KR101812586B1 - Terminal setting method of non-corrosive tendon and non-corrosive tendon manufactured thefewith - Google Patents

Abstract

The present invention relates to a method to install a terminal of a non-corrosive tendon, embedding a sensor in a non-corrosive tendon, such as a carbon fiber reinforced plastic (CFRP) tendon, and integrating a terminal with the embedded sensor to facilitate measurement of end and side parts; and a non-corrosive tendon manufactured thereby. According to the present invention, the method comprises the following steps: (a) withdrawing a sensor from an end part of a non-corrosive tendon having the sensor embedded therein and interconnecting the withdrawn sensor and a sensor of a terminal to install the terminal in the non-corrosive tendon; (b) installing a protection cap on the terminal installed in the non-corrosive tendon; (c) installing a terminal housing in a compression sleeve formed in an end part of the non-corrosive tendon; and (d) allowing the terminal to penetrate a finishing cap while installing the finishing cap in an opening part of the terminal housing. Accordingly, a cap of the finishing cap is opened to expose the terminal.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a non-corrosive torsion material,

The present invention relates to a method for installing a terminal of a non-corrosive tough material and a non-corrosive tough material made using the same. More specifically, a method of installing terminals of a noncorrosive material, which has a built-in sensor in a noncorrosive material such as a CFRP material, and a terminal formed integrally with the built-in sensor, facilitates measurement of the end and the side, and a noncorrosive material .

FIG. 1A shows an example of a configuration of a conventional PC strand and a smart strand.

The PC stranded wire 10 is also referred to as a tensile member for introducing a prestress into a concrete member and is formed so that a plurality of stranded wires 11 are twisted around the core 12.

These PC strands are installed to settle after the tension on the fixture including the wedge. Once the fixture is fixed to the fixture, it is almost impossible to check the amount of the pre-stress introduced and the amount of loss by the PC strand.

In order to confirm the introduction amount of the prestress and the amount of loss, there is a case where an EM sensor is used. However, a smart strand 20 equipped with a sensor is introduced as shown in Fig.

That is, the smart strand 20 is formed of a CFRP smart core 21 instead of the core 12 and an FBG sensor 22 (optical fiber sensor) embedded in the CFRP smart core 21.

Accordingly, the FBG sensor 22 can extract data from the smart strand 20 and measure necessary data values using a decoder or the like through terminals not shown.

Further, the FBG sensor 22 may be embedded in the CFRP tensile material other than the PC stranded wire.

That is, as shown in FIG. 1B, the FBG sensor 22 is set together with the CFRP roving 31, and the primary guide plate is linearly aligned.

Then, the resin-impregnated bass is secondarily aligned through the second guide plate, and the impregnated fiber and the sensor are passed through the mold 32 so that the sensor is positioned at the center of the CFRP cross section.

The CFRP having passed through the mold is cured while passing through the heating furnace 33 and pulled through the final stretching machine 34, and the CFRP can be cut and cut using a cutter after being wound to a certain length.

That is, a part of the CFRP roving is replaced by the FBG sensor 22 in the process of manufacturing the CFRP tensions, and the built-in FBG sensor 22 is drawn out of the CFRP tensions. So that it can be measured.

At this time, when the wedge is used as a conventional fixing member in the fixing after the tension, the CFRP tensile member 30 may be damaged due to brittleness, so that the pressing sleeve is used as a fixing unit.

A method of forming such a compression sleeve in the CFRP tensile member can be seen in FIG.

That is, the CFRP tensile member 30 is fitted with the compression sleeve 51 and aligned between the hydraulic jack 52 for extrusion and the swaging block 53 for compression,

Next, the hydraulic jack 52 is operated to allow the compression sleeve 51 to pass through the swaging block 53.

At this time, since the inner diameter of the swaging block 53 is smaller than the outer diameter of the compression sleeve 51, a pressing force is generated in the compression sleeve 51 by a forced force.

Finally, the compression sleeve 51 passing through the swaging block 53 is compressed to the same size as the inner diameter of the swaging block 53, and the diameter is reduced and the length is increased to the CFRP tensile material 30.

The FBR sensor 14 can be used by pressing the compression sleeve 51 on the CFRP tensile member 30. The problem is that the terminals are installed in the CFRP tensile member 30 on which the FBG sensor 14 is mounted, But there was no other description as to whether maintenance would be possible.

Korean Patent No. 10-1731053 (entitled " Tensile fixation member crimping apparatus and method for installing a tense fixation member using the same, public date: May 11, 2017) Korean Patent No. 10-1179572 (entitled " End Fixation Structure of an F-Apei Cable ", and Method for Improving End Fixation Performance of an F-Apei Cable, published on Sep. 5, 2012)

 Development of smart tensions management technology of PSC bridges in Korea (Open date: 2015.12)

Accordingly, the present invention provides a terminal connection method that can be easily connected to a sensor drawn from a non-corrosive tensional material such as a CFRP tensional material, thereby providing a method of installing a terminal of a non-corrosive toughening material, The present invention has been made in view of the above problems,

The method of installing the terminal of the non-corrosive tough material according to the present invention and the non-corrosive tough material manufactured using the method

(a) withdrawing the sensor from the end of the non-corrosive taut material with built-in sensor, and connecting the sensor of the terminal to the drawn sensor to establish a terminal in the non-corrosive taut material; (b) attaching a protective cap to a terminal provided in the non-corrosive material; (c) installing a terminal housing in a compression sleeve formed at an end of the non-corrosive taut material; And (d) inserting a finishing cap into the opening of the terminal housing to allow the terminal to pass through the finishing cap, thereby opening the cap of the finishing cap to expose the terminal.

Also preferably,

 (a) withdrawing the sensor from the end of the non-corrosive taut material with built-in sensor, and connecting the sensor of the terminal to the drawn sensor to establish a terminal in the non-corrosive taut material; (b) attaching a protective cap to a terminal provided in the non-corrosive material; (c) installing a terminal housing in a compression sleeve formed at an end of the non-corrosive tensional material, and installing an extension end housing having a side hole (S1) in the housing of the terminal housing; And (d) installing a finishing cap on the opening of the extended end housing and allowing the terminal to pass through the side hole (S1), thereby opening the cap of the finishing cap to expose the terminal .

According to the present invention, since the terminal is integrated at the end of the non-corrosive tough material by inserting the terminal of the non-corrosive tough material, it is possible to sense by inserting, for example, a jack in such a terminal. This can be a very useful means.

In addition, the terminal of the non-corrosive tough material according to the present invention can be extended in the end direction and the lateral direction, and it is possible to provide a non-corrosive tough material having greatly improved usability.

FIG. 1A is a perspective view of a conventional PC strand and a smart strand,
Figure 1b is a schematic representation of a conventional non-corrosive,
1C shows a conventional compression sleeve manufacturing process,
FIGS. 2A, 2B, and 2C illustrate examples of methods of installing terminals of the non-corrosive taut material of the present invention,
3 is an illustration of an example of a noncorrosive material fabricated by a method of installing a terminal of a noncorrosion-
4 is an exemplary view of a terminal protection device for non-corrosive tensions of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

[How to install terminals for non-corrosive tensions]

FIGS. 2A, 2B, and 2C illustrate examples of methods of installing terminals of the non-corrosive taut material of the present invention.

Referring first to FIG. 2A, a method of forming a terminal of the non-corrosive toughening material 100 of the present invention can be confirmed.

The non-corrosive toughening material (100) can be made of CFRP, and is made of CFRP, not made of a steel material in comparison with PC stranded wire. Therefore, there is no fear of corrosion and is formed in a rod shape. It is possible. The non-corrosive tensions 100 are hereinafter referred to as CFRP tensions.

The noncorrosive toughening material 100 has a tensile strength almost the same as that of a conventional PC strand but has little difference in weight compared with a compressive strength and is small in weight and has no brittle property but has a brittle property, The compression sleeve 120 is compressed and used as a fixing unit.

Also, in order to measure the introduction amount and loss amount of the compression prestress by the non-corrosive toughening material 100, a sensor 130 such as an FBG sensor is used together with CFRP roving in the manufacturing roving process, And is made of a tensile material 100.

So that the sensor 130 is drawn out from the end surface of the non-corrosive toughening material 100 and the terminal 140 is connected to the sensor 130 to be connected to the measurement system.

It is understood that the noncorrosive toughening material 100 of the present invention includes the FRP main body 110, the compression sleeve 120, the sensor 130, and the terminal 140.

The FRP main body 110 is a CFRP rod member having a predetermined length. The FRP main body 110 is cut into a predetermined length in a wound state.

The compression sleeve 120 is formed by press-fitting the FRP main body 110 on the outer circumferential surfaces of both end portions of the FRP main body 110 with a tube-shaped sleeve made of stainless steel or the like, It may be formed integrally with the FRP main body 110. These compression sleeves 120 are formed at both ends of the FRP main body 110 respectively.

The sensor 130 is embedded in the FRP body 110 and used as an FBG sensor drawn from the end face of the FRP body 110 and is shown in a wire form.

The terminal 140 is formed to be connected to the sensor 130 drawn out from the end of the FRP main body 110 so that the jack can be inserted.

The FRP main body 110 is prepared so as to have a predetermined length and the pressing sleeve 120 is formed by pressing the both ends of the FRP main body 110 and then the sensor 130 is pulled out from both ends of the FRP main body 110.

The sensor 130 of the terminal 140 and the sensor 130 of the FRP main body 110 are connected to each other in such a manner that the sensor 130 of the terminal 140 and the sensor 130 of the FRP main body 110 are fused to each other .

The sensors 130 connected to each other are finished with resin or the like so as to have the same diameter as the diameter of the FRP main body 110 and the terminal 140 and eventually measure the data value from the sensor 130 through the terminal 140 .

Accordingly, the terminal 140 and the FRP main body 110 are formed to be flexible in a form capable of being freely deformed as well as being confirmed to extend in the same shape with the naked eye.

Furthermore, the end housing 200 is separately provided at the end of the non-corrosive toughening material 100 and the terminal 140 with the protective cap 300 is provided at the end housing 200 to enable the end measurement.

That is, as shown in FIG. 2B,

The FRP main body 110 is prepared so as to have a predetermined length and the pressing sleeve 120 is formed by pressing the both ends of the FRP main body 110 and then the sensor 130 is pulled out from both ends of the FRP main body 110.

The sensor 130 of the terminal 140 and the sensor 130 of the FRP main body 110 are fused to each other by preparing a flexible terminal 140 in which the sensor 130 is separately drawn out from one side, . The sensors 130 connected to each other are finished with resin or the like so as to have a diameter equal to the diameter of the FRP main body 110 and the terminal 140 and eventually measure the data value from the sensor 130 through the terminal 140 .

At this time, the end housing 200 is installed in the compression sleeve 120 formed in the non-corrosive tensional material 100, and the end housing 200 can enhance the protection and usability of the terminal 140.

As shown in FIG. 2B, the end housing 200 includes a connection tab 210, a housing 220, and a finishing cap 230.

That is, a connection tab 210 having a threaded portion formed on the outer circumferential surface thereof is formed on the outer peripheral surface of the end portion of the compression sleeve 120,

The housing 220 formed of a hollow tube is coupled to the outer circumferential surface of the connection tab 210 to extend in the longitudinal direction of the noncorrosive material 100,

A finishing cap 230 is fastened to the inside of the opening of the housing 220,

And the protective cap 300 installed on the terminal 140 is inserted through the finishing cap 230.

The protection cap 300 includes a loss prevention ring 310, a body 320, and a cap 330.

That is, the loss prevention ring 310 is connected to the body 320 as a wire,

The body 320 covers the end of the terminal 140,

A threaded portion is formed at the end of the body 320 to fasten the cap 330.

Accordingly, the operator can rotate the cap 330 to expose the terminal 140 covered on the body 320,

The cap 330 is connected to the body 320 by the loss prevention ring 310 to prevent loss.

At this time, the body 320 is fixedly installed through a finishing cap 230 fastened to the end of the opening of the housing 220.

Thus, the terminal 140 is located inside the end of the hollow tube-like housing 220 and is protected, and a jack or the like is inserted into the exposed terminal 140 so that the data value from the sensor 130 is measured at the end Able to know.

2C is a side view measurement in addition to the end measurement as shown in FIG. 2B.

That is, the terminal 140 is formed integrally and flexible with the FRP main body 110 and is used as it is. The terminal 140 is inserted into the hole formed in the side of the extended end housing 220a, which is further formed in the housing 220 in the longitudinal direction, 300, respectively.

That is, the FRP main body 110 is prepared so as to have a predetermined length, and the pressing sleeve 120 is formed by pressing the both ends of the FRP main body 110, and then the sensor 130 is pulled out from both ends of the FRP main body 110.

The sensor 130 of the terminal 140 and the sensor 130 of the FRP main body 110 are connected to each other in such a manner that the sensor 130 of the terminal 140 and the sensor 130 of the FRP main body 110 are fused to each other. The same.

The sensors 130 connected to each other are finished with resin or the like so as to have a diameter equal to the diameter of the FRP main body 110 and the terminal 140 and eventually measure the data value from the sensor 130 through the terminal 140 .

At this time, the end housing 200 and the extension end housing 220a are continuously installed in the compression sleeve 120 formed in the non-corrosive tensional material 100. [

The end housing 200 is also formed to include a connection tab 210, a housing 220 and a finishing cap 230. The extending end housing 220a includes a housing 210, which is additionally provided at an end of the end housing 200, .

The connection tab 210 is formed by rotating the outer circumferential surface of the compression sleeve 120,

The housing 220 is fastened to the outer peripheral surface of the connection tab 210,

The extended end housing 220a having the side holes S1 formed therein is further extended to the opening of the housing 220,

The finishing cap 230 is fastened to the inside of the opening of the extended end housing 220a,

The protection cap 300 is installed in the side hole S1 of the extension end housing 220a so that the flexible terminal 140 is inserted through the protection cap 300. [

In this case, the protective cap 300 includes the loss prevention ring 310, the body 320, and the cap 330.

That is, the loss prevention ring 310 is connected to the body 320 as a wire,

The body 320 covers the end of the terminal 140,

A threaded portion is formed at the end of the body 320 to fasten the cap 330.

Accordingly, the operator can rotate the cap 330 to expose the terminal 140 covered on the body 320,

The cap 330 is connected to the body 320 by the loss prevention ring 310 to prevent loss.

At this time, the body 320 is inserted and fixed in the side hole S1 formed at the side of the extended end housing 220a formed in the housing 220. [

As a result, the terminal 140 is located on the side of the extension end housing 220a, and it is possible to perform the lateral measurement in such a manner that a jack lamp is inserted laterally.

As a result, it can be appreciated that the terminal 140 of the present invention can be configured to allow end and side metering, either end or side metrology, or a combination thereof, using an end housing, an end housing.

[Noncorrosive Tensile Material (100) manufactured using the method of installing a terminal of a noncorrosive material]

3 is an illustration of an example of a noncorrosive tie 100 fabricated by a method of installing a terminal of a noncorrosive tie material of the present invention.

That is, according to FIG. 3,

The noncorrosive material 100 with the sensor 130 is cut to a required length and used.

The compression sleeve 120 is formed by pressing the opposite ends of the non-corrosive prismatic material 100 having the sensor 130 having a predetermined length.

At this time, the compression sleeve 120 is formed at a position where both ends of the FRP main body 110 are partially exposed, and the FRP main body 110 is cut to expose the sensor 130.

The terminal 140 is connected to the sensor 130 as described above. In this case, it is understood that the protective cap 300 is provided at the end of the end housing 200 as described above. As a result, the terminal 140 is exposed through the protection cap 300 so that end measurement is possible.

Further, the extension end housing 220a is further provided in the end housing 200, and the leaf protection cap 300 is inserted into the side hole S1 formed on the side of the extension of the extension end housing 220a, The noncorrosive tension member 100 capable of side measurement together with the end measurement can be manufactured through the terminal 140 connected to the noncorrosive material 300.

[Tensile Material Protection Device (400) Using Noncorrosive Tension Material (100) of the Present Invention)

4 illustrates a perspective view of a configuration of a tension member protection apparatus 400 using the non-corrosive tension member 100. As shown in FIG.

4, the terminal 400 of the non-corrosive tensional material 100 is formed to be embedded in the surface of the structure 500, and the terminal 140 of the non-corrosive tensional material 100 is electrically connected to the terminal 140 of the tensional device 400 (Measurement) can be done through.

Specifically, it is as follows.

As shown in FIG. 4, the taut material protecting apparatus 400 is formed as a box body inserted and fixed in the taut material protecting apparatus groove 510 formed in the structure 500 in advance.

The tensile material protecting device groove 510 is formed on the surface of the structure 500 in such a size that the tensile protecting device 400 is inserted therein and the tensile material protecting device groove 510 is formed with a tensile member The groove 520 is communicated.

The trench grooves 520 are formed in the bottom surface of the structure 500 so that the trenches 100 are filled with the non-corrosive trenches 100.

At this time, the fusing unit 410 is fixedly installed in the taut material protecting device groove 510.

The fixing unit 410 includes a fixing member 411 extending in the longitudinal direction of the structure and a tension member fixing block 412 integrally formed between both fixing members.

That is, the two fixing plates 411 are fixed to the trench protection device groove 510, and the upper surface of the fixing plates 411 is crossed in the direction perpendicular to the longitudinal direction of the structure, (100) is fixed.

The both fixing plates 411 are fixed to the inside of the tensile material protecting device groove 510 by the anchor bolts 413 passing through the bolt holes formed in the fixing plate 411,

A non-corrosive toughening material 100 is inserted into the trench grooves 100 and is fixed after being tensioned by a compression sleeve 120 provided at an end of the non-corrosive toughening material 100.

Further, a locking groove 415 is further formed on the upper surface of the tension member fixing block 412 so that the fixing bolt 430 passing through the insertion body 420 is fastened so that the tension member protector 400 is fixed to the fixing bolt 430 And it is fixed to the taut material protecting device groove 510.

It will be understood that the tension member protecting apparatus 400 includes the fixing unit 410, the insertion body 420, the fixing bolt 430, the terminal 140, and the rotary door 450.

The fixing unit 410 serves to fix the insertion body 420 to the fixing unit 410 using the fixing bolts 430 while fixing the noncorrosive material 100. The fixing unit 410 includes two fixing plates 411, And a tension member fixing block 412.

The insertion body 420 is formed to be inserted into the tensile member protector groove 510 so that the fusing unit 410 is exposed. The insertion body 420 is formed as a rectangular box chain body 421 having an open bottom,

It can be seen that the upper surface of one side of the body portion 421 is cut so that the rotary opening / closing port 450 is hingedly connected to the opening portion.

The fixing bolt 430 is inserted into the bolt hole of the body portion 421 so that the bolt hole 422 is passed through the upper surface of the body portion 421 and the fastening hole 415 formed on the upper surface of the tension member fixing block 412, Respectively,

As a result, it can be seen that the taut material protecting apparatus 400 is inserted and fixed in the taut material protecting apparatus groove 510.

In addition, the above-described terminal 140 is formed in the rotary door 450 so that the sensor 130 extending to the terminal 140 is extended to the non-corrosive material 100.

For example, the operator connects the cable connected to the decoder to the terminal 140 installed on the rotary door 450 through the jack, and directly senses the sensed signal from the sensor 130 built in the non-corrosive material 100 through the notebook or the like connected to the decoder Corrosion of the non-corrosive toughening material 100 and the integrity of the pre-stress introduced into the non-corrosive toughening material 100 can be confirmed through (data acquisition), and the jack of the cable can be pulled out to complete the operation simply.

Also, it is possible to check the integrity of the noncorrosive toughening material 100 located inside the toughness protection device 400 by simply opening and closing the rotary opening and closing port 450 while visually observing it.

It will be understood by those skilled in the art that the foregoing description of the present invention is for illustrative purposes only and that those of ordinary skill in the art can readily understand that various changes and modifications may be made without departing from the spirit or essential characteristics of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: Non-corrosive tensile material 110: FRP body
120: compression sleeve 130: sensor
140: Terminal 200: Terminal housing
210: connection tab 220: housing
220a: extension end housing 230: finishing cap
300: Protective cap 310: Loss prevention ring
320: body portion 330: cap
400: Tensile protecting device 410: Fusing unit
411: Fusing plate 412: Tensile fixing block
415: fastening hole 420: insertion body part
421: body portion 422: bolt hole
430: Fixing bolt 450: Rotating door
500: Structure 510: Tension Protection Device Home
520: Tension material groove S1: Side hole

Claims (10)

(a) pulling the sensor out of the end of the non-corrosive material 100 with the sensor 130 and connecting the sensors of the terminal 140 to the drawn sensor to connect the terminal 140 to the non-corrosive material 100 Installing;
(b) installing a protective cap (300) on a terminal (140) provided in the non-corrosive tensional material (100);
(c) installing a terminal housing (200) in a compression sleeve (120) formed at an end of the noncorrosive material (100); And
(d) installing a finishing cap (230) on the opening of the terminal housing (200) and allowing the terminal to pass through the finishing cap; and opening the cap (330) Of the non-corrosive tensions. (a) a sensor 130 is pulled out from an end of a non-corrosive material 100 having a built-in sensor 130, and a sensor of a terminal is connected to the sensor 130, 140);
(b) installing a protective cap (300) on a terminal (140) provided in the non-corrosive tensional material (100);
(c) a terminal housing 200 is installed in a compression sleeve 120 formed at an end of the non-corrosive tensional material 100 and a side hole S1 is further formed in the housing 220 of the terminal housing 200 Extending the extension end housing (220a); And
(d) installing a finishing cap (230) on the opening of the extended end housing (220a) and allowing the terminal to be inserted through the side hole (S1) 330) to open the terminal. 3. The method according to claim 1 or 2,
The terminal 140 of the step (a)
A FRP main body 110 with a built-in sensor is prepared,
The pressing sleeve 120 is formed by press-fitting both ends of the FRP main body 110 and then the sensor 130 is pulled out from both ends of the FRP main body 110,
The sensor 130 of the terminal 140 and the sensor 130 of the FRP main body 110 are connected to each other by preparing a terminal 140 drawn out from one side of the sensor 130,
The sensors 130 may be closed to measure the data value from the sensor 130 through the terminal 140 so that the terminal 140 connected to the FRP main body 110 is formed in a flexible form Of the non-corrosive taut material. delete The method according to claim 1,
The protective cap 300 of step (b)
A body 320 formed to cover the end of the terminal 140; A loss prevention ring 310 connected to the body 320 as a wire; And a cap 330 coupled to the threaded portion formed at the end of the body 320 and connected to the loss prevention ring,
The body 320 is fixedly installed through a finishing cap 230 fastened to the end of the opening of the housing of the end housing 200 to rotate the cap 330 so that the terminal 140 ) Of the non-corrosive taut material. 6. The method of claim 5,
The end housing 200 of the step (c)
The connection tab 210 is formed by rotating the outer periphery of the compression sleeve 120,
The housing 220 is fastened to the outer peripheral surface of the connection tab 210,
A finishing cap 230 is fastened to the inside of the opening of the housing 220,
Wherein the protective cap (300) provided with the terminal (140) is passed through the finishing cap (230) so as to be fixedly installed on the finishing cap (230). 3. The method of claim 2,
The protective cap 300 of step (b)
A body 320 formed to cover the end of the terminal 140; A loss prevention ring 310 connected to the body 320 as a wire; And a cap 330 coupled to the threaded portion formed at the end of the body 320 and connected to the loss prevention ring,
The body 320 may be fixedly installed through the side hole S1 of the extended end housing 220a to expose the terminal 140 covered by the body 320 by rotating the cap 330 The method of installing terminals of non-corrosive tensions. 8. The method of claim 7,
The end housing 200 of the step (c)
The connection tab 210 is formed by rotating the outer periphery of the compression sleeve 120,
The housing 220 is fastened to the outer peripheral surface of the connection tab 210,
An extended end housing 220a having a side hole is connected to the opening of the housing 220,
Wherein the protective cap (300) provided with the terminal (140) is inserted through the lateral hole (S1) so as to be fixedly installed. A noncorrosive material produced by a method of installing a terminal of a noncorrosive material according to any one of claims 1 or 2. 10. The method of claim 9,
The noncorrosive toughening material 100 is fixed to the surface of the structure 500 by using the state in which the fixing unit 410 for fixing the noncorrosive tentering material 100 after the tension is installed inside the tentering material protecting device groove 510 as it is The box chain insertion body 420 is inserted into the tension member protector groove 510 by the fixing bolt 430 to which the lower end is fastened to the fastening groove 415 formed in the tension member fixing block 412 of the fixing unit 410. [ The noncorrosive tension member 400 fixed to the fixing unit 410 is opened by opening a rotary door 450 formed in the body portion 421 of the insertion body 420 so that the non- The insertion body portion 420 of the taut material protection device 400 is protected by the taut material protection device 400. The insertion body portion 420 of the taut material protection device 400 is formed by a body portion 421 of a rectangular box chain whose bottom surface is open, (421) is formed with a rotary opening / closing port (4 And a bolt hole 422 is formed in the upper surface of the other side of the body portion 421 so that the fixing bolt 430 passes through the bolt hole 422 and the lower end of the fixing bolt 430 penetrates through the bolt hole 422, Noncorrosive material made by a method of installing a terminal of a noncorrosive material to be fastened to a fixing block 422.

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