KR20090041017A - Anchorage apparatus for frp tendon by sleeve with opening and installation method of the same - Google Patents

Abstract

An anchorage device for FRP tendon using a cutting sleeve is provided that the anchorage of the FRP tendon is performed regardless of an anchoring position. An anchorage device for FRP tendon using a cutting sleeve comprises an anchoring mold(100), an FRP tendon(200) which is inserted to the inside of the anchoring mold and is settled, and a wedge(300) which is installed in the displacement outer circumference of sleeve side and in which the FRP tendon is settled the anchoring mold. An open cut sleeve(400) in which a plurality of cutting grooves(S) are formed along the longitudinal direction is installed between the FRP tendon and wedge.

Description

ANCHORAGE APPARATUS FOR FRP TENDON BY SLEEVE WITH OPENING AND INSTALLATION METHOD OF THE SAME}

The present invention relates to a fixing device for FRP tension material using an incision sleeve, and more specifically, more stable prestress in consideration of the structural characteristics of the FRP tension material having high tensile strength in the longitudinal direction and vulnerable to local stress and shear stress. The present invention relates to a fixing device for a FRP tension member provided with a sleeve to be introduced into a structure, and a construction method thereof.

In general, PS steel wire (PC tendon) is the main material of tension material used to introduce prestress to concrete structures, but recently, prestress is introduced by using FRP tension material made of new material such as carbon fiber material or glass fiber material. Is being researched and developed. A representative example is FRP tension material using carbon fiber reinforced composite material (CFRP).

When the tension force is to be introduced by using the FRP tension member, first, a fixing device is installed in a concrete structure requiring tension force introduction, and the FRP tension material is fixed to the fixing device after tension.

The fixing device is, for example, formed in a cylindrical shape as shown in Figure 1 to be pre-mounted on both ends of the concrete structure (A) and the fixing mold 10 formed inside the cone-shaped hollow portion, the inside of the concrete structure is fixed at both ends The FRP tension member 20 is installed to extend through the mold 10, and wraps the extended end of the FRP tension member 20 to restrain the tension force introduced into the FRP tension member 20. It is configured to include a cone-shaped wedge 30 is fitted fitted in the cone-shaped hollow portion.

At this time, when the tension force introduced into the FRP tension member 20 is released, the FRP tension member 20 is bitten by the fixing mold 10 by the cone-shaped wedge 30 and its position is constrained so that the tension force introduced into the FRP tension member 20. This can be restrained.

Accordingly, when the cone-shaped wedge 30 is bitten by the fixing mold 10, a significant amount of tightening force and shear stress are generated in the FRP tension member 20.

However, the FRP tension member 20 has a high tensile strength in the longitudinal direction as a one-way tension member, but because it is vulnerable to local stress and shear stress, by the local tightening and shear stress applied by the wedge 30 Its cross section is easily damaged,

Finally, since the FRP tension member 20 frequently breaks before reaching the maximum tensile strength of the FRP tension member 20, there is a problem that it is impossible to apply a conventional fixing device as it is.

2 and 3 by pressing the cylindrical thin sleeve 40 to the outer peripheral surface of the FRP tension member 20 in advance so that the tightening force applied to the FRP tension member 20 by the wedge 30 is dispersed by the FRP tension member ( A fixing device using a sleeve has been proposed which prevents 20) from being damaged by local tightening and shear stresses.

The fixing device using the sleeve is a cylindrical mold 10, FRP tension member 20, FRP tension member with a cylindrical thin sleeve 40, the sleeve 40 is attached to the outer circumferential surface of the FRP tension member 20 in advance It is comprised including the wedge 30 formed in the cone shape so that the 20 may be bitten and fixed by the fixing mold 10. As shown in FIG.

The fixing device using the sleeve 40 as described above is that the fixing of the FRP tension member 20 is dependent on the friction force between the FRP tension member 20 and the sleeve 40 and between the sleeve 40 and the wedge 30 It can be seen that, in particular, in order to secure a sufficient friction between the FRP tension member 20 and the sleeve 40, the sleeve 40 is installed in the form of pressing in advance in the FRP tension member 20.

The sleeve 40 is installed to be compressed to the FRP tension member 20 by various types of compression apparatuses, and generally uses a steel pipe having a thickness of about 0.5 mm.

In this case, when the thickness of the sleeve 40 is too thick, when the compressive force acts on the sleeve 40, the sleeve 40 is not evenly pressed against the FRP tension member 20 due to the rigidity of the sleeve 40. , The FRP tension member 20 and the sleeve 40 may not result in sufficient contact with each other,

On the contrary, when the thickness of the sleeve 40 is thin, it is easy to squeeze the FRP tension member 20, but the sleeve has a moderately thin thickness because the FRP tension member 20 may be easily damaged by the tightening force of the cone-shaped wedge 30. (40) Use becomes very important

As such, there is a problem in that the limited use of the thickness of the sleeve may be very cumbersome, and there is a disadvantage in that the efficiency and economic efficiency of the sleeve installation have to be added since a model for compressing the sleeve to the FRP tension member in advance regardless of the thickness.

In the present invention, the fixing mold, the FRP tension member, the FRP tension member fixing device comprising a wedge configured to fix the FRP tension member in the fixing mold, while the FRP tension member is not damaged by the tightening force by the wedge, while the FRP tension member In order to ensure sufficient friction between the wedge and the wedge to increase the fixing performance of the FRP tension member, and also to solve the provision of the fixing device for the FRP tension member with a sleeve that can be installed without regard to the fixing portion of the FRP tension member It is a task.

The present invention, in order to achieve the above technical problem, in the fixing device for the FRP tension member configured to include a wedge for fixing the fixing mold, the FRP tension member, the FRP tension member in the fixing mold, incision groove between the FRP tension member and the wedge A plurality of cutaway sleeves were formed.

FRP tension member fixing device using a cutaway sleeve according to the invention

According to the geometrical characteristics of the fixing mold and wedge (cone hollow and cone-shaped wedge installed in the cone hollow), the tightening force applied to the FRP tension member can be effectively distributed through the incision sleeve to prevent local damage of the FRP tension member. Can be,

Compared with the non-incision sleeve, the incision sleeve can effectively secure the frictional force with the FRP tension member, thereby increasing the fixing performance of the FRP tension member, and it is not necessary to pre-squeeze the incision sleeve in the FRP tension member. It is possible to provide a fixing device for the FRP tension material which is efficient and efficient,

In addition, the installation position of the incision sleeve can be easily adjusted to facilitate the installation of the fixing device of the FRP tension material.

BRIEF DESCRIPTION OF DRAWINGS To describe the present invention more clearly and easily, the following describes the best embodiments of the present invention in detail with reference to the accompanying drawings, and embodiments according to the present invention may be modified in various other forms, and thus the scope of the present invention. Is not limited to the embodiment described below.

FRP tension member fixing device using a cutaway sleeve according to the present invention is an FRP tension member, a wedge formed in a cone shape to fix the FRP tension member, a plurality of incision sleeves formed in the longitudinal direction is installed between the FRP tension member and the wedge And a fixing mold in which a cone-shaped hollow portion is formed so that the wedge is inserted and fixed, which will be described in detail with reference to FIGS. 5, 6A to 6C, and 7A to 7C.

The FRP tension member 200 inserted into the fixing mold 100 and fixed therein has excellent tensile strength and a carbon fiber material having a low risk of relaxation and corrosion that decreases in tensile strength as time passes after the tension force is introduced. The glass fiber material is used in the form of a long round rod or rope, and a representative example thereof may be a tension material using a carbon fiber reinforced composite material (CFRP).

The fixing portion of the FRP tension member 200 is inserted into the incision sleeve 400 formed with a plurality of incision grooves S in the longitudinal direction (longitudinal direction) as shown in FIG. 5, which will be described in detail later. .

A wedge 300 is installed on the outer circumferential surface of the cutaway sleeve 400 as shown in FIGS. 5, 6, and 7.

The wedge 300 may be applied to the FRP tension member 200 by applying a tightening force formed in the shape of a cone formed with a hollow portion so that the FRP tension member 200 is fixed to the fixing mold 100.

At this time, the inner diameter of the wedge 300, that is, the diameter of the hollow portion is smaller than the outer diameter of the incision sleeve 400 in order to firmly fix the FRP tension member 200, the incision during tension and fixation of the FRP tension member 200 The outer diameter and wedge of the cutaway sleeve 400 to prevent local stress concentration and damage to the FRP tension member 200 caused by the difference in curvature between the outer diameter of the shaped sleeve 400 and the inner diameter of the wedge 300. It is desirable to equalize or very similar the curvature of the inner diameter of (300),

In the state where the wedge 300 is installed before tensioning the FRP tension member 200, two or three separation grooves are formed in the body so that the wedge 300 by the separation groove when the FRP tension member 200 is tensioned. As the spacing between the respective portions of the reducing the FRP tension member 200 can be delivered to the tightening force. (This is introduced in the Republic of Korea Patent Publication (Special Publication No. 2003-59048) that the wedge for the FRP tension member is introduced.)

In addition, the inner circumferential surface of the wedge 300 may increase the attachment force with the cutaway sleeve 400 and a thread may be formed in a direction perpendicular to the length of the ruler.

In this case, as well as the friction force between the wedge 300 and the cutaway sleeve 400, the adhesion can be further increased by the mechanical engagement by the thread.

The wedge 300 is inserted into the fixing mold 100, the fixing mold 100 is a cylindrical member whose outer diameter is larger than the outer diameter of the wedge 300 is generally made of steel, the inside of the cone-shaped wedge Tapered to insert the 300 is formed in the hollow portion is reduced in diameter so that the wedge 300 is tightly fitted, inserted into the hollow portion.

At this time, when the tension force is introduced into the FRP tension member 200 and released, the cone-shaped wedge 300 slips along the inner circumferential surface of the hollow portion of the cone shape of the fixing mold 100 while being in the central axis direction of the FRP tension member 200. As the tightening force is generated, the size of the tightening force is proportional to the length of the wedge 300 or the fixing mold 100, and thus the total length of the wedge may be adjusted according to the required tension and tightening force.

Between the FRP tension member 200 and the wedge 300 is provided with a cut-away sleeve 400 formed with a plurality of cut grooves (S) in the longitudinal direction, there is a technical feature of the present invention will be described in detail below.

The cutaway sleeve 400 has an inner diameter slightly larger than the diameter of the FRP tension member 200, and its length is longer than the length of the wedge 300 so that the tightening force transmitted from the wedge 300 is the FRP tension member 200. As a member in the form of a pipe to be transmitted while being distributed to the tube, it is generally manufactured using a thin steel pipe, the thickness of which is rigid enough not to damage the FRP tension member 200 by the tightening force in the direction of the central axis when the tension is introduced. It has a predetermined thickness to have.

That is, the cutaway sleeve 400 has a cutout groove S formed in the longitudinal direction as shown in FIG. 5, and the cutaway groove S is formed to have a predetermined interval in the circumferential direction of the sleeve, so that the sleeve The incision grooves act in the form of a plurality of separate sleeves.

6A to 6C, when the tightening force in the central axis direction according to the tension force is applied by the wedge, the tightening force is distributed to the sleeves separated by the incision grooves, and the respective sleeves are respectively divided into the FRP tension members 200. Since the sleeve can be in close contact with the sleeve of the thin steel pipe, the frictional force between the FRP tension member 200 and the sleeve can be increased while preventing the local breakage of the FRP tension member 200, so that the fixing performance of the FRP tension member 200 can be improved. It can be seen that.

In addition, since the cutaway sleeve 400 may be closely contacted by the tightening force, there is no need to compress the FRP tension member 200 in advance, and thus the function of the cutaway sleeve 400 may be performed without regard to the fixing portion of the FRP tension member 200.

That is, when a large tension force is required, when using a sleeve made of a thin steel pipe in which the incision groove is not formed in the FRP tension member 200 as in the prior art, it is necessary to increase the thickness of the sleeve because local breakdown of the FRP tension member is concerned. do.

However, in this case, the tightening force transmitted by the wedge 300 does not act on the FRP tension member 200 due to the stiffness of the thickened sleeve surrounding the FRP tension member 200, so that the friction force between the sleeve and the FRP tension member 200 is reduced. It is not generated is not able to introduce tension to the FRP tension member 200.

Therefore, in order to secure the friction force between the FRP tension member 200 and the sleeve, it is necessary to compress by applying a force in the central axis direction to the sleeve surrounding the FRP tension member 200 before the first tension force is introduced,

When using a cutaway sleeve 400 formed with a plurality of cutout grooves S in the longitudinal direction, even when using a cutaway sleeve 400 by using a rather thick steel pipe due to the need for introducing a larger tension, the tightening force due to the wedge is the FRP tension member ( It is effectively dispersed in 200) to prevent local breakage of the FRP tension member,

Introduced tightening force is enough to compress the FRP tension member and the incision sleeve through the incision sleeves in the end it is possible to finally introduce sufficient tension force to the FRP tension member 200,

Since the frictional force between the sleeve and the FRP tension member 200 can be secured by the tightening force of the wedge, it is possible to exclude the work to compress the sleeve to the FRP tension member 200 in advance, thereby enabling more economical FRP tension fixing.

Here, the formation of the cutaway groove S in the cutaway sleeve 400 is not formed over the entire length of the cutaway sleeve 400.

This is to facilitate the handling and installation by having the cutaway sleeve 400 as a member, the cut groove (S) is a position spaced a predetermined distance from one end of the cutaway sleeve 400 as shown in FIG. It is formed in the longitudinal direction from the other end to the circumferential direction, so that a large number is formed at regular intervals.

That is, a predetermined portion of one end of the cutaway sleeve 400 is to maintain a pipe (pipe) shape, and to form a cutout groove (S) in the remaining portion so that the cutaway sleeve 400 can exist as one member.

At this time, the portion where the wedge 300 is in contact with the cutaway sleeve 400 is a cutaway groove S of the cutaway sleeve 400 so that the cutaway sleeve 400 may be in close contact with the FRP tension member 200 by a tightening force. Should be a formed site.

In addition, a fine thread may be further formed on the inner circumferential surface of the cutaway sleeve 400 in a direction perpendicular to the longitudinal direction in order to increase friction with the FRP tension member 200.

However, in this case, the thread formed on the inner circumferential surface of the cutaway sleeve 400 should not be damaged because the FRP tension member 200 should be formed finer than the thread formed on the inner circumferential surface of the wedge 300.

7A and 7B illustrate another embodiment of the cutaway sleeve, wherein the cutaway sleeve 410 of FIG. 7A is positioned from a position in which the cutaway groove S is spaced a predetermined distance from one end of the cutaway sleeve 410. It is formed in the longitudinal direction from the other end of the incision sleeve 410 to a predetermined distance spaced apart, so that a plurality of predetermined intervals in the circumferential direction.

That is, a predetermined portion of both ends of the cutaway sleeve 410 is to maintain a pipe (pipe) shape, and to form a cutout groove (S) in the remaining portion so that the cutaway sleeve 410 can exist as one member.

The cutaway sleeve 420 of FIG. 7B is formed in the longitudinal direction from the position in which the cutaway groove S is spaced a predetermined distance from one end of the cutaway sleeve 420 to the other end, and has an opposite direction in the circumferential direction. The groove (S) and a plurality of iterative intervals to be formed repeatedly.

That is, the 's' shape is formed along the circumferential surface of the cutaway sleeve 420 so that the cutaway sleeve 420 may be present as one member.

Of course, a portion where the cutaway sleeves 410 and 420 are in contact with the wedge 300 is a cutaway groove S in the cutaway sleeves 410 and 420 so that the cutaway sleeves 410 and 420 may be in close contact with the FRP tension member 200 by tightening force. Should be a formed site.

Figure 1 shows a cross-sectional view of a conventional wedge-shaped fixing device.

Figure 2 shows a cross-sectional view of a fixing device using a conventional sleeve.

Figure 3 shows an assembled perspective view of a fixing device using a conventional sleeve.

Figures 4a, 4b and 4c shows a compression flowchart of the sleeve in the fixing device using a conventional sleeve.

Figure 5 shows an assembled perspective view of the fixing device for the FRP tension material using the incision sleeve according to the present invention.

Figures 6a, 6b and 6c shows a close-up flow chart of the cutaway sleeve in the fixing device for the FRP tension material using the cutaway sleeve according to the present invention.

Figures 7a, 7b and 7c shows a perspective view of an embodiment of a fixing device for the FRP tension material using a cutaway sleeve according to the present invention.

<Description of the symbols for the main parts of the drawings>

100: fixing mold 200: FRP tension material

300: Wedge 400,410,420: Cutting sleeve

S: Cutting groove A: Concrete structure

Claims (8)

In the FRP tension member fixing device comprising a FRP tension member, a wedge having a hollow portion to fix the FRP tension member and a fixing mold into which the wedge is inserted and fixed, FRP tension member fixing device using a cutaway sleeve, characterized in that the incision is provided with a plurality of incision sleeve formed in the longitudinal direction in the longitudinal direction between the FRP tension member and the wedge. The method of claim 1, wherein the incision groove of the incision sleeve is formed in the longitudinal direction from the position spaced apart a predetermined distance from one end of the incision sleeve to the other end, a plurality of incisions formed at a predetermined interval in the circumferential direction Fixing device for FRP tension member using sleeve. The method of claim 1, wherein the incision groove of the incision sleeve is formed in the longitudinal direction from a position spaced a predetermined distance from one end of the incision sleeve to a position spaced a predetermined distance from the other end of the incision sleeve, it is constant in the circumferential direction FRP tension member fixing device using a cutaway sleeve, characterized in that formed a plurality of intervals. According to claim 1, wherein the incision groove of the incision sleeve is formed in the longitudinal direction from the position spaced apart a predetermined distance from one end of the incision sleeve to the other end, repeated in a circumferential direction and the incision grooves in the opposite direction in the circumferential direction FRP tension member fixing device using a cutaway sleeve, characterized in that formed by a plurality. Install the fixing mold on the structure, Install the FRP tension member so that both ends penetrate the fixing mold, To the FRP tension member, between the FRP tension member and the wedge is inserted and installed without a pressing force to the incision sleeve formed with a plurality of incision grooves in the longitudinal direction in the form of a tube, And installing a wedge mounted between the FRP tension member and the fixing mold so as to surround the FRP tension member so that the FRP tension member having the cutaway sleeve installed therein is constrained to the fixing mold after the tension. Construction method of fixing device for tension material. The method of claim 5, wherein the incision groove of the incision sleeve is formed in the longitudinal direction from the position spaced apart a predetermined distance from one end of the incision sleeve to the other end, characterized in that a plurality of formed at a predetermined interval in the circumferential direction Construction method of fixing device for FRP tension material using incision sleeve. The method of claim 5, wherein the incision groove of the incision sleeve is formed in the longitudinal direction from a position spaced a predetermined distance from one end of the incision sleeve to a position spaced a predetermined distance from the other end of the incision sleeve, it is constant in the circumferential direction A method of constructing a fixing device for an FRP tension member using a cutaway sleeve, characterized in that a plurality of ones are formed at intervals. According to claim 5, The incision groove of the incision sleeve is formed in the longitudinal direction from the position spaced apart a predetermined distance from one end of the incision sleeve to the other end, repeated in the circumferential direction and at regular intervals in the opposite direction in the circumferential direction Method for constructing a fixing device for the FRP tension material using a cutaway sleeve, characterized in that using a plurality formed.

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