KR100772657B1 - Tendon assembly - Google Patents

Abstract

A tendon assembly is provided to prevent coatings of second tendons from being damaged even in the multistage tension by placing first and second tendons separately. A tendon assembly comprises a sheath pipe(10), first tendons(20), second tendons(30), and a relative position fixing unit(35). The sheath pipe is embedded in girders. The first tendons have two ends exposed to two sides of the girder respectively, and a center part having tendons placed in the sheath pipe. The second tendons have tendons(31) placed to the sheath pipe in parallel, and coatings(32) shielding outer peripheral surfaces of the tendons from the outside. The relative position fixing unit fixes the relative position for the sheath pipe of the second tendon. Two ends of the tendons are fixed to the girders by fixing devices. The fixing devices have mounting plates having second through holes, first wedges fixing the first tendons, covers, and second wedges.

Description

Tendon Assembly

1 is a view for explaining the arrangement of the tension member and the sheath pipe of the prestressed concrete girder.

2 is a view for explaining a fixing device exposed to the outside of the prestressed concrete girder.

3 and 4 are diagrams for explaining examples of the arrangement of the tension member used in the conventional multi-stage prestressed introduction.

5 is a view for explaining the arrangement of the tension member according to an embodiment of the present invention.

6 is a view for explaining an example of a fixing device for fixing the tension members shown in FIG.

7 is a cross-sectional view of the fixing device shown in FIG.

** Explanation of symbols for the main parts of the drawing **

10: Sheath Hall 20: First Tendon

30: second tendon 31: tension material

32: sheath 35: relative position fixing means

40: fixing device

The present invention relates to a tendon assembly for embedding in a girder of a bridge and prestressing the girder of the bridge. More particularly, the present invention relates to a tendon assembly and a non-adhesive tensioning member having a sheathing insulated from each other so as not to interfere with each other. Thus, a tendon assembly is provided to allow tensioning of a general tension material first, and then retensioning without loss of the tension material with the coating even when the tensioning material with the coating is re-tensioned during the construction of the bridge or after the construction is completed.

Prestressed concrete structure, as is well known, refers to a concrete structure that is pre-tensioned by the tendon to resist the load on the concrete structure. In general, the girder of the bridge is formed of such prestressed concrete, as shown in Figure 1 to apply the prestress, the tension member (1) and the sheath tube (2) for receiving the tension member, the girder after applying tension to the tension member ( A fixing device 3 or the like for fixing to 100 is used. In the drawing, a state in which one strand of tension material 1 is accommodated in one sheath tube 2 for convenience of illustration, but in reality, several strands of tension material are accommodated in each of the several sheath tubes.

In the past, the tension material was once tensioned during construction of the girders and there was no additional tension, but recently, a so-called multi-level tensioning method has been implemented in which the construction is completed as well as during the construction and additional tension is applied to the girders during the use of the bridge.

In the case of tensioning the tensioning material only once, the tensioning material has no separate coating, and so-called adhesive tensioning material is used in which the tensioning material is brought into direct contact with the tensioning material after the tensioning force is introduced. However, in the case of adherent tensioning material, it is fixed by the grouting material, so to introduce additional tensioning force, a so-called non-adhesive tensioning material having a covering surrounding the outer circumference of the tensioning material is used, so that the tensioning material does not come into direct contact with the grouting material. It should be possible to introduce tension.

In order to implement this multi-stage tensioning method, it is necessary to use the fixing device 5 exposed to the side of the end of the girder 100, as described in Korean Patent Registration No. 10-0554026, and this configuration is briefly illustrated in FIG. have. In the case of using the fixing device 3 at the end face of the girder, since there is not a sufficient working space for tensioning the tension member between the end faces in the part where the girder is connected to each other, the exposed fixing device 5 is used. Either by adhering the non-adhesive tension material and the non-adhesive tension material, or by fixing only the non-adhesive tension material, further tension of the tension material is possible.

As described above, a technology in which an adhesive tension material and a non-adhesion tension material is used in combination is disclosed in Korean Patent Registration No. 10-0420367. 3 and 4 are examples of such conventional tensioning arrangements. Conventionally, as shown in FIG. 3, conventionally, a sheath tube 2 is used by using an attachable tension member 1a and a non-adhesive tension member 1b in combination, or as shown in FIG. 4. Only the tension member 1b was inserted and used.

However, the adhesive tension member 1a and the non-adhesive tension member 1b are mixedly disposed in one sheath tube, the attachment tension member 1a is first tensioned and fixed, and then the non-adhesive tension member 1b is subsequently added. In case of tension, the coating of the non-adhesive tension member 1b may be damaged due to the friction generated during the tension of the adherent tension member 1a. If the coating of the non-adhesive tensioning material 1b is damaged, the grouting material and the non-adhesive tensioning material 1b come into direct contact with each other, and as a result, the non-adhesive tensioning material 1b is fixed by the grouting material, thereby introducing tension in the future. You will not be able to.

In addition, when arranging the tension members 1a and 1b in the sheath tube 2, even when the arrangement is specifically specified, the arrangement is disturbed by the tension force in the process of tensioning the attachment tension member 1a, and thus the tension members ( 1a, 1b) are arranged irregularly. As such, when the tension members 1a and 1b are irregularly arranged, first, the frictional force acting between the tensioned attached tension member 1a and the non-adhesive tension member 1b appears differently, so that the non-adhesive tension member 1b is later added. When straining, there is also a problem that may occur in addition to the problem that the tension force to be introduced to the non-adhesive tension member (1b) in the design process and the tension force of the non-adhesive tension member (1b) actually acted.

The present invention has been made to solve the above-described problems, by separating the non-adhesive tension material and the non-adhesive tension material for the multi-stage tension, even when using a non-adhesive and non-adhesive tension material mixed, non-adhesive It is an object of the present invention to provide a tendon assembly which is capable of providing a constant tension force to the non-adhesive tension material without damaging the coating of the tension material.

In order to achieve the above object, the present invention,

A tendon assembly used to introduce prestress into the girder of a prestressed bridge,

Sheath pipe embedded in the inside of the girder,

Both ends are exposed to both sides of the girder, the center portion of the first tendon including a tension member disposed inside the sheath tube,

Both ends are respectively exposed to both sides of the girder, the center portion of the girder in the outer side of the sheath tube with a tension member disposed in parallel with the sheath tube, the second having a sheath to shield the outer peripheral surface of the tension member from the outside It provides a tendon assembly comprising a tendon.

The second tendon is preferably disposed below the sheath tube.

It is preferable to further comprise a relative position fixing means for fixing the relative position of the second tendon with respect to the sheath tube.

It is preferable that the said tension material is a stranded wire.

Both ends of the tension member of the first tendon and the second tendon are fixed to each girder by a fixing device,

The fixing device,

A fixing plate fixed to both ends of the girder and having a first through hole through which an end of the first steel wire passes and a second through hole through which ends of the tension member of the second steel wire pass;

A first wedge for fixing the tension members passed through the first through hole by being fitted into the first through hole in a state in which the outer circumferential surface of the end portion of the tension member of the first tendon is in contact with the inner circumferential face thereof;

A third through hole for passing the tension member of the second tendon is formed, and includes a cover for blocking an end of the tension member of the first tendon and the first wedge from the outside;

And a second wedge for fixing the tension members passed through the second through hole and the third through hole by being inserted into the third through hole in a state in which the outer circumferential surface of the end portion of the tension member of the second tendon is in contact with the inner circumferential face thereof. desirable.

Hereinafter, a configuration of an embodiment of the present invention will be described with reference to the drawings.

5 is a view for explaining the arrangement of the tension member according to an embodiment of the present invention, Figure 6 is a view for explaining an example of a fixing device for fixing the tension member shown in Figure 5, Figure 7 is shown in Figure 6 Section of a fixed fixing device.

The tendon assembly according to an embodiment of the present invention is used to introduce prestress into a girder of a prestressed bridge, and includes a sheath tube 10, a first tendon 20, a second tendon 30, and a relative fixing means. (35), and has the property of being fixed by one fixing device.

The sheath tube 10 is embedded in the girder 100, and is generally buried in a parabolic shape. The sheath tube 10 may use a corrugated tube-shaped tube mainly used in the field.

The first tendon 20 is a so-called adhesive tension material without a coating, and in this embodiment, a stranded wire made by twisting a plurality of strands is used.

Both ends of the first tendon 20 are exposed to the outside of the girder 100 through fixing devices exposed to the outside of the both ends of the girder 100 as shown in FIG. It is arranged inside the sheath tube 10.

The second tendon 30 is a so-called non-tensioning tension member having a tension member 31 that is a strand and a sheath 32 that shields the outer circumferential surface of the tension member 31 from the outside, that is, covers the outer circumferential surface of the tension member 31. . The tension member 31 and the sheath 32 are filled with grease (not shown), and when the tension force is introduced into the tension member 31 inside the sheath 32, the tension member 31 is covered with the sheath 32. Make sure you move around smoothly.

Both ends of the second tendon 30 are exposed to the outside of the girder 100 through fixing devices exposed to the outside of both end portions of the girder 100, similarly to the first tendon 20, and a central portion thereof. The inner side of the girder 100 is arranged side by side with the sheath tube 10 on the outside of the sheath tube 10, in this embodiment the second tendon 30 is disposed below the sheath tube 10 It is.

The relative position fixing means 35 is for fixing the relative position of the second tendon 30 with respect to the sheath tube 10, and is a thin wire in this embodiment. Using a thin wire wrapped around the sheath tube 10 and the second tendon 30 is fixed. The relative position fixing means 35 may be provided in plural at regular intervals along the longitudinal direction of the sheath tube 10.

Meanwhile, the first tendon 20 and the second tendon 30 are respectively fixed by one fixing device 40.

The fixing device 40 includes a fixing plate 41, a first wedge 42, a cover 43, and a second wedge 44.

The fixing plate 41 is fixed to both ends of the girder 100, respectively, and the first through hole 411 through which the end of the first tendon 10 passes and the second through hole through which the second tendon passes ( 412).

The first wedge 42 is fitted into the first through-hole 411 in contact with the outer circumferential surface of the end of the first tendon 10 on its inner circumferential surface, and is composed of three segments as shown in FIG. The first tendon 10 passing through the first through hole 411 is fixed by the frictional force between the inner circumferential surface of the first wedge 42 and the outer circumferential surface of the first tendon.

The cover 43 includes a third through hole 421 through which the tension member 31 of the second tendon 30 passes, and an end portion of the first tendon 10 and the first wedge 42. From the outside.

The second wedge 44 is fitted into the third through hole 421 in a state in which the outer circumferential surface of the end portion of the tension member 31 of the second tendon 30 is in contact with the inner circumferential surface thereof, so that the second through hole 412 and Fixing the tension member (31) passed through the third through hole (413). The second wedge 44 is also composed of three segments as shown in FIG.

The third through hole 421 is formed in the cover. The third through hole 421 is located at a position corresponding to the position of the second through hole 412, and the tension member of the second tendon 30 passing through the second through hole 412 passes through the third through hole. Through the ball 421 to be exposed to the outside. Since the third through hole 421 formed by such a shape is formed in the cover 43, it protrudes in the longitudinal direction of the girder 100 compared with the first through hole 411 formed in the fixing plate 41. This structure is advantageous when applying a tension force to the tension member 31 of the second tendon 30, for the following reasons.

The tension member 31 of the second tendon 30 is tensioned when the tension is introduced to the first tendon 10 and is settled, and later, when the secondary tension is applied, the third through hole 421 and the first through When the end surface of the ball 411 is formed on the same plane, the interference between the tip of the hydraulic jack used to tension the tension member 31 of the second tendon 30 and the end of the first tendon 20 Occurs. In order to prevent such interference, the position of the first through hole 411 through which the first tendon 20 passes and the second through hole 412 through which the tension member 31 of the second tendon 30 passes through The position of the three through holes 421 should be spaced apart by a predetermined distance or more, and by forming the third through holes 421 in the cover 43, the second tendons 30 exposed through the third through holes 421. In the case where the tension member 31 of) is brought into contact with the front end of the hydraulic jack, interference with the end of the first tendon 20 does not occur. In order to prevent interference between the tension member 31 of the first tendon 20 and the second tendon 30, the interval between the first through hole 411, the second through hole 412, and the third through hole 421 is fixed. In order to install a large fixing plate, a large fixing plate is required. In order to install a large fixing plate, an increase in material cost and manufacturing cost is required. In the case of fixing in the above-described manner, the size of the fixing plate can be reduced. And it will be possible to reduce the production cost.

Four third through holes 421 are formed on the drawing, and the third through holes 421 are formed on one plate, but the number of third through holes 421 is determined by the number of second tendons 30. It may be formed to fit, it does not have to be formed on one plate, each may be formed on a separate plate.

Hereinafter, the functions, functions, and effects of the components of the above-described embodiment will be described.

The sheath tube 10 accommodates the first tendon 20 therein to protect the received first tendon 20 from moisture, salt, oxygen, or external shock, and guides the position of the first tendon 20. .

After tensioning the first tendon 20 accommodated in the sheath tube 10, the remaining space therein, that is, the space not occupied by the first tendon 20 is filled with a grouting material such as cement paste. The first tendon 20 to protect the moisture from the concrete which forms the girder 100 from the flaw that may occur in the sheath tube 10, etc., and firmly fix the first tendon 20.

The first tendon 20 and the second tendon 30 are used to introduce the prestress into the girder 100. However, the tension times of the first tendon 20 and the second tendon 30 are different, the first tendon 20 after the girder 100 is mounted on the piers after the slab which is the upper structure of the girder 100 is formed It is used at the time of introduction of the secondary prestress to be carried out, and the second tendon 30 decreases the prestress by the first tendon 20 as time passes in use after the construction of the bridge is completed, so that additional prestress is introduced. It is used to introduce tertiary prestressing or the like performed when necessary.

The second tendon 30 is provided with a sheath 32 in addition to the tension member 31, and since the concrete forming the girder 100 and the tension member 31 are separated from each other by the sheath 32, the above-described tertiary prestress. The introduction of is possible.

Unlike the conventional case, the second tendon 30 is separated from the sheath tube 10 in which the first tendon 20 is disposed, so that the coating of the second tendon 30 is damaged during the introduction of the first prestress. There is no problem, such as that, the relative position with the sheath tube 10 by the relative position fixing means 35 is fixed, in the manufacturing process of the girder 100 in a concrete position in the concrete of the girder 100 It becomes possible.

The second tendon 30 is located in the lower portion of the sheath tube 10, in the case of the lower portion is provided with some protection by the sheath tube 10 in the process of pouring concrete to manufacture the girder 100. Since it is received, there is an advantage that the change of the position is less, there is also an advantage of fixing the relative position using the relative position fixing means 35 means to the sheath tube 10 is fixed first installed.

By fixing the relative position of the second tendon 30 with respect to the sheath tube 10 in the relative position fixing means 35, the arrangement of the concrete in which the arrangement of the second tendon 30 forms the girder 100 is performed. To prevent it from moving away from the original design.

In the above, the embodiment in which the stranded wire is used as the tension member has been described, but the tension member is not necessarily limited to the stranded wire, and high-strength tension members such as carbon fibers and aramid fibers may be used in addition to the stranded wire.

In the above description of the embodiment in which the second tendon is disposed below the sheath tube, it is not necessary to have such a position, and it may be installed on the upper side, the left side, or the right side of the second sheath tube according to the site situation. It will be apparent to those skilled in the art.

In the above, the embodiment having the relative position fixing means has been described, but the above-described relative position fixing means is not necessarily provided, and even if the relative position fixing means is not included in the technical idea of the present invention.

Although the preferred embodiments of the present invention have been described above, the technical spirit of the present invention is not limited to the described embodiments, and various forms of tendon assemblies can be realized within a range that does not violate the technical idea of the present invention. Do.

As described above, according to the present invention, by arranging the first tendon and the second tendon in isolation from each other, a tendon assembly capable of being efficiently tensioned without problems such as damage to the coating of the second tendon even in the case of tension in multiple stages. Can be provided.

Claims (5)

delete delete delete delete A tendon assembly used to introduce prestress into the girder of a prestressed bridge, Sheath pipe embedded in the inside of the girder, Both ends are exposed to both sides of the girder, the center portion of the first tendon including a tension member disposed inside the sheath tube, Both ends are respectively exposed to both sides of the girder, the center portion of the girder in the outer side of the sheath tube with a tension member disposed in parallel with the sheath tube, the second having a sheath to shield the outer peripheral surface of the tension member from the outside Tendon, Relative position fixing means for fixing the relative position of the second tendon with respect to the sheath tube; Both ends of the tension member of the first tendon and the second tendon are fixed to each girder by a fixing device, The fixing device, A fixing plate fixed to both ends of the girder and having a first through hole through which an end of the first steel wire passes and a second through hole through which ends of the tension member of the second steel wire pass; A first wedge for fixing the first tendon passed through the first through hole by being inserted into the first through hole in a state in which the outer circumferential surface of the end portion of the first tendon is in contact with the inner circumferential face; A third through hole for passing the tension member of the second tendon is formed, and includes a cover for blocking an end of the tension member of the first tendon and the first wedge from the outside; And a second wedge for fixing the tension members passed through the second through hole and the third through hole in a state in which the outer circumferential surface of the end portion of the tension member of the second tendon is in contact with the inner circumferential surface thereof. Tendon assembly.

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