KR20200002526U - Dummy structure for clamping steel strand - Google Patents

Abstract

The present design relates to a dummy structure used when a bundle of strands of stranded wire installed in a cable is tied with a clamp in a cable bridge such as a cable-stayed bridge, and is continuously applied from the outside while the inside of the clamp is loose. It provides a dummy structure for clamping a stranded wire that can greatly reduce the cost of replacement and maintenance by exerting a strong binding force within the clamp. For this purpose, the dummy structure structure for clamping the strands of the present invention is located in a clamp member that wraps around and binds the strands of strands together, and the body fills the space between the clamp member and the strands, or between the strands and strands, and the clamp It is characterized in that it is fixed by pressing together with the stranded wire by the fastening force of the member.

Description

Dummy structure for clamping steel strand}

The present design relates to a dummy structure used when a bundle of strands of strands installed in a cable is tied with a clamp in a cable bridge such as a cable-stayed bridge to hold the shape. More specifically, vibration is continuously generated from the outside while the inside of the clamp is loose. Even when applied, it relates to a dummy structure for clamping a stranded wire that can significantly reduce the cost of replacement and maintenance by exerting a strong binding force within the clamp.

In a cable bridge such as a cable-stayed bridge, a cable supporting the upper plate (bottom plate) of the bridge has a configuration in which a bundle of strands consisting of a plurality of strands is arranged in a tensioned state within a stay pipe.

In addition, the strands of strands arranged in the stay pipe are entirely or individually stretched and then tied and fixed through a clamp to form a cross-sectional shape of a certain shape (eg, a hexagonal cross-section).

In this case, the larger the diameter of the stay pipe forming the outer shell of the cable, the larger the area that receives the wind, and accordingly, the wind load transmitted by the cable increases.Therefore, it is required for the part where the cable is settled on the pylon or upper plate of the bridge. As the resulting strength is increased, it is very disadvantageous in terms of the structure of the entire bridge. Therefore, if the same number of strands are arranged in the stay pipe, it is desirable to reduce the diameter of the stay pipe as much as possible.

On the other hand, in order to reduce the diameter of the stay pipe in order to be less affected by the wind as described above, it is necessary to narrow the spacing of the plurality of strands arranged inside the stay pipe.

That is, although the strands of strands composed of a plurality of strands must be bundled so as to be densely packed together, since it becomes possible to enter the stay pipe, the work of tying the strands of strands is essentially required. In this case, the strands of strands are grouped and tied together through a separate clamp so that the cross section forms a specific shape such as a hexagon.

However, since the number of stranded strands installed in the cable may vary depending on the construction situation of the bridge, such as the location of the cable, for example, if the number of stranded strands is small, it may be difficult to maintain a bundle of strands in a specific shape. .

That is, when the number of strands installed in the cable decreases, the inside of the clamp that binds the strands becomes loose, making it difficult to bundle the strands together in a specific shape.

For this reason, in the past, short-cut pieces of strands of strands left after being used in the field were tied and fixed together with the strands of strands through clamps to maintain the strands in a specific desired shape.

However, when the conventional method as described above is used, the rubber member attached and fixed to the inner surface of the clamp so that it can be compressed and wrapped around the strands of strands and strands of the strands is hardened after a long period of time, and the compression force is lowered, resulting in a loose inner clamp. A losing situation occurs, and this causes a situation in which a piece of stranded wire that was bitten in the clamp is separated from the clamp by its own weight and slides downward along the inner space of the stay pipe. Accordingly, the gap between the strands that were tied through the clamps becomes wider again, making it difficult to maintain the shape, which may eventually lead to a structural problem that is vulnerable to vibration.

In addition, in the case of a strand of stranded wire that is tied and fixed together with a strand of stranded strands in a clamp, a plurality of strands are formed in a state in which a plurality of strands are twisted along the axial direction as in a conventional stranded strand, and corrosion is prevented around the strands of strands. It forms a structure in which a corrosion-preventing rust inhibitor such as grease or wax is filled around the bundle of steel hulls in the sheath, and the temperature increases as in the summer. When the viscosity is lowered, there is a problem in that the rust inhibitor filled around the steel hull of the stranded wire operation flows downward by gravity and flows down to the cable anchorage portion located at the bottom, thereby polluting the surrounding environment.

Patent Registration No. 10-1306973 (2013.09.03) Patent Registration No. 10-1425340 (2014.07.24)

The present design was devised to solve the above problems, and the technical problem to be solved in the present design is that vibration is continuously applied from the outside while the inside of the clamp member is loose due to the hardening of the elastic material that wraps and compresses the strands of strands. It is also to provide a dummy structure structure for clamping a stranded wire that does not require separate replacement work or maintenance by allowing a strong binding force to be exhibited within the clamp member.

Another technical problem to be solved in the present invention is to provide a dummy structure structure for clamping a stranded wire that can prevent contamination around a cable anchorage due to leakage of a rust inhibitor due to external temperature change.

Another technical problem to be solved in the present invention relates to a dummy structure for clamping a stranded wire that can reduce manufacturing cost and improve workability by being readily and easily installed in the field.

The dummy structure for clamping a strand of strand according to the present invention for solving the above technical problem is located in a clamp member that wraps around and binds a strand of strands together, and a body is between the clamp member and the strand, or between the strand and the strand. It is characterized in that it fills the space of and is fixed by pressing together with the stranded wire by the fastening force of the clamp member.

Here, the body may be formed in a hollow rod-like structure made of synthetic resin or metal material or a hollow tubular structure.

In addition, the body may be provided with a clamp member or a locking means for suppressing downward movement of the body by being caught by the adjacent stranded wire portion.

At this time, as the locking means, a bolt having one side coupled to the upper surface of the body and having a hook portion formed on the other side and supported by the upper end of the clamp member may be employed.

In addition, as the locking means, an eye bolt is formed on one side and is fastened to the upper surface of the body, and a binding member that is tied or fixed to a stranded wire or a clamp member portion while being fitted to the ring portion of the eye bolt. Can be employed.

In addition, as the locking means, a through hole formed through the outer surface of the body, and a binding member that is fixed to a stranded wire or a clamp member portion while being inserted into the through hole may be employed.

In addition, as the locking means, an annular groove formed along the periphery of the outer circumferential surface of the body, and a binding member that is fixed to a stranded wire or a clamp member portion while being fitted into the annular groove may be employed.

In addition, as the locking means, a ring member having an annular groove formed along the periphery of the outer circumference of the body and a ring member having a ring shape that is fitted and coupled to the annular groove to form a diameter larger than the diameter of the body may be employed. have.

In addition, as the locking means, an annular protrusion structure formed while protruding around the outer circumferential surface of the body may be employed to form a diameter larger than the diameter of the body.

In addition, as the locking means, a tapered portion structure formed on the outer surface of the body in a shape in which the diameter size gradually decreases from top to bottom may be employed.

According to the dummy structure structure for clamping a stranded strand of the present invention as described above, a clamp member adjacent to the body portion of the dummy structure or a locking means capable of restraining downward movement by being caught on a portion of a strand of stranded strand is provided, which is attached to the inner surface of the clamp member. Even when external force (for example, wind power) is applied to the cable while the elastic material is hardened and the inside is loose, the dummy structure can exert a strong restraining force inside the clamp member, so the shape of the strands of strands is disturbed. Since it is possible to prevent the dummy structure from being separated from the clamp member and falling downward, there is an advantage of reducing the cost of maintenance and replacement of the dummy structure.

In addition, since the dummy structure is formed in a rod-like structure made of a light synthetic resin or metal material, it is easy to manufacture and has the advantage of low manufacturing cost, and its weight is relatively light compared to the existing stranded dummy structure. Since it is less affected by gravity, it has the advantage that it is not easily separated from the clamp member even if a vibration load due to wind power is continuously applied to the cable, and the cable fixing part is damaged due to leakage of rust inhibitors like the existing stranded dummy structure. Since no contamination occurs, there is an advantage of reducing the cost of maintenance of the cable fixing part.

In addition, since the dummy structure has a simple shape structure, it is easy to manufacture, and the cost of manufacturing can be reduced, and there is an advantage of improving workability because it can be easily installed immediately through a simple operation at the cable installation site.

1 is an installation cross-sectional view showing the configuration of the peripheral portion of the cable in which the dummy structure for clamping the stranded wire of the present invention is installed.
2 is a perspective view showing a state in which the dummy structure for clamping the stranded wire of the present invention is installed around the cable anchorage in the pylon part of the bridge.
3 is a cross-sectional view showing a cross-sectional structure of a clamp member portion in which a dummy structure for clamping a stranded wire of the present invention is installed.
4 is an exemplary view showing various embodiments of a dummy structure for clamping a stranded wire according to the present invention.
Figure 5 is a cross-sectional view showing a state in which the dummy structure shown in Figure 4 (a), (b) is installed in the clamp member.
6 is an exemplary view showing another embodiment of the dummy structure of the present invention.
7 is a cross-sectional view showing a state in which the dummy structure shown in FIG. 6 (a), (b), and (c) is installed in a clamp member.
8 is an exemplary view showing another embodiment form of the dummy structure of the present invention.
9 is a cross-sectional view showing a state in which the dummy structure shown in FIG. 8 (a) is installed in the clamp member.
10 is an exemplary view showing another embodiment of the dummy structure of the present invention.
11 is a cross-sectional view showing a state in which the dummy structure shown in FIG. 10(a) is installed in the clamp member.

Hereinafter, preferred embodiments of a dummy structure for clamping a stranded wire according to the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

In addition, terms to be described later are terms set in consideration of functions in the present invention, and since these may vary according to the intention or custom of a producer producing a product, the definition may be made based on the contents throughout the present specification.

First, FIG. 1 is a cross-sectional view showing the configuration of a cable periphery in which a dummy structure for clamping a stranded strand of the present invention is installed, and FIG. 2 is a perspective view showing a state in which a clamp member for tying a bundle of strands is installed around a cable anchorage in the pylon of a bridge to be.

1 and 2, in a cable bridge such as a cable-stayed bridge, a plurality of cables 30 for supporting the load of the upper plate 20 are installed between the pylon 10 and the upper plate 20. In this cable 30, a bundle of strands 32 made of a plurality of strands 31 are disposed inside a stay pipe 34 made of a steel material or a synthetic resin material, so that one end is settled on the top plate 20 and the other One end is fixed to the pylon 10 through tensioning.

And, in the vicinity of the cable fixing unit 60 located in the upper plate 20 part and the cable fixing unit 50 located in the pylon 10 part, a bundle of strands in the cable 30 fixed through each of the cable fixing units 50 and 60 ( A clamp member 40 is installed that binds 32) together and holds it in a certain shape.

The clamp member 40 is formed to have a cylindrical or polygonal shape of a predetermined length so as to wrap the outer periphery of the strands 32 of strands 32, so that the strands 32 are grouped together to have a certain shape.

That is, in the clamp member 40, both sides are symmetrical, one side of the divided two members is hinged to each other, and the other side is formed in a form in which a fastener is coupled, and the strands of strands 32 are wrapped and then fastened with a fastener. It is possible to tie and fix the strands 32 of the strands.

At this time, the inner surface of the clamp member 40 includes an elastic member 42 made of an elastic material such as rubber so that the outer periphery of the strand 32 is elastically adhered to the outer circumference of the strand 32 during the fastening process of the clamp member 40. Attached and fixed.

In addition, a damper 70 for attenuating the vibration of the cable 30 when an external force such as wind power is applied to the cable 30 may be installed on one side of the cable 30.

Meanwhile, FIG. 3 shows a partial cross-sectional structure A-A of FIG. 2, and shows an internal structure in which a bundle of strands 32 is bound through a clamp member 40.

As shown in Figure 3, the strands of strands 32 disposed inside the stay pipe 34 forming the outer shell of the cable 30 are tied together with a plurality of dummy structures 100 through a clamp member 40 It is fixed.

As shown in FIG. 3, the structure of a conventional stranded wire 31 forms a bundle structure in a state in which a plurality of steel hulls 31a are twisted along the axial direction, and corrosion prevention around the bundles of the steel hulls 31a A coating 31b is applied, and a structure in which a corrosion-preventing rust inhibitor 31c such as grease or wax is filled around the bundle of the steel hull 31a in the coating 31b is formed. have.

And, as described above, the dummy structure 100 corresponds to the strand 31 because it is difficult to bundle the strands 32 and maintain a constant shape when the number of strands of the strands bitten in the clamp member 40 is small. It is a structure used to keep one or more dummy structures having a shape with a clamp member 40 together with a bundle of strands 32 to maintain an external shape in a specific shape (a hexagonal shape in the embodiment).

In the past, the method of tying and fixing the strands of strands left over during the cable construction process with the clamp member 40 together with the strands of strands 32 was mainly used, but these strands of strands are not uniform in length, so they are effective in tying together with a clamp member. As the elastic material adhered to the inner surface of the clamp member is hardened after a long time, and vibration is continuously applied while the fixing force is lowered, a piece of heavy stranded wire is separated from the clamp member by its own weight and moves downward along the inside of the stay pipe. In addition, there was a problem of loss, and in addition, the viscosity of the rust inhibitor filled in the pieces of the stranded wire in the summer when the temperature was high was lowered and flowed downward, thereby polluting the environment around the cable anchorage.

In order to improve such conventional problems, in the present invention, at least one dummy structure 100 having a hollow rod-like structure or a hollow tubular structure having a diameter corresponding to the diameter of the stranded wire 31 The strands 32 are tied together with a clamp member 40 so that even when the number of strands of the strands 31 is insufficient, the entire shape of the strands 32 can be maintained in a certain shape. The dummy structure of the structure will be described as an example)

The dummy structure 100 is formed of a light weight material in which the body 110 is made of a light metal material such as aluminum or a synthetic resin material that is the same as the covering material of the stranded wire 31, and a part of the outer edge of the stranded strand 32 or a strand 32 ) It is disposed in the space between the strands 32 and is tied and fixed through the clamp member 40 together.

That is, in the clamp member 40, the dummy structure 100 fills the space between the clamp member 40 and the strand 31 or between the strand 31 and the strand 31, and the clamp member 40 It is compressed together with the strand 32 by the fastening force of and fixed.

In this case, the clamp member 40 that binds the strands 32 is a position close to the cable anchorage 50 of the pylon 10 and the cable anchorage 60 of the upper plate 20 as shown in FIG. Since they are installed on each of the above, the dummy structure 100 as described above may be applied to each clamp member 40 installed at each of these portions, so that the strands of strands 32 can be assembled and fixed to have a specific cross-sectional shape.

4 is a listing of various exemplary embodiments applicable to the actual field in the dummy structure 100 according to the present invention.

First, the dummy structure 100 of the shape shown in (a) of FIG. 4 is formed to have a tapered shape in which the shape of the body 110 gradually decreases in diameter from top to bottom.

That is, the dummy structure 100 shown in FIG. 4 (a) has a tapered portion 112 in a shape whose diameter gradually decreases from top to bottom on the outer surface of the body 110, and the ( As shown in the installation cross-sectional view shown in a), when the strands of strands 32 are bundled and fixed with the clamp member 40, between the clamp member 40 and the strand 31 at the upper side of the clamp member 40 It may be installed in a manner in which the body 110 of the dummy structure 100 is pushed out of the gap space.

In this case, in the dummy structure 100 pressed into the clamp member 40, the upper portion of the body 110 having a large diameter is not pressed between the clamp member 40 and the stranded wire 31, and the clamp member 40 By being caught between the upper end and the stranded wire 31, downward movement is suppressed.

Therefore, the elastic member 42, such as rubber, which is attached to the inner surface of the clamp member 40 to improve the fixing force, is hardened after a long period of time, so that even if vibration is continuously applied from the outside, the tapered body 110 The upper end of the clamp member 40 is caught between the upper end of the clamp member 40 and the strand 31 to prevent downward movement of the dummy structure 100, thereby preventing the dummy structure 100 from being separated from the clamp member 40 and falling downward. can do.

In addition, the shape of the dummy structure 100 shown in (b) of FIG. 4 is a modified example of the dummy structure 100 shown in (a) of FIG. 4, and the tapered portion 112 of the body 110 It shows a structure formed only in the upper part.

That is, a portion of the body 110 of the dummy structure 100 that is closely fixed between the clamp member 40 and the stranded wire 31 is formed in a circular rod shape having the same diameter, and the clamp member 40 and the stranded wire 31 The upper side of the body 110, which is not interdigitated, has a structure in which a tapered portion 112 having a diameter gradually expanding toward the top is formed.

Accordingly, in a state in which the dummy structure 100 is installed as shown in FIG. 5B, the gap between the clamp member 40 and the stranded wire 31 is even when vibration is continuously applied to the cable under the influence of wind. Due to the shape of the tapered portion 112 on the upper body 110 than the area, the dummy structure 100 may be prevented from being separated from the clamp member 40 by moving downward.

In addition, in (c) of FIG. 4, a structure of a dummy structure 100 in which a separate tapered structure is not formed on the outer surface of the body 110 is shown. In the dummy structure 100 according to the present invention, since the material of the body 110 is basically made of a light plastic such as a covering of the stranded wire 31 or a light light metal material such as aluminum, a separate locking means on the outer surface of the body 110 Even if this is not provided, the force to go downward by its own weight is smaller than the restraining force in the clamp member 40, so that downward movement of the dummy structure 100 can be suppressed to a certain level.

That is, the dummy structure 100 itself is made of a material having a light weight, so that it is relatively less affected by gravity compared to the case where a piece of stranded wire having a large weight was used, so that the dummy structure within the clamp member 40 When the restraining force of 100 is maintained to some extent, the dummy structure 100 is not easily separated from the clamp member 40 even if vibration is applied.

Meanwhile, FIG. 6 shows another embodiment of the dummy structure 100 according to the present invention.

First, the dummy structure 100 of the form shown in FIG. 6A has a separate structure-type locking means that can be caught on the upper end of the clamp member 40 at the top of the body 110 having the shape of a circular rod filled with a solid. It is a prepared form.

That is, the dummy structure 100 shown in FIG. 6(a) is a hook part 113 having a bent structure of a'b' shape coupled to the upper surface of the body 110, and the hook part 113 ) Is formed on one side of the male screw portion (113a) is coupled to the female screw portion (111) formed on the upper surface of the body (110), the other side (113b) is extended to the outside of the body (110) to the top of the clamp member (40) It is structured to be able to take.

At this time, the hook part 113 can be managed as a separate part from the body 110, and after fastening the hook part 113 with the body 110 at a construction site, it is tied together with a bundle of strands 32 to clamp It can be fixed with the member 40.

Therefore, as shown in the installation sectional view shown in (a) of FIG. 7, the dummy structure 100 is bound by the clamp member 40 together with the strands of strands 32 and is fixed to the outside of the body 110 One side (113b) of the hook portion (113) extended by being caught on the upper end of the clamp member (40) is supported, so that the dummy structure (100) is continuously applied from the outside while the inside of the clamp member (40) is loose. It is possible to secure a stable restraining force within the clamp member 40.

In this case, the hook part 113 may be formed in various shapes as long as it has a structure that can be effectively caught on the upper end of the clamp member 40 in addition to the'L' shape as described above.

And, the dummy structure 100 shown in (b) of FIG. 6 shows a form in which an eye bolt 114 is coupled to the upper surface of the body 110 as a locking means.

The eye bolt 114 is a structure in which a ring portion 114b is formed at an upper end and a male threaded portion 114a is formed at the lower end, and the male threaded portion 114a is attached to the female threaded portion 111 formed on the upper surface of the body 110. It is joined by fastening.

At this time, a binding member 114d such as a string or a wire is provided in the ring portion 114b of the eye bolt 114 so that the dummy structure 100 can be tied to and fixed to the adjacent strand 31 or clamp member 40. Will be inserted.

Therefore, as shown in the installation cross-sectional view shown in (b) of FIG. 7, the dummy structure 100 together with the strands 32 of strands 32 are tied and fixed with the clamp member 40 and the ring portion of the eye bolt 114 ( A binding member 114d such as a string or a wire may be inserted into the 114b) and wound around the adjacent strands 31 or bundles 32, or may be tied and fixed to the clamp member 40.

When the dummy structure 100 is fixed in this form, the loop portion 114b of the eyebolt 114 and the strand 32 of the eyebolt 114 even when vibration is continuously applied from the outside while the inside of the clamp member 40 is loose Alternatively, since the dummy structure 100 can be restrained from being moved downward through the binding member 114d that binds the clamp members 40, the strands of strands 32 have the original shape within the clamp member 40. By keeping it as it is, it can maintain a bonded state.

In addition, (c) of FIG. 6 shows a structure of a dummy structure 100 in which a through hole 115 through which a binding member 115a such as a string or wire can penetrate is formed on the outer surface of the body 110 of the dummy structure 100. Showing.

In the dummy structure 100 having such a shape structure, as shown in the installation cross-sectional view shown in FIG. 7(c), the dummy structure 100 is bound and fixed by a clamp member 40 together with the strands of strands 32 In the state, by penetrating the binding member 115a through the through hole 115 formed in the body of the dummy structure 100 and binding and fixing it to the adjacent strand 32 or clamp member 40, Thus, even if the dummy structure 100 is forced to descend downward, the dummy structure 100 and the strand of strands 32 or the clamp member 40 are bound by the binding force of the binding member 115a that binds the dummy structure 100 100) is not separated from the clamp member 40, it is possible to secure a stable binding force.

In this case, the number of through holes 115 formed in the body portion of the dummy structure 100 may be formed in one or more numbers on the outer peripheral surface of the body 110 for convenience of installation. In this case, the through hole 115 formed at a different position when the through hole 115 on one side formed in the body 110 of the dummy structure comes into contact with the adjacent strand 31 or the inner circumferential surface of the clamp member 40 and is covered. By inserting the binding member 115a through the dummy structure 100 can be easily installed.

On the other hand, FIGS. 8A to 8C are views showing another embodiment of the dummy structure 100 according to the present invention.

The dummy structure 100 of the shape shown in FIGS. 8A to 8C is a stranded wire adjacent to the body 110 by hanging a binding member 116a such as a string or wire around the outer surface of the upper side of the body 110 in the form of a circular rod (31) Or the annular groove 116 is formed so as to be bound to the clamp member 40 portion.

At this time, the annular groove 116 has a longitudinal cross-sectional shape of a circular structure as shown in (a) of FIG. 8, or formed to have a polygonal structure such as a triangle or a square as shown in (b) and (c) of FIG. 8 Can be.

And, as shown in the installation cross-sectional view shown in FIG. 9, the dummy structure 100 in which the annular groove 116 is formed is fixed by binding the dummy structure 100 together with the strands of strands 32 by a clamp member 40 In the state, the binding member 116a is fastened to the annular groove 116 and is bound to the adjacent strands 32 or clamp members 40, thereby suppressing downward movement of the dummy structure 100.

Alternatively, a cable tie used to tie various cables to the annular groove 116 in a state where the dummy structure 100 is tied and fixed with the clamp member 40 together with the strands of strands 32, not shown. ) May be combined so that a portion of the cable tie protruding out of the outer surface of the dummy structure 100 is caught by the adjacent strand 31 or the clamp member 40 to prevent downward movement of the dummy structure 100.

In addition, as described above, the dummy structure 100 is fixed by binding the binding member 116a to the annular groove 116 portion of the dummy structure 100 and binding to the adjacent strands 32 or clamp member 40. The downward movement of the ring can be suppressed, but in addition, a ring member capable of elastic deformation, such as a rubber ring, is coupled to the annular groove 116, and the portion to which the ring member (not shown) is coupled is a dummy structure. By forming to have a diameter size that is larger than the diameter of the body of (100), the ring member portion coupled to the annular groove 116 is between the strand 31 and the strand 31, or the strand 31 and the clamp member ( 40) It is possible to forcibly suppress the downward movement of the dummy structure 100 by being caught between them.

On the other hand, (a) and (b) of Figure 10 shows another embodiment form of the dummy structure 100 according to the present invention, the annular protrusion 117 around the upper outer peripheral surface of the body 110 is integrally It shows the formed structure.

At this time, the annular protrusion 117 is integrally formed with the body 110 to have an expanded diameter larger than the body diameter of the dummy structure 100.

In this case, the longitudinal cross-sectional shape of the annular protrusion 117 may have a circular outer surface as shown in FIG. 10(a), or may have a rectangular shape as shown in FIG. 10(b). It is not limited to shape.

In this way, as the annular protrusion 117 having an extended diameter is formed on the outer peripheral surface of the upper side of the body of the dummy structure 100, as shown in the installation cross-sectional view shown in FIG.

In a state in which the dummy structure 100 is tied and fixed with the clamp member 40 together with the strands of strands 32, the annular protrusion 117 formed on the upper side of the dummy structure 100 is connected to the upper end of the adjacent clamp member 40 Downward movement of the dummy structure 100 is suppressed by being caught between the outer circumferential surfaces of the strands 31 covered.

Therefore, in a state in which the elastic member in the clamp member 40 is hardened after a long time and the fixing force is loosened, vibration is continuously applied from the outside and the dummy structure 100 is applied to the dummy structure 100 even if the force to move downward acts on the dummy structure 100 ), the annular projection 117 on the upper side of the clamp member 40 is caught between the upper end of the clamp member 40 and the covered outer peripheral surface of the stranded wire 31, so that downward movement of the dummy structure 100 can be forcibly suppressed, The dummy structure 100 can secure a stable restraining force within the clamp member 40, and thus, replacement and maintenance costs due to separation and loss of the dummy structure 100 are not incurred, and thus cost reduction can be realized.

In the above, a preferred embodiment of the present invention has been described, but the scope of the present invention is not limited to such a specific embodiment, and a person of ordinary skill in the relevant field appropriately changes within the scope described within the scope of the claims of the present invention. This will be possible.

10: pylon 20: top plate
30: cable 31: stranded wire
32: strand of stranded wire 34: stay pipe
40: clamp member 50: fixing fixture
60: tension anchorage 70: damper
100: dummy structure 110: body
112: taper part 113: right angle bolt
114: eye bolt 115: through hole
116: annular groove 117: protrusion

Claims (11)

A clamp member surrounding a plurality of strands and tying the plurality of strands into a bundle;
It is provided to fill the space between the inner circumferential surface of the clamp member and the strand or between the strand and the strand, and is press-fixed together with the strand by the clamping force of the clamp member to maintain the plurality of strands in a bundle shape. A dummy member for clamping one or more strands of strands;
Including,
The dummy member for clamping the stranded strand is,
A body having a cross-sectional shape corresponding to the cross-sectional shape of the stranded wire and extending in the same direction as the stranded strand;
The upper side of the body is positioned to protrude upward in the gravitational direction than the clamp member in the extension direction of the strand of strands and is supported on the upper end of the clamp member or on one side of the strands of strands to prevent downward movement of the body, thereby preventing the body from moving downward. Comprising a locking means for preventing separation from the, stranded wire bundle coupling structure. The method of claim 1,
The body,
One side is in contact with the inner circumferential surface of the clamp member, and the other side is arranged to be in contact with the stranded wire bundle coupling structure. The method of claim 1,
The locking means,
Interfering with the upper end of the clamp and formed on the upper end of the body to prevent downward movement of the body, stranded strand coupling structure. The method of claim 3,
The locking means,
A tapered portion formed in a conical shape such that the diameter increases from the upper end of the body toward the upper side, the stranded strand coupling structure. The method of claim 3,
The locking means,
An annular protrusion formed in a shape protruding around the outer peripheral surface of the body so as to have a diameter larger than the diameter of the body on the upper side of the body, the stranded wire bundle coupling structure. The method of claim 3,
The locking means,
It is formed to be bent in a'a' shape, one side is coupled to the upper surface of the body and the other side is a bolt formed with a hook portion that is hooked and supported by the upper end of the clamp member. The method of claim 1,
The locking means,
An eye bolt formed on the upper side of the upper side and fastened to the upper surface of the body;
A binding member fixed and tied to the stranded wire or the clamp member while being fitted into the ring portion of the eye bolt;
Containing, stranded wire bundle coupling structure. The method of claim 1,
The locking means,
A through hole formed through the outer surface of the portion exposed upwardly than the clamp member of the body;
A binding member bound and fixed to the stranded wire or the clamp member while being inserted into the through hole;
Containing, stranded wire bundle coupling structure. The method of claim 1,
The locking means,
An annular groove formed along the circumference of an outer peripheral surface of a portion of the body exposed upwardly than the clamp member;
A binding member that is fixed to or tied to the stranded wire or the clamp member while being inserted into the annular groove;
Containing, stranded wire bundle coupling structure. The method of claim 3,
The locking means,
An annular groove formed along a circumference of a portion of the body exposed upwardly than the clamp member;
A ring member having a ring shape that is inserted into and coupled to the annular groove so as to form a diameter larger than the diameter of the body and spans the upper end of the clamp member;
Containing, stranded wire bundle coupling structure. The method of claim 1,
It is located on the inner circumferential surface of the clamp member, further comprising an elastic member provided to be in close elasticity to the strand of stranded strands coupling structure.

Images