step (S10);
A longitudinal FRP reinforcing bar arranging step (S20) of arranging the longitudinal FRP reinforcing bars 30 at regular intervals on the top of the widthwise FRP reinforcing bars 40;
A body forming step (S30) of pouring concrete to cure the PC deck formwork (A) so that the upper end of the upwardly inclined portion 41 of the widthwise FRP reinforcing bar 40 is exposed (S30); And
Deck demoulding step (S40) of opening the side plate 200 to demold the PC deck (D);
FRP reinforced PC deck manufacturing method using a formwork comprising a.
The method of claim 10,
The longitudinal FRP reinforcement mounting step (S20),
FRP reinforcement using a form, characterized in that the reinforcing protrusions 32 formed at both ends of the longitudinal FRP reinforcing bar 30 are respectively mounted in the reinforcing bar mounting grooves 320 formed at regular intervals on the upper end of the end plate 300 How to make a PC deck.
In the PC deck (D) that has a certain thickness (t) and is provided so that the shear connector 20 is partially exposed to the upper part of the precast concrete body 10 of a rectangular shape with a flat bottom,
The PC deck (D) is manufactured according to the manufacturing method (M) of the PC deck (D) of claim 10, and the main body 10 includes a plurality of longitudinal FRP reinforcing bars 30 and a widthwise FRP reinforcing bar 40. However, both ends of the widthwise FRP reinforcing bar 40 are formed with an upward inclined portion 41 to be exposed upward, and the upward inclined portion 41 is horizontally extended to the outside to form a reinforcing protrusion 42, At both ends of the body 10 in the width direction and at both ends in the length direction, the side slopes 50 and the end slopes 60 gradually lower in height toward the outside so that the effective cross-sectional area of the field concrete (TC) to be poured on the top is increased. ) FRP reinforced PC deck, characterized in that each is provided.

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