JP2017125352A - Fixing part structure of prestress strand and wedge body - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fixing part structure for prestress strand and a wedge body, in which measurement error in tension of the prestress strand may be suppressed.SOLUTION: A fixing part structure 100 for prestress strand fixes prestress strand 1 with optical fiber comprising prestress strand which is formed by twisting a plurality of PC steel element wires and has spiral strand and an optical fiber member arranged on the spiral onto a fixation target part 101. The fixing part structure 100 for the prestress strand comprises a base part 11 which contacts to the fixation target part 101 and into which the prestress strand 1 with the optical fiber are inserted, a socket part 13 which is arranged at rear side of the base part 11 and into which the prestress strand 1 with the optical fiber is inserted, and a wedge body 17 inserted between inner wall surface of a taper hole 13a on the socket part 13 and the prestress strand 1 with the optical fiber from a rear side. On the inner wall surface of the wedge body 17, a recessed strip part extending along the strand is formed.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a fixing portion structure and a wedge body of a PC steel stranded wire, and more particularly to a fixing portion structure of a PC steel stranded wire with an optical fiber and a wedge body used for a fixing portion structure of a PC steel stranded wire with an optical fiber.

  Conventionally, the tension of the PC steel stranded wire by the PC steel stranded wire with an optical fiber in which the optical fiber is attached to the PC steel stranded wire used for tensile materials and tension materials of various structures (bridges, buildings, slopes, etc.) Is being measured. As a technique related to such a PC steel stranded wire with an optical fiber, for example, a tension member described in Patent Document 1 is known. The tension member includes a hollow body, an optical fiber housed inside the hollow body, and a plurality of tension strands that are twisted so as to surround the outer periphery of the hollow body and bear a tension force.

Japanese Patent No. 5604760

  Generally, a PC steel stranded wire is fixed to a fixing portion by, for example, a wedge portion (wedge mechanism), and transmits a tension force and the like through the wedge portion. Therefore, it is desirable to fix the PC steel stranded wire with an optical fiber so that the tension of the PC steel stranded wire can be measured up to the position of the wedge portion.

  By the way, when an optical fiber is attached to a PC steel stranded wire formed by twisting a plurality of PC steel strands and having a helical twist, an optical fiber may be installed at the twist. In this case, in order to measure the tension of the PC steel stranded wire up to the position of the wedge portion, an optical fiber is passed between the inner wall surface of the wedge portion and the PC steel stranded wire, and the inner wall surface of the wedge portion and the PC steel There is a possibility that the optical fiber is damaged by being pinched by the stranded wire. As a result, there is a possibility that a measurement error of the tension of the PC steel stranded wire may occur.

  Then, an object of this invention is to provide the fixing | fixed part structure and wedge body of PC steel twisted wire which can suppress the measurement error of the tension | tensile_strength of PC steel twisted wire.

  The fixing part structure of the PC steel stranded wire according to the present invention includes a PC steel stranded wire formed by twisting a plurality of PC steel strands and having a helical twist, and an optical fiber installed in the twist. A fixing portion structure of a PC steel stranded wire with an optical fiber for fixing the PC steel stranded wire with an optical fiber to the fixing portion, and a base portion for contacting the fixing portion and inserting the PC steel stranded wire with an optical fiber; A socket part that is installed behind the base part and allows the PC steel stranded wire with optical fiber to be inserted; a wedge part that is inserted from the rear between the inner wall surface of the socket part and the PC steel stranded wire with optical fiber; And a concave line portion extending along the fold is formed on the inner wall surface of the wedge portion.

  In this PC steel stranded wire fixing portion structure, a PC steel stranded wire with an optical fiber is inserted into the socket portion, and a wedge portion is inserted from the rear between the inner wall surface of the socket portion and the PC steel stranded wire with an optical fiber. Thus, the PC steel stranded wire with optical fiber is firmly held by the socket portion and the wedge portion, and the PC steel stranded wire with optical fiber is fixed to the fixing portion via the base portion. In this structure, the PC steel stranded wire with optical fiber is strongly pressed in the radial direction by the inner wall surface of the wedge portion. Here, the optical fiber of the PC steel stranded wire with optical fiber is installed at the twist of the PC steel stranded wire. On the other hand, the inner wall surface of the wedge part is formed with a concave line part extending along the fold. Therefore, it is possible to prevent the concave stripe portion from functioning as an escape of the optical fiber, and the pressing force from the inner wall surface of the wedge portion from acting directly on the optical fiber. Therefore, it is possible to suppress the optical fiber from being damaged by being sandwiched between the inner wall surface of the wedge portion and the PC steel stranded wire. As a result, the measurement error of the tension of the PC steel stranded wire can be suppressed.

  In the PC steel stranded wire fixing portion structure, the wedge portion has a wedge body including a tapered shape and an inner wall surface that contacts the PC steel stranded wire with an optical fiber, and the concave stripe portion is an inner portion of the wedge body. It may be a groove formed on the wall surface. In this case, the groove portion can be easily formed by this groove.

  Further, in the PC steel stranded wire fixing portion structure, the wedge portion has a tapered wedge body, and a cylindrical member interposed between the wedge body and the PC steel stranded wire with optical fiber. The concave stripe portion may be a slit along the twist formed in the cylindrical member. In this case, the concave strip portion can be easily formed by this cylindrical member.

  Moreover, in the fixing part structure of PC steel stranded wire, it is preferable that the width | variety of the groove part in the circumferential direction of PC steel stranded wire with an optical fiber is a width more than the width of the optical fiber in the circumferential direction. In this case, contact of the inner wall surface of the wedge body with the optical fiber is avoided, and damage to the optical fiber can be suitably suppressed.

  Moreover, this invention can also be grasped as invention of a wedge body, and this wedge body is formed by twisting a plurality of PC steel strands, and has a helical twist. An installed optical fiber, and a wedge body used in a fixing portion structure of a PC steel stranded wire for fixing a PC steel stranded wire with an optical fiber having a fixing portion to a fixing portion, The wedge body is provided with a base part that contacts the fixing part and allows the PC steel stranded wire with optical fiber to be inserted, and a socket part that is installed behind the base part and allows the PC steel stranded wire with optical fiber to be inserted. Between the inner wall surface of the socket part and the PC steel stranded wire with optical fiber, a groove extending along the twist is formed on the inner wall surface of the wedge body.

  This wedge body is inserted from the rear between the inner wall surface of the socket portion and the PC steel stranded wire with optical fiber inserted through the socket portion. Thereby, the PC steel stranded wire with optical fiber is firmly held by the socket portion and the wedge body, and the PC steel stranded wire with optical fiber is fixed to the fixing portion via the base portion. This wedge body strongly presses the PC steel stranded wire with an optical fiber in the radial direction by the inner wall surface of the wedge body. Here, the optical fiber of the PC steel stranded wire with optical fiber is installed at the twist of the PC steel stranded wire. On the other hand, a groove extending along the fold is formed on the inner wall surface of the wedge body. Therefore, the groove functions as a relief of the optical fiber, and it can be avoided that the pressing force from the inner wall surface of the wedge body acts directly on the optical fiber. Therefore, it is possible to suppress the optical fiber from being damaged by being sandwiched between the inner wall surface of the wedge portion and the PC steel stranded wire. As a result, the measurement error of the tension of the PC steel stranded wire can be suppressed.

  ADVANTAGE OF THE INVENTION According to this invention, the fixing | fixed part structure and wedge body of PC steel twisted wire which can suppress the measurement error of the tension | tensile_strength of PC steel twisted wire can be provided.

FIG. 1 is a diagram illustrating an overall configuration of a ground anchor to which a PC steel stranded wire fixing unit structure according to a first embodiment of the present invention is applied. Fig.2 (a) is a perspective view of PC steel twisted wire with an optical fiber. FIG. 2B is a perspective view showing an example of an optical fiber. FIG. 3 is a partial cross-sectional view showing a main part of the fixing structure of the PC steel stranded wire of FIG. FIG. 4 is an exploded perspective view showing the socket part and the wedge part according to the first embodiment. FIG. 5 is a perspective view showing grooves formed in the wedge body of FIG. FIG. 6 is an exploded perspective view showing a socket part, a wedge part, and a cylindrical member according to the second embodiment. FIG. 7A is a perspective view showing a cylindrical member and a slit formed by the cylindrical member. FIG. 7B is a development view of the cylindrical member.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of a fixing structure of a PC steel stranded wire and a wedge body according to the present invention will be described in detail with reference to the drawings. Note that in the description, the same elements or elements having the same function may be denoted by the same reference numerals, and redundant description will be omitted. In the following description, when terms having front and rear concepts such as “front”, “back”, “front end”, “rear end” are used, the upper side in FIG. 1 is the rear, and the lower side in FIG. 1 is the front. And

[First Embodiment]
FIG. 1 is a diagram showing an overall configuration of a ground anchor having a fixing structure of a PC steel stranded wire according to a first embodiment of the present invention. Fig.2 (a) is a perspective view of PC steel twisted wire with an optical fiber. FIG. 2B is a perspective view showing an example of an optical fiber. The PC steel stranded wire fixing portion structure 100 according to the present embodiment presses the fixing portion 101 which is a structure such as a retaining wall provided on the rock mass R to the rock mass R side, for example, on a dam and a slope. It is applied to the ground anchor 50 for ensuring the mechanical stability. The plurality of PC steel stranded wires constituting the ground anchor 50 do not necessarily have to be the PC steel stranded wire 1 with an optical fiber, and even if no optical fiber is attached to some PC steel stranded wires. Good. In the following description, “PC steel stranded wire with optical fiber 1” and “part of PC steel stranded wire with no optical fiber attached” may be collectively abbreviated as “PC steel stranded wire 1, 3”. .

  As shown in FIG. 1, the ground anchor 50 is provided inside a hole 103 drilled in the rock mass R and the fixing portion 101. The hole 103 is drilled in the bedrock R and the fixing portion 101 with a diameter of 90 to 165 mm, for example. In the ground anchor 50, the front end side of the PC steel stranded wires 1 and 3 is inserted into the hole 103 with a length of about 20 to 100 m, for example, and the rear end side of the PC steel stranded wires 1 and 3 is about 150 to 350 mm, for example. Now, it protrudes backward from the surface to be fixed 101a.

  The ground anchor 50 includes a head 51 including a PC steel stranded wire fixing portion structure 100, an anchor free length portion 52, an anchor body length portion 55, and a plurality of PC steel stranded wires. The head 51 is provided at the opening of the hole 103 in the fixing surface 101 a of the fixing unit 101. The head portion 51 fixes the rear ends of the PC steel stranded wires 1 and 3 to the fixing portion 101 by the PC steel stranded wire fixing portion structure 100. In the head 51, after a predetermined tension is applied to the PC steel stranded wires 1 and 3, the rear ends of the PC steel stranded wires 1 and 3 are fixed to the fixing portion 101 so as to maintain the tension. The Details of the PC steel stranded wire fixing part structure 100 will be described later.

  The anchor free long portion 52 is a portion where the PC steel stranded wires 1 and 3 are not fixed in the ground anchor 50 on the front side from the fixing surface 101a. In the anchor free long part 52, the PC steel stranded wires 1 and 3 extend so as to connect the head part 51 and the anchor body long part 55. The anchor free length portion 52 includes a presser plate 53 and an array plate 54 provided in the hole 103 of the fixing portion 101. The holding plate 53 is inserted with the PC steel stranded wires 1 and 3, and seals the hole 103 between the fixed surface 101 a and the array plate 54. PC steel stranded wires 1 and 3 are inserted through the array plate 54. The array plate 54 aligns the PC steel stranded wires 1 and 3 so that the PC steel stranded wires 1 and 3 are substantially parallel to each other behind the array plate 54.

  The anchor body length portion 55 is a portion for fixing the front end portions of the PC steel stranded wires 1 and 3 in the ground anchor 50. The anchor body length portion 55 has a load-bearing body 56 for fixing the front end portions of the PC steel stranded wires 1 and 3 continuously extending from the anchor free length portion 52. In the anchor body long portion 55, a plurality of load bearing bodies 56 are provided in series. The load-bearing bodies 56 are arranged at a predetermined pitch (for example, every 1.5 m) along the PC steel stranded wires 1 and 3. The number of load-bearing bodies 56 is, for example, the number obtained by dividing the number of installed PC steel stranded wires 1 and 3 by two. The number of installed PC steel stranded wires 1 and 3 is not particularly limited, but may be an even number (4 in this case).

The load-bearing body 56 includes a load-bearing body main body 57 in which the front ends of the PC steel stranded wires 1 and 3 are disposed, a reinforcing bar 58 provided so as to surround the PC steel stranded wires 1 and 3 behind the load-bearing body main body 57, and Have
The load-bearing body main body 57 is a columnar member formed by casting aluminum alloy or the like, for example. The load-resistant body 57 can be inserted with a fixing portion for fixing the PC steel stranded wires 1 and 3 fixed by the load-resistant body 57 and the PC steel stranded wires 1 and 3 not fixed by the load-resistant body 57. Through holes are provided. The load-bearing body main body 57 is provided with, for example, two fixing portions, and is provided with a number of through-holes that is two less than the number of PC steel stranded wires 1 and 3 installed.

  In the load-bearing body main body 57 other than the foremost end of the anchor body long portion 55, the PC steel stranded wires 1 and 3 fixed by the load-bearing body main body 57 are fixed to the fixing portion, and extended to the front side of the load-bearing body main body 57. PC steel stranded wires 1 and 3 are inserted into the through holes. In the load bearing body main body 57 at the foremost end of the anchor body long portion 55, the PC steel stranded wires 1 and 3 fixed by the load bearing body main body 57 are fixed to the fixing portion.

  The reinforcing bars 58 are metal spring-like members provided behind the respective load-bearing body main bodies 57. The reinforcing bars 58 extend three-dimensionally in the filler 5 behind each load-bearing body main body 57, and reinforce the strength of the surrounding filler 5.

  The hole 103 in the anchor free length portion 52 is filled with the filler 5 on the front side of the presser plate 53. The hole 103 in the anchor body long part 55 is filled with the filler 5 continuously from the anchor free long part 52. The filler 5 is, for example, cement milk, mortar, or the like, and is filled in the hole 103 and cured in order to fix the PC steel stranded wires 1 and 3 in the hole 103.

  As shown in FIG. 2, the PC steel stranded wire with optical fiber 1 includes a PC steel stranded wire 3 and an optical fiber member 20 attached to the surface of the PC steel stranded wire 3. The PC steel stranded wire 3 is a stranded wire formed by twisting a plurality of (seven in this embodiment) PC steel strands 4 made of, for example, strand steel material and having the same diameter. On the surface of the PC steel stranded wire 3, a twist line 3a of the PC steel stranded wire 3 is formed as a valley between two adjacent PC steel strands 4, 4. The valley is inclined at a predetermined angle on the surface of the PC steel stranded wire 3 with respect to the bus bar extending in parallel with the axis A of the PC steel stranded wire 3 and extends in a spiral shape with the axis A as the center. In other words, the PC steel stranded wire 3 has a helical twist 3a. The surface of the PC steel stranded wire 3 is provided with a coating (sheath) for preventing corrosion.

  The optical fiber members 20 are respectively installed on two of the twisted lines 3a and extend in a spiral shape. Each optical fiber member 20 is installed so as to be embedded in the valley, and extends in a spiral manner between the adjacent PC steel wires 4, 4 along the adjacent PC steel wires 4, 4. It is installed to do. The optical fiber member 20 includes an optical fiber main body 21 embedded in the center thereof, and a resin filler 22 surrounding the optical fiber main body 21. The filler 22 is made of, for example, polyethylene resin. The optical fiber main body 21 has an optical fiber strand 23 and a coating 24 that covers the optical fiber strand 23. The coating 24 is made of, for example, a polyamide-based material.

  FIG. 3 is a partial cross-sectional view showing a main part of the fixing structure of the PC steel stranded wire of FIG. As shown in FIG. 3, the PC steel stranded wire fixing portion structure 100 includes a base portion 11 that abuts on the fixing surface 101 a of the fixing portion 101 and allows the PC steel stranded wires 1 and 3 to pass therethrough, and a base portion 11. The socket part 13 which is installed behind the PC steel stranded wires 1 and 3 and is inserted between the inner wall surface 13s of the tapered hole 13a of the socket part 13 and the PC steel stranded wires 1 and 3 16.

  The base portion 11 is a bearing plate that supports the tension of the PC steel stranded wires 1 and 3. The base part 11 has a circular opening 11a through which a plurality of PC steel stranded wires 1 and 3 are inserted. The base portion 11 is formed with a plurality of screw holes for attaching a cap member 14 to be described later. Between the base part 11 and the socket part 13, a columnar spacer member 12 having a through hole through which the PC steel stranded wires 1 and 3 are inserted is inserted. The diameter of the front surface of the spacer member 12 is larger than the diameter of the circular opening 11a. The socket portion 13 is a columnar member disposed on the rear surface of the spacer member 12. As an example, the diameter of the front surface of the socket portion 13 is smaller than the diameter of the rear surface of the spacer member 12.

  The spacer member 12 and the socket part 13 are covered with a cap member 14. The cap member 14 has a hat shape, and is fixed by screwing a bolt B into a screw hole of the base portion 11. An O-ring 14 c is disposed between the cap member 14 and the base portion 11, and a sealed space is defined by the cap member 14 and the base portion 11. This sealed space includes a space behind the presser plate 53 in the hole 103. This sealed space is filled with rust preventive oil 15. The rust preventive oil 15 is injected through the injection port 14a. At the top of the cap member 14, an exhaust port 14 b for discharging the air in the sealed space is provided.

  FIG. 4 is an exploded perspective view showing the socket part and the wedge part. As shown in FIG. 4, the socket portion 13 is formed with a taper hole 13 a through which a plurality (four in this case) of PC steel stranded wires 1 and 3 are inserted. The tapered hole 13a has a conical surface formed such that its inner wall surface 13s decreases in diameter toward the front.

  The wedge portion 16 functions as a wedge in a state where it is inserted from the rear between the inner wall surface 13s of the tapered hole 13a and the PC steel stranded wires 1 and 3 (hereinafter also simply referred to as “inserted state”). The wedge portion 16 has a truncated cone (tapered) wedge body 17 having a through hole in the center. The outer wall surface of the wedge body 17 is a conical surface corresponding to the inner wall surface 13s of the tapered hole 13a. The inner wall surface 17 d of the wedge body 17 is a cylindrical surface corresponding to the outer peripheral surface of the PC steel stranded wires 1 and 3, and is in close contact with the outer peripheral surface of the PC steel stranded wires 1 and 3. As an example, the wedge body 17 includes three wedge pieces 17a, 17b, and 17c that are formed by being divided into three in the circumferential direction.

  As shown in FIG. 3, in the inserted state, the wedge pieces 17a to 17c are arranged at equal intervals so as to surround the PC steel stranded wires 1 and 3 in the circumferential direction. The front end surfaces 17t of the wedge pieces 17a to 17c are substantially flush with the front surface of the socket portion 13. The rear ends of the wedge pieces 17 a to 17 c protrude rearward from the rear surface of the socket portion 13. The rear end portions of the PC steel stranded wires 1 and 3 protrude further rearward from the rear end surfaces 17u of the wedge pieces 17a to 17c.

  The wedge body 17 is inserted from the rear between the inner wall surface 13 s of the tapered hole 13 a of the socket portion 13 and the PC steel stranded wires 1 and 3 inserted through the socket portion 13. The wedge body 17 functions as a wedge between the socket portion 13 and the PC steel stranded wires 1 and 3. Specifically, in the inserted state, the wedge bodies 17 respectively press the inner wall surface 13s of the tapered hole 13a of the socket portion 13 and the PC steel stranded wires 1 and 3 inserted through the socket portion 13. When a predetermined tension is applied to the PC steel stranded wires 1 and 3, the wedge body 17 presses the PC steel stranded wires 1 and 3 more strongly, so that the PC steel stranded wires 1 and 3 are firmly held. Thus, the PC steel stranded wires 1 and 3 are fixed to the fixing portion 101 so as to support the tension. At this time, the wedge body 17 strongly presses the PC steel stranded wires 1 and 3 in the radial direction by the inner wall surface 17 d of the wedge body 17.

  Next, the structure for suppressing the measurement error of the tension | tensile_strength of the PC steel twisted wire 1 with an optical fiber is demonstrated in detail with reference to FIGS.

  On the inner wall surface 17 d of the wedge body 17, a concave line portion 30 is formed that extends along the strand 3 a of the PC steel stranded wire 3. Specifically, as shown in FIG. 5, at least one of the wedge pieces 17 a to 17 c (here, the wedge piece 17 a) extends along the twist line 3 a of the PC steel stranded wire 3 on the inner wall surface thereof. A groove 31 is formed. Here, the length of the wedge body 17 is, for example, about 3 to 4 times the outer diameter of the PC steel stranded wire 3. The pitch of the strand 3a of the PC steel stranded wire 3 is, for example, about 10 times the outer diameter of the PC steel stranded wire 3. In this case, by forming the groove 31 in any one of the wedge pieces 17a to 17c, the optical fiber member 20 can face only the inner wall surface of the wedge piece in the inserted state. Therefore, in the present embodiment, as an example, the groove portion 30 is formed by forming the groove 31 in the inner wall surface 17s of the wedge piece 17a. The inner wall surface 17s is a cylindrical surface that constitutes a part of the inner wall surface 17d.

  The groove 31 is inclined at a predetermined angle on the inner wall surface 17 s of the wedge piece 17 a with respect to a generatrix extending parallel to the axis C of the wedge body 17, and extends in a spiral shape with the axis C as the center. In the inserted state, the axis A of the PC steel stranded wire 3 and the axis C of the wedge body 17 substantially coincide. That is, the groove | channel 31 is extended along the helical strand 3a of the PC steel strand 3 in the insertion state.

  The width of the groove 31 in the circumferential direction of the wedge body 17 (the circumferential direction of the PC steel stranded wire with optical fiber 1 in the inserted state) is equal to or greater than the width of the optical fiber member 20 in the circumferential direction of the PC steel stranded wire with optical fiber 1. It is formed to have a width of. The groove 31 is formed such that the depth in the thickness direction of the wedge body 17 (the circumferential direction of the PC steel stranded wire with optical fiber 1 in the inserted state) is greater than or equal to the outer diameter of the optical fiber member 20. ing.

  When the wedge body 17 is inserted from the rear between the inner wall surface 13s of the tapered hole 13a and the PC steel stranded wires 1 and 3, the groove 31 is made to follow the optical fiber member 20 of the PC steel stranded wire 1 with optical fiber. This functions as a relief of the optical fiber member 20. In other words, the portion of the inner wall surface 17d of the wedge body 17 where the groove 31 is not formed presses the PC steel stranded wires 1 and 3 in the radial direction. Therefore, in the groove 31, it is avoided that the pressing force from the inner wall surface 17 d of the wedge body 17 is directly applied to the optical fiber member 20.

  As described above, in the PC steel stranded wire fixing portion structure 100 according to this embodiment, the PC fiber stranded wire with optical fiber 1 is inserted into the socket portion 13, and the inner wall surface 13 s of the tapered hole 13 a of the socket portion 13 By inserting the wedge body 17 between the PC steel stranded wire with optical fiber 1 from the rear, the PC steel stranded wire with optical fiber 1 is firmly held by the socket portion 13 and the wedge body 17, and the base portion 11 is removed. Then, the PC steel stranded wire with optical fiber 1 is fixed to the fixing portion 101. In this structure, the PC steel stranded wire with optical fiber 1 is strongly pressed in the radial direction by the inner wall surface 17 d of the wedge body 17. Here, the optical fiber member 20 of the PC steel stranded wire 1 with an optical fiber is installed in the twist line 3 a of the PC steel stranded wire 3. On the other hand, a groove 31 extending along the twist 3a is formed on the inner wall surface 17s of the wedge piece 17a. Therefore, the groove 31 functions as a relief of the optical fiber member 20, and it can be avoided that the pressing force from the inner wall surface 17 d of the wedge body 17 directly acts on the optical fiber strand 23. Therefore, it is possible to prevent the optical fiber 23 from being damaged by being sandwiched between the inner wall surface 17d of the wedge body 17 and the PC steel stranded wire 3. As a result, it is possible to suppress the measurement error of the tension of the PC steel stranded wire 1 with an optical fiber.

  In the PC steel stranded wire fixing part structure 100, the wedge body 17 has a wedge body 17 having an inner wall surface 17 d in contact with the PC steel stranded wire 1 with an optical fiber while having a tapered shape. Is a groove 31 formed in the inner wall surface 17s of the wedge piece 17a. Thereby, the groove part 30 can be easily formed by the groove 31.

  Moreover, in the fixing part structure 100 of PC steel stranded wire, it is preferable that the width of the groove 31 in the circumferential direction of the PC steel stranded wire with optical fiber 1 is equal to or larger than the width of the optical fiber member 20 in the circumferential direction. Thereby, the contact of the inner wall surface 17s of the wedge piece 17a with the optical fiber member 20 is avoided, and the optical fiber strand 23 can be suitably suppressed from being damaged.

  The wedge body 17 according to the present embodiment is inserted from the rear between the inner wall surface 13s of the tapered hole 13a of the socket portion 13 and the PC steel stranded wire with optical fiber 1 inserted through the socket portion 13. Thereby, the PC steel stranded wire with optical fiber 1 is firmly held by the socket portion 13 and the wedge body 17, and the PC steel stranded wire with optical fiber 1 is fixed to the fixing portion 101 via the base portion 11. The wedge body 17 strongly presses the PC steel stranded wire 1 with an optical fiber in the radial direction by the inner wall surface 17 d of the wedge body 17. Here, the optical fiber member 20 of the PC steel stranded wire 1 with an optical fiber is installed in the twist line 3 a of the PC steel stranded wire 3. On the other hand, a groove 31 extending along the twist 3a is formed on the inner wall surface 17s of the wedge piece 17a. Therefore, the groove 31 functions as a relief of the optical fiber member 20, and it can be avoided that the pressing force from the inner wall surface 17 d of the wedge body 17 directly acts on the optical fiber strand 23. Therefore, it is possible to prevent the optical fiber 23 from being damaged by being sandwiched between the inner wall surface 17d of the wedge body 17 and the PC steel stranded wire 3. As a result, it is possible to suppress the measurement error of the tension of the PC steel stranded wire 1 with an optical fiber.

  In the conventional PC steel twisted wire fixing portion structure, when the optical fiber member is pressed by the wedge body, the optical fiber member is not passed between the inner wall surface of the wedge body and the PC steel twisted wire. Furthermore, it is necessary to pull out the optical fiber member from the PC steel stranded wire with optical fiber on the front side of the wedge body and fix the PC steel stranded wire with optical fiber. If it does so, the tension | tensile_strength of PC steel twisted wire cannot be measured to the position of a wedge body, and the latest distortion data of a wedge body cannot be taken. Originally, the nearest part of the wedge body is most likely to cause the failure of the PC steel stranded wire, so the nearest part of the wedge body can measure the tension of the PC steel stranded wire most (that is, measure the strain of the optical fiber strand). This is the desired part. On the other hand, in the fixing part structure 100 of the PC steel stranded wire, the optical fiber member 20 is passed from the end face of the PC steel stranded wire 1 with an optical fiber through the optical fiber member 20 between the 17d of the wedge body 17 and the PC steel stranded wire 3. Since it can be pulled out, it is possible to measure the tension of the PC steel stranded wire 1 with an optical fiber up to the nearest part of the wedge body 17.

  In addition, in the fixing part structure 100 of the PC steel stranded wire, two optical fiber members 20 are attached to one PC steel stranded wire 1 with an optical fiber, and the two optical fiber members 20 are connected to a PC with an optical fiber. The optical fiber member 20 is pulled out from the end face on one end side of the stranded steel wire 1 and connected to the one end side to form a double-length reciprocating optical fiber member 20, and the two optical fiber members 20 on the other end side. It is often the case that the end of each is connected to a predetermined strain analyzer. If it carries out like this, when measuring the distortion | strain of the optical fiber strand 23 about the one PC steel twisted wire 1 with an optical fiber, the distortion data for reciprocation can be taken. At this time, as described above, since the two optical fiber members 20 can be pulled out from the end face on one end side of the PC steel stranded wire 1 with optical fiber, the work of connecting the optical fiber strands 23 to each other on the one end side is facilitated. It can be carried out.

[Second Embodiment]
A second embodiment of the present invention will be described with reference to FIGS. The present embodiment is different from the first embodiment in the structure for forming the concave line portion 30 that functions as a relief of the optical fiber member 20. Specifically, as shown in FIG. 6, the wedge portion 16 includes a wedge body 47 having a tapered shape, and a cylindrical member 48 interposed between the wedge body 47 and the PC steel stranded wires 1 and 3. And having. The wedge body 47 has wedge pieces 47a to 47c. The wedge pieces 47 a to 47 c differ from the wedge pieces 17 a to 17 c in that the groove 31 is not provided and that the thickness is thinner by the thickness of the cylindrical member 48. Other than that, it is comprised similarly to the wedge body 17. FIG.

  FIG. 7A is a perspective view showing a cylindrical member and a slit formed by the cylindrical member. As shown in FIG. 7A, the cylindrical member 48 has the same length as the wedge body 47, and has an inner wall surface 48a and an outer wall surface 48b. The inner wall surface 48 a of the cylindrical member 48 is overlaid on the outer peripheral surface of the PC steel stranded wires 1 and 3. The outer wall surface 48 b of the cylindrical member 48 is overlaid on the inner wall surface 47 d of the wedge body 47. The surface of the inner wall surface 48a of the cylindrical member 48 is preferably roughened by shot blasting or sand blasting. As an example, since there are 15.2 mm outer diameter and 15.7 mm outer diameter as the standard size of the outer diameter of the PC steel stranded wire, the outer diameter d1 of the cylindrical member 48 is 15.7 mm. The inner diameter d2 of 48 is preferably 15.2 mm. In this case, a PC steel stranded wire having an outer diameter of 15.2 mm and a wedge body for a PC steel stranded wire having an outer diameter of 15.7 mm can be used, which is advantageous in terms of availability of members. The cylindrical member 48 can be made of a thin steel plate having a thickness of 0.25 mm.

  The cylindrical member 48 has an outer edge 48c, an outer edge 48d, an outer edge 48e, and an outer edge 48f. The cylindrical member 48 is formed with slits 32 extending along the outer edge 48d and the outer edge 48f. The slit 32 constitutes a concave line portion 30 that extends along the strand 3 a of the PC steel stranded wire 3.

  FIG. 7B is a development view of the cylindrical member. As shown in FIG. 7 (b), the shape of the plate material in which the cylindrical member 48 is developed on a plane with the slit 32 as both ends (with the outer edge 48d and the outer edge 48f as both ends) (hereinafter simply referred to as "deployed shape"). Is also a parallelogram. In the developed shape, the angle θ of the base length L1, height L2, acute diagonal (the angle formed by the outer edge 48c and the outer edge 48d, and the angle formed by the outer edge 48e and the outer edge 48f) is determined by twisting the slit 32 into the PC steel. In order to extend along the strand 3 a of the wire 3, it is preferably defined as follows.

For example, when the outer diameter of the PC steel stranded wire 3 having seven PC steel strands 4 is 15.2 mm, the circumference of the circumscribed circle of the PC steel stranded wire 3 is about 47.75 mm. In this PC steel stranded wire 3, as a standard size of the PC steel stranded wire, the length (twist pitch) of the twist line 3a is about 200 mm. From this, the crossing angle between the plane perpendicular to the axis of the PC steel stranded wire 3 and the strand 3a is determined as an angle substantially equal to the diagonal of the parallelogram having a base of 47.75 mm and a height of 200 mm. Can do. The diagonal angle θ is approximately 76.6 ° according to the following equation (1).
tan ⁻¹ (47.75 / 200) = 76.6 (1)

  The expanded parallelogram may be any shape that is substantially similar to the parallelogram having a base of 47.75 mm and a height of 200 mm and that forms the slit 32. The base length L1 is a length obtained by subtracting a width (here 2 mm) that is equal to or greater than the width of the optical fiber member 20 in the circumferential direction of the PC steel stranded wire with optical fiber 1 from a predetermined coefficient multiple of about 45.75 mm. And the height L2 is a length of the predetermined coefficient multiple of about 200 mm. For example, when the diameter of the circumscribed circle of each PC steel strand 4 is 15.2 mm in the PC steel twisted wire 3 composed of seven PC steel strands 4, the inner wall surface 48a of the cylindrical member 48 is connected to each PC steel strand. In order to come into contact with the wire 4, the base length L1 is preferably about 39.8 mm or more.

  The cylindrical member 48 can be formed by rounding the parallelogram plate material configured in this way, and the slit 32 has a spiral shape and the outer peripheral surface of the cylindrical member 48 at the same pitch as the twist pitch of the twist 3a. It will extend along the twisted line 3a. Then, by overlapping the wedge body 47 and the cylindrical member 48, the concave strip portion 30 is formed by the inner wall surface 47d of the wedge body 47 and the side surfaces (outer edges 48d, 48f) of the slit 32.

  This recessed strip part 30 can be made into the position suitable for the twist 3a in which the optical fiber member 20 extends in PC steel twisted wire 1 with an optical fiber. Further, the width of the recess 30 is the width of the slit 32 according to the width of the optical fiber member 20 (for example, 2 mm). For this reason, it is avoided that the cylindrical member 48 and the optical fiber member 20 contact in the circumferential direction of the PC steel stranded wire 3. That is, the slit 32 along the twisted line 3 a functions as a relief of the optical fiber member 20, and the compression force from the inner wall surface 47 d of the wedge body 47 directly acts on the optical fiber strand 23 via the cylindrical member 48. Avoided. As a result, the same effect as the first embodiment is achieved.

  As mentioned above, although embodiment of this invention was described, this invention is not restricted to the said embodiment, You may change in the range which does not change the summary described in each claim.

  For example, the present invention is not limited to the case where the present invention is applied to the PC steel stranded wire 3 having the seven PC steel strands 4 as in the above embodiment. For example, the 19 stranded PC steel stranded wire or other PC The same applies to steel stranded wires.

  In the above embodiment, the four taper holes 13a are formed in the socket part 13, but the number of the taper holes 13a is not limited to this. In addition, the wedge bodies 17 and 47 are divided into three wedge pieces by dividing the wedge bodies into three in the circumferential direction, but the number of wedge bodies divided (the number of wedge pieces constituting one wedge body) is not limited to this. . Moreover, although the two optical fiber members 20 were attached to PC steel twisted wire 1 with an optical fiber, the number of the optical fiber members 20 is not limited to this.

  In the said embodiment, although the base part 11 and the socket part 13 were separate bodies and the taper hole 13a was formed in the socket part 13, it is comprised as a member with which the base part 11 and the socket part 13 were integrated, the said A tapered hole similar to the tapered hole 13a may be directly formed in the member.

  DESCRIPTION OF SYMBOLS 1 ... PC steel twisted wire with optical fiber, 3 ... PC steel twisted wire, 3a ... Twist, 4 ... PC steel strand, 11 ... Base part, 13 ... Socket part, 13s ... Inner wall surface, 16 ... Wedge part, 17 ... Wedge body, 17d, 17s ... Inner wall surface, 20 ... Optical fiber member (optical fiber), 30 ... Recess, 31 ... Groove, 32 ... Slit, 47 ... Wedge body, 47d ... Inner wall surface, 48 ... Cylindrical member , 100: PC steel stranded wire fixing portion structure, 101: fixing portion.

Claims (5)

A PC steel stranded wire with an optical fiber having a PC steel stranded wire formed by twisting a plurality of PC steel strands and having a spiral fold, and an optical fiber installed in the fold, is used as a fixing portion. It is a fixing part structure of a PC steel stranded wire with an optical fiber to be fixed,
A base part that is in contact with the fixing part and through which the PC steel stranded wire with optical fiber is inserted;
A socket part installed behind the base part and allowing the PC-fiber stranded wire with optical fiber to be inserted;
A wedge part inserted from the rear between the inner wall surface of the socket part and the PC steel stranded wire with optical fiber,
A fixing portion structure of a PC steel stranded wire, wherein an inner wall surface of the wedge portion is formed with a concave strip portion extending along the twist line. The wedge part has a wedge body including the inner wall surface that is tapered and contacts the PC steel stranded wire with optical fiber,
2. The fixing structure of a PC steel stranded wire according to claim 1, wherein the recess is a groove formed in the inner wall surface of the wedge body. The wedge part includes a wedge body having a tapered shape, and a cylindrical member interposed between the wedge body and the PC steel stranded wire with an optical fiber,
2. The fixing structure of a PC steel stranded wire according to claim 1, wherein the recess is a slit along the twist formed in the cylindrical member.   The PC steel according to any one of claims 1 to 3, wherein a width of the concave strip portion in the circumferential direction of the PC steel stranded wire with optical fiber is equal to or greater than a width of the optical fiber in the circumferential direction. Twisted wire fixing part structure. A PC steel stranded wire with an optical fiber having a PC steel stranded wire formed by twisting a plurality of PC steel strands and having a spiral fold, and an optical fiber installed in the fold, is used as a fixing portion. A wedge body used for a fixing structure of a PC steel stranded wire to be fixed,
The fixing part structure of the PC steel stranded wire is
A base part that is in contact with the fixing part and through which the PC steel stranded wire with optical fiber is inserted;
A socket part installed behind the base part and allowing the PC fiber stranded wire with optical fiber to pass therethrough, and
The wedge body is inserted from the rear between the inner wall surface of the socket part and the PC steel stranded wire with optical fiber, and a groove extending along the twist is formed on the inner wall surface of the wedge body. Wedge body that has been.

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