KR102048287B1 - Tendon spreading fixing appratus for prestressed girder - Google Patents

Abstract

The present invention relates to a strand embedded distribution apparatus for fixedly installing one end of a plurality of strands for introducing prestress to a girder for bridges to be embedded in concrete of the girder. A fixation anchorage apparatus of the present invention includes a first distribution body in which a guide hole for blocking the inside of a sheath tube surrounding a strand in the concrete from the outside and penetrating the strand one by one is formed. Therefore, a bulbing unit formed at one end of the strand is embedded in the concrete outside the first distribution body, thereby suppressing inflow of substance of the poured concrete into the sheath tube accommodating the strand and increasing the reliability of the fixation anchorage unit of the strand.

Description

Stranded Decentralized Fusing Device for Prestress Girder {TENDON SPREADING FIXING APPRATUS FOR PRESTRESSED GIRDER}

The present invention relates to a fixed strand fixing apparatus for prestressed girders, and more particularly, to fix the fixed fixing portion of the stranded wire for introducing the prestress to the concrete portion of the bridge girder more firmly to the concrete portion and to cast The present invention relates to a strand wire anchorage fixing device that effectively prevents unconsolidated concrete from flowing into the sheath pipe.

In general, a bridge is constructed by mounting a girder on a lower structure such as a pier or a shift, and a floor plate through which a vehicle or a pedestrian passes on an upper surface of the girder. The load acting on the bridge acts as a fixed load and a live load according to the traffic of a vehicle, and a compression prestress is introduced under the neutral shaft to increase the load capacity of the bridge.

As a method of introducing the compressive prestress, a method of fixing the stranded wire 20 in the state in which the tensile force is introduced into the stranded wire 20 while being installed in the sheath pipe 20s of the concrete part 12 is widely used.

According to the Republic of Korea Patent Publication No. 10-0547619, the applicant has applied for and registered a patent, the compressive stress introduced into the concrete portion at the girder end position does not exceed the allowable stress, while the bending moment (BMDr) acting in common Similarly, a configuration for introducing compression prestress is disclosed.

According to this, as shown in FIGS. 1A and 1B, in order to introduce compression prestress into the concrete portion 12 of the steel composite girder 10 in which the steel beam 11 and the concrete portion 12 are synthesized. The strand 21 is fixed to the one end E1 of the girder by the movable fixing port 21a and fixed to the inside of the concrete at a position spaced apart from the other end E2 of the girder by the fixing anchor 21b, and the second strand 22 is It is configured to be fixed to the other end (E2) of the girder by the movable fixing port (22a) and fixed to the fixing fixture (22b) inside the concrete at a position spaced apart from the one end (E1) of the girder.

Then, the compression prestress is introduced into the concrete portion 12 by fixing in the state where the tensile force is introduced into the strands 21 and 22 in the movable fixing ports 21a and 22a. In particular, as the fixed anchorages 21b and 22b are buried and fixed at positions spaced apart from the ends E1 and E2 of the concrete portion 12, as shown in FIG. 1B, the prestress introduced into the concrete portion 12 is shown. The bending moment BMDp, which is supported by the, is actually formed in a stepped shape similar to the bending moment BMDr acting on the bridge girders 9.

Here, as shown in FIG. 2, the fixed anchorage 22b is a sheath pipe 20s at the end of the strand wire 22b built in the sheath pipe 20s inside the reinforcing bar 25 provided in the steel beam 11. ) Is exposed to the outside, and the bulbous portion 20x is formed at the end of the strand, and the concrete portion 12 and the bulbous portion 20x are fixed integrally.

However, as shown in FIG. 3, the inner space of the sheath tube 20s is formed to be wider than the cross-sectional space occupied by the strand 22 to smoothly install and insert the strand 22. Even in the state arranged inside the sheath tube 20s, the empty space V occupies a large space.

Accordingly, when the concrete for forming the concrete portion 12 is poured in the state in which the strand 22 is installed in the sheath tube 20s as shown in FIG. 2, the pouring concrete (for example, cement paste) There was a limit to reliably obtain the corrosion resistance at the end of the sheath tube 20s in which the fixing anchorage 22b is formed by being introduced into the sheath tube 20s and hardened.

In addition, the plurality of strands 21 and 22 in the sheath tube 20s is effective to spread the ends formed with the bulging portion 20x at appropriate intervals to form a fixed anchorage, and the strands 21 and 22 are applied one by one. There were also problems with opening up.

Accordingly, in forming a fixed fixing part in which the end of the strand for introducing prestress to the bridge girders is embedded in the concrete part, the inside and the outside of the sheath pipe 20s are clearly distinguished to suppress the penetration of the poured concrete. There is an increasing need to efficiently disperse the bulge at the end of the strand.

An object of the present invention is to more reliably form a fixed fixing part in which an end of a strand of wire that introduces prestress into a girder for bridges is embedded in concrete.

That is, the present invention, the fixed anchoring portion of the end of the stranded wire embedded in the concrete portion is distributed evenly to the concrete portion to improve the adhesion to the concrete portion, the object of the present invention is to reliably implement the action as a fixed fixing portion even greater force.

Not only this, but also an object of this invention is to distribute | distribute the edge of the stranded wire which forms a fixed fixing part easily evenly as much as it intended, regardless of an operator's skill.

In addition, an object of the present invention is to ensure that corrosion resistance and durability are prevented by mixing the grout material and the poured concrete which are filled in the sheath pipe containing a strand wire embedded in the concrete part to form a fixed fixing part.

The present invention is derived in order to achieve the above object, as a strand wire dispersing device for fixed installation of one end of a plurality of strands for introducing prestress to the girder for bridges embedded in the concrete of the girder, the concrete A first dispersion formed with guide holes for blocking the inside of the sheath pipe surrounding the strand and the outside thereof, and guiding the strand by one; Including, the bubbling portion formed at one end of the strand wire provides a strand anchor distributed type fixing device for prestressed girders, characterized in that embedded in the concrete from the outside of the first dispersion.

According to the present invention configured as described above, as the sheath pipe and the concrete part are partitioned by the first dispersion, even if the concrete is poured to form the concrete part in the state where the strand is installed in the sheath pipe, the concrete is introduced into the sheath pipe. By preventing the inflow can be obtained to ensure the corrosion resistance of the strand.

In addition, the present invention is determined by the guide hole formed in the first dispersion, the position of the strands are guided one by one, so that the gap and the degree of gap between the strands can be secured exactly as a predetermined amount regardless of the skill of the operator and the fixed fixing unit The effect which becomes easy to form can be acquired.

Above all, according to the present invention, a plurality of strands are distributed to each other in the radial direction and in the longitudinal direction so that the adhesive force with the concrete part is more secured, thereby achieving the effect of more reliably implementing the fixed fixing part.

Through this, the present invention can more accurately introduce the compression prestress corresponding to the bending moment acting on the girder for the bridge to obtain the effect of reliably implementing the predetermined load capacity.

Figure 1a is a front view showing the structure of the strand strand of the conventional composite girder for bridges,
Figure 1b is a plan view and a bending moment of Figure 1a.
Figure 2 is an enlarged view of portion 'A' of Figure 1a before concrete pouring,
3 is a cross-sectional view taken along line III-III of FIG. 2;
4 is a perspective view showing a strand wire distributed fixed fixing device for a prestress girder according to a first embodiment of the present invention;
5 is a longitudinal cross-sectional view of FIG. 4;
FIG. 6 is a perspective view showing a strand dispersing fixed fixing device for prestress girders according to a second embodiment of the present invention; FIG.
7 is a longitudinal cross-sectional exploded view of FIG. 6;
8 and 9 are longitudinal cross-sectional exploded views showing a strand wire distributed fixed anchoring device for a prestress girder for bridges according to a modified embodiment of FIG.
FIG. 10A is a side view of the first dispersion of FIG. 7; FIG.
FIG. 10B is a side view of the second dispersion of FIG. 7;
FIG. 11 is an enlarged view of a state in which the strand is arranged in the guide hole of the first dispersion as another embodiment of the present invention. FIG.

Hereinafter, with reference to the accompanying drawings, a bridge-type distributed fixed anchoring device 100 for a prestress girder for bridges according to an embodiment of the present invention will be described in detail. However, in describing the present invention, a detailed description of known functions or configurations will be omitted to clarify the gist of the present invention.

The strand-type distributed fixed anchoring device 100 for bridges of the prestress girder according to the first embodiment of the present invention, as shown in FIGS. 4 and 5, wraps the strand 20 in the concrete part 12. Coupling tube 110 coupled to the sheath tube 20s and coupled to the end of the connecting tube 110 to block the inside of the sheath tube 20s surrounding the strand 20 in the concrete portion 12 and the outside thereof. And a first dispersion body 120 formed with guide holes 122 for guiding the strand wires 20 one by one to bridge the ends of the plurality of strand wires 20 for introducing prestress to the bridge girder. It is configured to be fixed in the form of being embedded in the concrete portion 12 of the girder.

As shown in FIGS. 4 and 5, the connection tube 110 is connected to the end of the sheath tube 20s into which the plurality of strands 20 are inserted, and is exposed to the outside of the sheath tube 20s. It accommodates the strand 20 of the penetrating.

For example, one end of the connection tube 110 is formed in a form surrounding the end outer peripheral surface (20so) of the sheath tube (20s), one end inner peripheral surface (110i) of the connection tube 110 and the outer peripheral surface 20so of the sheath tube end and Fitted or welded together. In some cases, one end of the connection tube 110 may be installed to be inserted into the end of the sheath tube 20s, the present invention is not limited to the connection method of the connection tube 110 shown in the drawings, The connection tube 110 may be connected to the sheath tube 20s by various known methods.

As shown in FIG. 5, the connection tube 110 is provided with an expansion area Ex formed so that the cross section becomes larger toward the end of the strand 20, and the end surface of the connection tube 110 may have a sheath tube ( Larger than the cross section of 20 s).

The first dispersion 120 has a body 120p having a plurality of guide holes 122 formed therein, and is coupled to the connection tube 110 to partition an inner space and an outer space of the sheath tube 20s.

In order to install the first dispersion 120, the first dispersion 120 includes an extension 120e in which a surface 120i contacting the end surface 110o of the connection tube 110 extends in the axial direction. Thus, the surfaces 110o and 120i may be integrated in various ways such as by welding or adhesive bonding in a state where the surfaces 110o and 120i abut.

However, the present invention is not limited to the shape shown in the drawings, and includes various shapes including a body 120p having a guide hole 122 for guiding the strand 20. In addition, although the configuration in which the body 120p of the first dispersion 120 is formed in the shape of a plate is illustrated in the drawings, the configuration may be formed in various shapes such as a block shape.

Here, as shown in FIG. 4, the body 120p of the first dispersion 120 is preferably formed in a circle, and a part of the plurality of guide holes 122 is disposed in a circle along a circular edge. As a result, the strands 20 penetrating the guide holes 122 of the first dispersion 120 are respectively spaced farther from the concrete part 12 while maintaining a distance ey spaced farther from each other. Distributed. The guide holes 122 of the first dispersion 120 are disposed in the center portion in addition to the guide holes formed in a circular shape, and the stranded wire 20 passing through the guide holes 122 of the first dispersion 120 is sheathed. Spaced apart from each other in the radial direction about the central axis of the tube.

As a result, the plurality of strands 20 accommodated in the sheath tube 20s are distributed and disposed while passing through the guide holes 122 of the first dispersion 120 one by one, regardless of the skill of the operator and the like. ), The stranded wire 20 is in a separated state, and at the same time, the bulging portion 20x at the end of the stranded wire 20 is evenly distributed in the concrete portion 12.

Furthermore, as the connecting tube 110 is provided with an expansion area Ex that has a larger cross section, the cross section of the body 120p of the first dispersion 120 is larger than the cross section of the sheath tube 20s. do. Therefore, the guide holes 122 formed in the first dispersion 120 are provided with an environment that can be spaced farther apart from each other, thereby increasing the efficiency of distributing the strand 20 more spaced apart from the concrete part 12. have.

On the other hand, according to another embodiment of the present invention, the connecting tube 110 is not provided to the end of the sheath tube 20s, the first dispersion 120 is in the form directly connected to the sheath tube 20s. Can be configured. In this case, although the effect of distributing more spaced apart in the plane direction perpendicular to the longitudinal direction by the expansion region Ex is obtained, the effect of dispersing the strand 20 through the guide hole 122 at a predetermined position is obtained. Can be.

In addition, since the end of the sheath tube 20s is blocked by the first dispersion body 120, both the inner space and the outer space of the sheath tube 20s except the guide hole 122 are blocked. Accordingly, in the state where the strand 20 penetrates the guide hole 122 of the first dispersion 120, all or most of the space of the guide hole 122 is blocked by the strand 20, so that the concrete portion In the process of forming (12), it is possible to prevent the unconsolidated concrete such as cement paste from flowing into the inner space of the sheath tube (20s).

According to a preferred embodiment of the present invention, the guide hole 122 of the first dispersion 120 may be provided with an elastic ring 88 capable of elastic deformation such as rubber. By doing so, while the strand 20 passes through the guide hole 122 one by one, while contacting the outer peripheral surface of the strand 20 by the elastic restoring force of the elastic ring 88, between the strand 20 and the guide hole 122 Since the gap can be minimized or eliminated completely, the inner space of the sheath tube 20s and the concrete part 12 can be brought into a completely partitioned state.

Meanwhile, according to another embodiment of the present invention, as shown in FIG. 11, the guide hole 122 ′ formed in the body 120 p of the first dispersion body is inserted based on the insertion direction 20 d of the strand. The cross section of one side may be formed to include an inclined portion such as a funnel or cone shape that is larger than the cross section of the other side that is discharged. The outer circumferential surface of the elastic ring 88 'is inclined so as to be in close contact with the inner wall of the funnel-shaped guide hole 122', when the strand 20 is installed while passing through the guide hole 122 '. While the 88 'is prevented from being pushed by the strand 20 and falling out of the guide hole 122', the outer peripheral surface of the strand 20 is reliably in close contact with the inner peripheral surface of the elastic ring 88 'by elastic restoring force. This ensures more confidentiality.

In the strand dispersing type fixed fixing device 100 according to the first embodiment of the present invention configured as described above, the inside of the sheath tube 20s accommodating the strand 20 and the concrete part 12 may include a first dispersion ( As clearly distinguished by 120, the grout material and the poured concrete which are filled in the sheath tube 20s are not mixed with each other, and the concrete part as the strands 20 are spaced apart from each other while maintaining a predetermined distance (ey) from each other. It is buried in a state dispersedly arranged in (12) and can be more firmly integrated into the concrete portion 12 can obtain the effect of making the action of the fixed fixing unit more reliable.

Hereinafter, with reference to the accompanying Figures 6 and 7, detailed description will be given of the strand dispersible fixed fixing device 200 according to a second embodiment of the present invention.

Bridge type pre-stress girders distributed fixed anchoring device 200 according to a second embodiment of the present invention, as shown in Figure 6 and 7, wraps the strand wire 20 in the concrete portion 12 A first dispersion body having a connection tube 210 coupled to the sheath tube 20s and a first guide hole 222 coupled to an end portion of the connection tube 210 and guiding through the strand wire 20 one by one ( 220 and an extension tube 240 connected in communication with the central through hole 226 formed through the central portion of the first dispersion 220, coupled to the end of the extension tube 240, and the strand 20. And a second dispersion body 250 having a second guide hole 252 formed therethrough for guiding one by one, and the end of the plurality of strands 20 for introducing prestress to the bridge girder of the bridge girder. It is configured to be fixed in a form embedded in the concrete portion 12.

Like the first embodiment described above, the connection tube 210 is connected to the end of the sheath tube 20s into which the plurality of strands 20 are inserted, and thus the plurality of strands exposed to the outside of the sheath tube 20s. 20 is accommodated through. The connection of the connection tube 210 and the sheath tube 20s may be made by various methods such as welding and taping. Preferably, as shown in the drawing, a part of the connection tube 210 and the sheath tube 20s is provided. Are overlapped and may be mutually coupled in a manner such as a welding joint or an adhesive joint.

Similarly, the connection tube 210 is provided with an expansion area Ex formed so as to have a larger cross section toward the end of the strand 20, so that the cross section of the end of the connection tube 210 is larger than the cross section of the sheath tube 20s. It is largely formed. For example, a portion of the first guide hole 222 may be partially disposed outside the cross section of the sheath tube 20s. Accordingly, as shown in FIG. 10A, the first guide hole 222 formed in the first dispersion 220 is distributed in a circle along the circular edge 220y of the dispersion 220, and the sheath tube ( And may be distributed in a radial position further away from the axis of 20s).

The first dispersion 220 includes a body 220p in which a plurality of first guide holes 222 are arranged in a circular shape, and an extension portion 220e extending from the body 220p along the axial direction of the sheath tube. ) Is provided. Accordingly, the first dispersion 220 is coupled to the connection tube 210 via the extension 220e.

That is, the first dispersion 220 is coupled to the end of the connection tube 110 as in the first embodiment described above, the surface is in contact with each other may be coupled by a method such as welding or fastening. In addition, the body 220p of the first dispersion 220 may have a plate shape or a block shape.

6 and 10A, the body 220p of the first dispersion 220 may be formed in a circular shape, and the plurality of first guide holes 222 may have a circular edge 220y. Along the circle. As a result, the first strand 20a generally disposed at the outermost side of the strands 20 from the central axis of the sheath tube 20s passes through the first guide hole 222 of the first dispersion 220. It is radially extended toward the position spaced apart radially from the sheath tube central axis in the concrete portion 12.

However, the present invention is not limited to the configuration in which the bodies of the first dispersions 120 and 220 are formed in a circular shape, and may be formed in various shapes.

In the first dispersion 220, a central through hole 226 is formed in a central portion thereof, such that the second strand wire (not passing through the first guide hole 222 of the first dispersion 220 among the strands 20) Pass 20b). As necessary, as shown in FIG. 7, a protruding pipe 228 that assists the connection with the extension tube 240 is protruded in the axial direction of the sheath tube in the central through hole 226.

The extension tube 240 is coupled through the protruding pipe 228 of the first dispersion 220 to extend toward the bulb portion 20x of the strand in communication with the central portion of the first dispersion 220. Thus, the internal space of the extension tube 240 is in communication with the internal space of the connection tube 210. For example, the outer peripheral surface 240o1 is inserted into the inner circumferential surface 228i of the protruding pipe 228 of the first dispersion 220 so as to be inserted therein, and the protruding pipe 228 and the extension tube ( 240 may be coupled by means of welding, gluing, or fastening, or the like, and may be coupled in a variety of similar ways.

Accordingly, in the strands 20 passing through the sheath tube 20s, the second strand 20b of the center portion which does not pass through the first guide hole 222 of the first dispersion 220 is an extension tube 240. It will penetrate through.

The second dispersion 250 is coupled to the end of the extension tube 240, a plurality of second guide holes 252 is formed to pass through the second strand 20b one by one.

Here, as illustrated in FIG. 10B, the second guide hole 252 includes a guide hole disposed in a circle close to the circular edge 250y of the second dispersion 250 and a guide hole disposed in the center thereof. In this way, the guide hole in the center guides the second stranded wire 20b to extend substantially in a straight line shape, and the guide hole of the circular edge extends substantially radially to guide the second stranded wire 20b to be spaced apart in the radial direction.

The second dispersion 250 includes a body 250p having a second guide hole 252 formed therein, and an extension part 250e extending in the axial direction to assist the coupling with the extension tube 240 from the body 250p. It is provided. The extension part 250e may be coupled to surround the outer circumferential surface of the extension tube 240, or may be fitted to be coupled to contact the inner circumferential surface of the extension tube 240. However, the present invention is not limited thereto, and the second dispersion 250 may be coupled to the extension tube 240 in various ways.

As the second dispersion 250 extends in the axial direction from the first dispersion, the position of the bulging portion 20x of the second strand 20b passing through the second guide hole 252 is changed to the first guide hole ( 222 may be spaced apart in the axial direction compared to the position of the bulging portion 20x of the first stranded wire 20a.

As a result, the strand 20 in the sheath tube 20s not only disperses the position of each of the bulbous portions 20x in the radial direction (the direction perpendicular to the axial direction (the longitudinal direction) of the sheath tube, but also in the axial direction. Disperse too. In other words, the first guide hole 222 of the first dispersion 220 serves to disperse the first strand 20a in a radial direction perpendicular to the axial direction, and the second of the second dispersion 250. The guide hole 252 serves to disperse the second strand 20b in a radial direction perpendicular to the axial direction, and the extension tube 240 divides the bulging portion 20x of the second strand 20b into the first stranded line ( Compared to the bulging part 20x of 20a, it serves to disperse | distribute at the position further spaced apart in the axial direction by the length shown by Ls. That is, the dispersion arrangement is made with a difference between the separation distance Ls of the first stranded wire 20a and the second stranded wire 20b by the length of the extension tube 240.

Here, the length of the extension tube 240 is preferably formed within 1.0m (for example, 0.01m ~ 1.0m). Through this, it is possible to obtain an effect in which the fixed fixing unit is formed at one point while dispersing the bulging unit 20x of the first strand 20a and the bulging unit 20x of the second strand 20b in the longitudinal direction.

As such, the end portions of the strands 20 are arranged to be spaced apart from each other in the longitudinal direction in addition to the radial direction perpendicular to the axial direction of the sheath tube, so that the concrete portions can be tightly filled and attached between the respective strands 20. In addition, the strand 20 and the concrete portion 12 may be more firmly coupled and improved corrosion resistance, it is possible to obtain the effect of performing the role of the fixed fixing unit more reliably.

In addition, since the inner space of the sheath tube 20s is completely blocked from the concrete part 12 by the first dispersion 220, the extension tube 240, and the second dispersion 250, the concrete during the concrete pouring process. Can be suppressed from penetrating into the sheath tube. As in the first embodiment described above, as shown in FIGS. 10A and 10B, the first guide hole 222 and the second guide hole 252 are provided with an elastic ring 88 capable of elastic deformation. The guide holes 222 and 252 penetrated by 20 may be tightly blocked to more clearly partition the space communicating with the inner sheath of the sheath tube 20s and the concrete part 12.

In addition, although not shown in the drawing, the shape of the funnel-shaped guide hole 122 'shown in FIG. 11 and the elastic ring 88' of the inclined outer circumferential surface fitted thereto are shown in FIG. 5 to FIG. The same may be applied to the first guide hole 222 and the second guide hole 252.

On the other hand, as described above, the strand 20 of the first strand 20a penetrating the first guide hole 222 of the first dispersion 220 and the second dispersion 250 spaced longitudinally therefrom In the second strand 20b passing through the second guide hole 252, the bulging portion 20x at the end thereof is fixed to the concrete portion 12. Then, compressive prestress is introduced into the concrete portion 12 by introducing and fixing the tensile force in the movable anchoring holes of the strand 20 (reference numerals 21a and 22a in FIG. 1A).

Here, the first stranded wire (20a) and the second stranded wire (20b) at the same time the tensile force is introduced at the same time the end portion is bulge is distributed to the load in the concrete portion 12 is embedded buried dispersion is prevented excessive stress concentration. However, this distributed arrangement is limited by the size of the concrete portion (cross section) and the interference of the abdominal and lower flanges of the steel beam 11. Therefore, the dispersion of the strand through the first guide hole 222 of the first dispersion 220 and the second guide hole 252 of the second dispersion 250 also has a limitation. In particular, since the central through hole 226 is formed in the center of the first dispersion 220, the arrangement of the guide holes for dispersing the stranded wire is narrower than that of the second dispersion 250. In addition, excessive dispersal arrangement into one dispersion is undesirable because it causes disadvantageous stress concentration in the concrete portion 12 and degrades the durability performance due to cracking.

Therefore, the amount of the strands dispersed through the first dispersion 220 and the second dispersion 250 may be equal, but the difference between the strands embedded in the sheath pipe in consideration of the use environment, such as the use of an odd number of strands, may be used. It is desirable to maintain the level at around 20% of (20). That is, the number of strands passing through the first guide hole 222 is preferably 40% to 60% of the sum of the number of strands passing through the first guide hole 222 and the second guide hole 252.

Meanwhile, according to another embodiment 200 ′ of the present invention, as shown in FIG. 8, the extension tube 240 ′ becomes larger in cross section toward the end of the strand 20 similarly to the connection tube 210. Expansion region Ex may be provided. As a result, the second strand 20b passing through the second guide hole 252 of the second dispersion 250 may be disposed to be spaced farther apart.

Meanwhile, according to another embodiment 200 ″ of the present invention, as shown in FIG. 9, an extension sheath tube 230 similar to the extension tube 240 is connected from the first dispersion 220 to the extension sheath. An extension tube 240 having an expansion region Ex may be connected to the tube 230. As such, when the extension sheath tube 230 is connected, the length L of the extension sheath tube 230 is connected. 1 m to 6 m long to distribute the fixed anchorage of one bundle of strands longitudinally to two or more different positions, increasing the efficiency of compressive prestressing and bending with external force at a lower dose. The effect of resisting the moment can be obtained.

According to one embodiment of the present invention, there is provided a steel composite girder or a concrete girder for a bridge including a concrete portion to which the strand wire dispersing device 100, 200, 200 ', 200 "according to the present invention configured as described above is applied. do.

1A and 1B, the other end E2 of the concrete part 12 across the girder center from one end E1 of the concrete part 12 synthesized in the steel beam 11 is not shown. The sheath tube 20s is installed at any one or more positions which are installed up to the first position which does not reach the end, or do not reach one end of the concrete portion across the girder center from the other end of the concrete portion, and a stranded wire (20s) is provided in the sheath tube 20s. 20) can be installed.

Here, the strand is exposed at one end to form a movable anchorage, and the other end is formed with a bulbous portion (20x) to form a fixed anchorage fixed integrally with the concrete portion (12). Here, the strand wire buried dispersing device (100, 200, 200 ', 200 ") may be applied to the bulging portion (20x) is integrally fixed to the concrete portion (12).

In the above, the preferred embodiments of the present invention have been described by way of example, but the scope of the present invention is not limited to these specific embodiments, and may be appropriately changed within the scope described in the claims.

In the embodiment shown in the drawings, the pre-strand girders distributed fixed anchoring device (100, 200, ...) of the present invention in the configuration to form a fixed fixing portion of the strand 20 in the concrete portion of the composite girder For example, the present invention is not limited thereto, and the present invention may be applied to a bridge girder having steel beams and concrete parts having various cross sections and shapes, and may be applied to a bridge concrete girder formed of reinforced concrete as a main material. .

9: Bridge girder 11: Steel beam
12: concrete part
100, 200, 200 ', 200 ": Strand Decentralized Fixed Fixture
110, 210: connection tube 120, 220: first dispersion
122: guide 222: first guide
252: second guide 230: second sheath hall
240: extension tube 250: second dispersion

Claims (15)

A strand wire embedding dispersing device for fixedly installing one end of a plurality of stranded wires for introducing prestress to a girder for bridges to be embedded in a concrete part of the girder,
A first dispersion in which the inside of the sheath pipe surrounding the strand is wrapped in the concrete part with the outside, and the guide hole is formed to guide the strand by passing the strand by one;
An extension tube extending toward one end of the strand in communication with a central portion of the first dispersion and receiving a second strand extending through a central through hole of the first dispersion;
A second dispersion body coupled to an end of the extension tube and having a second guide hole for guiding the strands one by one;
Includes, the bubbling portion formed at one end of the stranded wire is embedded in the concrete portion outside of the first dispersion,
The first dispersion has a central through-hole formed in the central portion, the second strand is a part of the stranded wire extending through the central through-hole distributed stranded fixed anchorage device for prestress girders.
The method of claim 1,
A connection tube coupled to the sheath tube surrounding the strand in the concrete part and receiving the strand wire exposed to the outside of the sheath tube;
It further comprises, wherein the first dispersion is stranded distributed fixed fixing device for prestress girders, characterized in that coupled to the end of the connecting tube.
The method of claim 2,
Wherein the connection tube is a strand wire distributed fixed anchoring device for the prestressed girder, characterized in that the area is formed so that the cross section is gradually increased toward the end of the strand.
The method of claim 3,
The guide line distributed fixed anchoring device for the prestressed girder according to claim 1, wherein the guide hole of the first dispersion includes a circular shape distributed along an edge of the first dispersion.
The method of claim 1,
The guide hole distributed strand fixing type fixing device for the prestressed girder, characterized in that the guide hole is formed with an elastic ring in contact with the strand.
delete The method of claim 1,
And the extension tube has a region in which a cross section is gradually increased toward one end of the second strand.
The method of claim 1,
The extension tube is fixed stranded fixed anchorage device for prestressed girders, characterized in that formed in a length of less than 1.0m.
The method of claim 1,
The second guide hole is distributed strand anchorage fixing device for prestress girders, characterized in that it comprises a circular distribution along the edge of the second dispersion.
The method of claim 1,
The second guide hole is a wire strand distributed type fixing device for prestress girders, characterized in that the elastic ring is formed in contact with the strand.
The method of claim 1,
The number of stranded wire passing through the guide hole is a distributed stranded fixed anchoring device for prestressed girder, characterized in that 40% ~ 60% of the sum of the number of stranded wire passing through the guide hole and the second guide hole.
The method of claim 1,
An extension sheath line fixed anchoring device for prestressed girders, wherein an extension sheath tube is formed between the extension tube and the first dispersion.
The method of claim 1,
The guide hole is formed on one side is larger than the other side, the strand strand distributed fixed fixing device for prestress girders, characterized in that the outer ring is in contact with the guide hole is provided in the guide hole.
A bridge girder comprising longitudinally extending concrete portions,
A sheath pipe is installed from the one end of the concrete part to a first position not crossing the other end of the concrete part, and is installed through the sheath pipe from one end of the concrete part, the first position and the other end of the concrete part. In the first site region between the end is provided with a strand formed with a first fixed anchoring part is fixed
The bridge girders are embedded in the concrete part by the strand wire distributed fixed fixing device according to any one of claims 1 to 5 or any one of claims 7 to 13.

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