KR20090041268A - Stranded cable having optical fiber sensor - Google Patents

Abstract

A strand in which the optical fiber sensor is mounted is provided to measure the stress degree of strand which is installed inside the structure. A strand in which the optical fiber sensor is mounted comprises an optical fiber sensing part(100) which is mounted on a core wire, and plural lateral wires(200) which is mounted on the circumference of the optical fiber sensing part with a twisted structure. The optical fiber sensing unit includes an optical fiber(110), and an optical fiber protection unit(120) which surrounds the exterior of the optical fiber in order to move with the optical fiber.

Description

Stranded cable with fiber optic sensor {STRANDED CABLE HAVING OPTICAL FIBER SENSOR}

The present invention relates to the field of construction, and more particularly, to a structure that can accurately measure the stress state of the stranded wire.

A stranded cable (steel strand) is a structure in which a plurality of strands are braided in a twisted shape and used in a pre-stressing method.

As shown in FIGS. 1 and 2, the plurality of element wires constituting the conventional strand 10 are again divided into a central core 11 and a circumferential side 12. 7 stranded wires formed by core wires and 6 side lines are called 19 stranded wires formed by one core wire and 18 side wires.

Since it is flexible, the curve arrangement is easy and the workability is good, and it is widely used as a tension material of the PC method, and it is also widely used as a construction material such as soil nailing and lock bolts.

This strand is applied to the tension in the structure, the role of generating a resistance that can resist the external force, and thus has a decisive influence on the structural stability of the structure, the measurement of the stress state is a very important factor It can be said.

By the way, it has been pointed out as a problem that the conventional method which can measure the stress state of such a stranded wire accurately and conveniently has not been devised.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a stranded wire equipped with an optical fiber sensor that can accurately and conveniently measure the stress state of the stranded wire installed in the structure.

The present invention, in order to achieve the above object, the optical fiber sensing unit 100 mounted at the core position; Presents a stranded wire with an optical fiber sensor comprising a; a plurality of side lines 200 mounted in a twisted structure around the optical fiber sensing unit 100.

The optical fiber sensing unit 100 is an optical fiber 110; And an optical fiber protection part 120 mounted around an outer surface of the optical fiber 110 to behave together with the optical fiber 110.

The optical fiber protection part 120 preferably includes a core material 121 formed of a material that can be deformed by the pressure of the plurality of side lines 200 while also acting together with the plurality of side lines 200. .

The core material 121 is preferably formed of a synthetic resin material.

The core member 121 and the side line 200 is preferably formed to have a substantially circular cross section.

The diameter of the core material 121 is preferably formed 1.2 ~ 1.3 times larger than the diameter of the side line 200.

The optical fiber protective part 120 is formed of a metallic material and includes a metallic protective material 122 mounted between the core member 121 and the optical fiber 110 to behave together with the optical fiber 110. It is preferable.

The metallic protective material 122 is preferably formed by a structure to maintain a cross section of a certain shape even when bending occurs.

It is preferable that a frictional force increasing structure is formed on the outer surface of the metallic protective material 122.

The metallic protective material 122 is preferably mounted as a braided structure by metal yarns.

The metallic protective material 122 is preferably formed of at least one material selected from the group consisting of silver, copper, aluminum, gold, platinum.

The optical fiber protection part 120 may further include a coating material 123 mounted between the core material 121 and the metallic protection material 122 to behave together with the metallic protection material 122.

The coating material 123 is preferably a heat resistant material capable of resisting high temperatures of 200 ° C or higher.

The coating material 123 is preferably a synthetic resin material.

The coating material 123 is preferably formed of a Teflon material.

The present invention proposes a stranded wire equipped with an optical fiber sensor that can accurately and conveniently measure the stress state of the stranded wire installed in the structure.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 3 or below, the stranded wire equipped with the optical fiber sensor according to the present invention basically includes an optical fiber sensing unit 100 mounted at a core wire position; And a plurality of side lines 200 mounted in a twisted structure around the optical fiber sensing unit 100.

Optical fiber refers to a thin fiber having a diameter of about 0.1 mm formed so that the refractive index of light is high inside and low outside, so that total reflection optical phenomenon occurs inside the fiber.

In order to reduce light loss when transmitting light using the above phenomenon, highly transparent material is required, and high purity quartz or polymer material having excellent optical properties is used.

The structure has a double cylinder shape in which a core called a core is wrapped around a portion called cladding. The outside is coated with one or two coats of synthetic resin to protect it from impact.

The total size excluding the protective coating is 100 to several hundred μm in diameter (1 μm is 1/1000 mm), and the refractive index of the core portion is higher than the refractive index of the cladding, so that the light is focused on the core portion so that the light can proceed without escaping well. have.

Optical fiber is mainly used in the communication field, but when the optical fiber is stretched by the temperature and pressure, it detects the interference pattern of the light passing through the inside and can measure the temperature and pressure. The sensor is called an optical fiber sensor.

Recently, various attempts have been made to utilize such optical fiber sensors in the field of construction measurement, and in detail, measurement of displacement (sag, deformation) of structures due to pressure changes, leak detection due to temperature changes, and the like.

As in the present invention, when the optical fiber sensing unit 100 equipped with the optical fiber having the characteristics described above at the core wire position of the stranded wire, accurate measurement is possible at the end of the optical fiber (end of the stranded wire), so it is installed in the structure The effect is that the stress state of the entire strand can be measured conveniently and accurately in real time.

However, since the strength of the optical fiber is easy to break due to its weak strength, a protective means for preventing this should be taken.

That is, the optical fiber sensing unit 100, as shown in Figures 3 and 4, the optical fiber 110; It is preferable to take a structure including a; optical fiber protection unit 120 mounted around the outer surface of the optical fiber 110 to behave together with the optical fiber 110.

Here, the optical fiber protection unit 120 is mounted around the outer surface of the optical fiber 110 to serve to prevent breakage of the optical fiber 110, so that the optical fiber 110 and the external side line 200 behave integrally. By doing so, it is necessary to allow the deformation and other state changes of the sideline 200 to be transmitted to the optical fiber 110 as it is, enabling accurate measurement of the state of the stranded wire.

To this end, the optical fiber protection unit 120 includes a core material 121 formed of a material that can be deformed by the pressure of the plurality of side lines 200 as well as behaves together with the plurality of side lines 200. Do.

In order for the core material 121 to have such a property, the core material 121 may be formed of a synthetic resin material such as PE (Poly-Ethylen) or PVC.

The core material 121 and the side line 200 are preferably formed to have a substantially circular cross section, like a general strand.

In this case, the diameter of the core material 121 is preferably formed to be 1.2 to 1.3 times larger than the diameter of the side line 200, which is the outer surface of the core material 121 by twisting the side line 200 as shown in FIG. This is because the mutual adhesion can be increased by causing a compression deformation.

Between the core 121 of the optical fiber protection unit 120 and the optical fiber 110, as shown in FIG. 5 or less, is formed of a metallic material, and the metallic protective material 122 to behave together with the optical fiber 110. It is preferred to be mounted.

Since the metal material has excellent strength, thereby protecting the outer surface of the optical fiber 110, it is possible to prevent the breakage of the optical fiber 110 and to have flexibility (flexibility) so that the displacement of the structure to be the parent If is generated, the displacement is transmitted to the optical fiber 110 as it is to enable accurate measurement.

In addition, in order for the optical fiber sensor to accurately measure the change in ambient temperature and perform a role such as leak detection (the leaking section uses the principle that the temperature decreases compared to the surroundings), the sensor itself may generate a certain amount of heat. By having, it is necessary to maintain a constant temperature.

If the temperature of the sensor itself changes with the change in the ambient temperature, since the reference temperature is changed, it is impossible to measure the change in temperature.

Since the metal material is basically not only excellent in thermal and electrical conductivity, but also finely adjusts the resistance value by the inclusion of impurities, the present invention forms a sensor by surrounding the protective material 122 on the outer surface of the optical fiber 110. In the case of taking the structure of, the optical fiber sensor can be maintained at a constant temperature, thereby obtaining the effect that accurate measurement of the ambient temperature change is possible.

It is preferable that the structure of the metallic protective material 122 adopts satisfying the following requirements.

First, since it serves to protect the internal optical fiber 110, even when bending occurs due to deformation of the parent structure, it is good to take a structure so as to maintain a constant cross section (for example, a circular shape) at all times.

For example, a corrugated pipe structure as shown in FIGS.

Second, in order to firmly bond with the core material 121 or the coating material 123 to be described later, it is preferable that a frictional force increasing structure is formed on the outer surface of the metallic protective material 122.

For example, it is an embossing structure (structure in which a plurality of protrusions are formed) as shown in FIG.

9 and 10, the metallic protective material 122 is preferable in that it takes the braided structure by metal yarn, and can naturally satisfy all the above requirements.

Here, the braided structure refers to a structure in which a metal yarn (processed with metal in the shape of a thin thread) is woven into a net structure diagonally with respect to the longitudinal direction of the optical fiber sensor, so that a cavity is naturally formed. .

As described above, this protects the optical fiber 110 inside due to the rigidity of the metal, while maintaining a constant circular cross section at the time of bending.

Furthermore, since it takes a net structure, when a coating operation is performed on this, a part of the metallic protective material 122 is naturally embedded in the core material 121 or the coating material 123 to be described later, and thus, a very excellent bonding force can be obtained. have.

As described above, the metallic protective material 122 may be made of a material having excellent flexibility, thermal and electrical conductivity, and controllability of resistance values.

Examples include silver, copper, aluminum, gold, platinum, and the like, specifically, silver has been shown to most certainly meet the above requirements.

As shown in FIG. 11, the optical fiber protection unit 120 of the optical fiber sensing unit 100 further includes a coating material 123 mounted around the outer surface of the metal protection material 122 to behave together with the metal protection material 122. It is desirable to take one structure.

After the coating of the metallic protective material 122 on the optical fiber 110, the outer surface of the metallic protective material 122 is coated by the coating material 123 to fix the metallic protective material 122, and inserted into the core material 121 This is because it is advantageous in terms of efficiency and ease of manufacturing.

Coating material 123 is a structure that is coated around the outer surface of the metallic protective material 122, in order to behave with the core material 121 is preferably formed of a material having excellent flexibility.

Since the metallic protective material 122 inside the coating material 123 serves as a heating element as described above, the coating material 123 mounted on the outside of the coating material 123 is formed of a heat resistant material capable of resisting a high temperature of about 200 ° C. or more. It is preferable.

In order to satisfy these conditions, it is preferable to employ synthetic resin as the material of the coating material 123, and more specifically, to use teflon.

Since the above has been described only with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention, as is well known, should not be construed as limited to the above embodiments, the present invention described above It will be said that both the technical idea and the technical idea which together with the base are included in the scope of the present invention.

1 is a perspective view of a conventional stranded wire.

2 is a cross-sectional view of a conventional stranded wire.

3 to 11 show an embodiment of the present invention,

3 is a sectional view of a first embodiment of a strand.

4 is a sectional view of a second embodiment of a strand.

5 is a sectional view of a third embodiment of a strand.

6 is a first state diagram of a second embodiment of a metallic protective material.

Fig. 7 is a second state diagram of the second embodiment of the metallic protective material.

8 is a side view of a third embodiment of a metallic protective material.

9 is a first state diagram of the fourth embodiment of the metallic protective material.

10 is a second state diagram of the fourth embodiment of the metallic protective material.

11 is a sectional view of a fourth embodiment of a strand.

** Description of the symbols for the main parts of the drawings **

100: optical fiber sensing unit 110: optical fiber

120: optical fiber protection unit 121: core material

122: metallic protective material 123: coating material

200: sideline

Claims (15)

An optical fiber sensing unit 100 mounted at a core line position; A plurality of side lines 200 mounted in a twisted structure around the optical fiber sensing unit 100; A stranded wire equipped with an optical fiber sensor, characterized in that it comprises a. The method of claim 1, The optical fiber sensing unit 100 Optical fiber 110; An optical fiber protection unit 120 mounted around an outer surface of the optical fiber 110 to behave together with the optical fiber 110; A stranded wire equipped with an optical fiber sensor, characterized in that it comprises a. The method of claim 2, The optical fiber protection unit 120 A stranded wire equipped with an optical fiber sensor, comprising: a core material 121 formed by a material capable of deforming by pressure of the plurality of side lines 200 while also acting together with the plurality of side lines 200. The method of claim 3, The core material 121 is a strand wire is equipped with an optical fiber sensor, characterized in that formed by a synthetic resin material. The method of claim 3, The core wire 121 and the stranded wire is equipped with an optical fiber sensor, characterized in that formed to have a substantially circular cross-section. The method of claim 5, The diameter of the core material 121 is a strand wire is equipped with an optical fiber sensor, characterized in that formed 1.2 ~ 1.3 times larger than the diameter of the side line (200). The method of claim 3, The optical fiber protection unit 120 The optical fiber sensor is formed by a metallic material and includes a metallic protective material 122 mounted between the core material 121 and the optical fiber 110 to behave together with the optical fiber 110. Stranded wire. The method of claim 7, wherein The metallic protective material 122 is a strand wire is equipped with an optical fiber sensor, characterized in that formed by the structure to maintain a constant cross-section even when bending occurs. The method of claim 7, wherein A stranded wire equipped with an optical fiber sensor, characterized in that a frictional force increasing structure is formed on an outer surface of the metallic protective material 122. The method of claim 8, The metallic protective material 122 is A stranded wire equipped with an optical fiber sensor, which is mounted as a braided structure made of metal yarn. The method of claim 7, wherein The metallic protective material 122 is The stranded wire with an optical fiber sensor, characterized in that formed by at least one material selected from the group consisting of silver, copper, aluminum, gold, and platinum. The method of claim 7, wherein The optical fiber protection unit 120 And a coating material (123) mounted between the core material (121) and the metallic protection material (122) to behave together with the metallic protection material (122). The method of claim 12, The coating material 123 is a stranded wire equipped with an optical fiber sensor, characterized in that the heat-resistant material capable of resisting high temperatures of 200 ℃ or more. The method of claim 12, The coating material 123 is The stranded wire equipped with an optical fiber sensor, characterized in that the synthetic resin material. The method of claim 14, The coating material 123 is A stranded wire equipped with an optical fiber sensor, characterized in that formed by Teflon material.

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