JP2012005203A - Double torsional damper - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a double torsional damper in which an inhibit wire of the double torsional damper has a weight drop prevention mechanism for preventing breakage of the inhibit wire and dropping of a weight and which facilitates breakage detection.SOLUTION: An inhibit wire 10 is composed of a core and a plurality of outer periphery wires each having the same outside diameter, in which the plurality of outer periphery wires are twisted together around the periphery of the core. One of the core or the plurality of outer periphery wires is higher in fatigue limit than other wires.

Description

  More particularly, the present invention relates to a double torsional damper in which a suppression wire of the double torsional damper has a weight drop prevention mechanism.

  When wind blows on the overhead electric wire, Karman vortex, which is a cross-spreading vortex, is generated on the leeward side of the electric wire, and vibration having an amplitude of 1 to several tens of millimeters is generated. This vibration gives repeated stress to the electric wire at the reflection point of vibration such as a suspension support point or a tension clamp which becomes a fixed point of the overhead electric wire, and causes the metal fatigue deterioration and breakage with time. In order to prevent this, a vibration preventing device is attached in the vicinity of the support point of the overhead electric wire.

  FIG. 1 is a damper configuration diagram showing the configuration of a double torsional damper that is a vibration preventing device. In FIG. 1, the double torsional damper 110 includes a restraining wire 10, a weight 20, and a wire gripping clamp 30. The weight 20 includes a fixing portion 25 that is fixed to the suppression wire 10, and is fixed to both ends of the suppression wire 10. The wire gripping clamp 30 includes a clamp portion 35 that grips the overhead wire 40 and a restraining wire compression hole 37 that is fixed to the restraining wire 10, and the restraining wire compression hole 37 is compressed at the center of the restraining wire 10. The restraining wire 10 is fixed and attached to the overhead electric wire 40 by the clamp portion 35.

  In the double torsional damper 110 of FIG. 1, the vibration of Karman vortex generated by the wind is transmitted to the restraining wire 10 and the weights 20 at both ends via the clamp portion 35. As a result, a new vibration is generated in the suppression line 10. This new vibration has a phase and period different from those of the Karman vortex, and acts to cancel the vibration of the Karman vortex, thereby preventing the fatigue and breakage of the overhead wire 40 over time.

  FIG. 11 is a configuration diagram showing a configuration of a conventional inhibition line. In FIG. 11, the conventional deterrence wire 50 is composed of the same core wire 51 and a plurality of outer peripheral wires 52, and the plurality of outer peripheral wires 52 are twisted around the core wire 51. Conventionally, this inhibition line 50 has been used as the inhibition line 10 in FIG. However, when new vibrations that act to cancel vibrations due to Karman vortices are repeatedly generated in the suppression line 50 over a long period of time, the same core wire 51 of the suppression line 50 and the plurality of outer peripheral lines 52 rub against each other. As a result, there was an accident in which the metal 20 was deteriorated and fractured, and the weight 20 dropped.

  In Patent Document 1, a wire rope having a predetermined length is inserted and bent through insertion holes provided on the left and right sides of a fall prevention plate attached to a cap of a clamp body, and the vicinity of a vibration node when a weight undergoes secondary resonance. The end of the wire rope is collectively compressed and fixed to the weight by the dovetail sleeve, and the wire rope is at least of the deterrent line so that tension does not act on the wire rope even if the deterrence line resonates and swings excessively. There is a description that the length is 10 to 20% or more from the length.

Japanese Patent Application No. 2006-230172

  The present invention has been made in order to solve such a problem. The purpose of the present invention is to prevent the weight of the double torsional damper from having a weight fall-preventing mechanism. Provided is a double torsional damper that does not fall and is easy to find a fracture.

  The double torsional damper of the present invention is a double torsional damper comprising a deterrence line, a weight fixed to both ends of the deterrence line, and a wire gripping clamp fixed to the center part of the deterrence line. A core wire and a plurality of outer peripheral wires, and a plurality of outer peripheral wires are twisted around the core wire, and one of the core wires or the plurality of outer peripheral wires is fatigued compared to other wires. It is characterized by a high limit.

  The double torsional damper of the present invention is characterized in that one of the core wire or the plurality of outer peripheral wires is composed of a composite twisted wire.

  The composite stranded wire constituting the core wire of the double torsional damper of the present invention has slack in the core wire portion with respect to the plurality of outer peripheral wires, and the composite stranded wire that is one of the plurality of outer peripheral wires is the other It has slackness with respect to a plurality of outer peripheral lines.

  The double torsional damper of the present invention is a double torsional damper comprising a deterrence line, a weight fixed to both ends of the deterrence line, and a wire gripping clamp fixed to the center part of the deterrence line. Each space formed by the core wire and the plurality of outer periphery lines around the core wire has a fatigue limit compared to the core wire and the plurality of outer periphery lines. It has a high fine wire, and a plurality of outer peripheral wires and the plurality of fine wires are twisted around the core wire.

  In the double torsional damper of the present invention, the thin wire made of a material having a high fatigue limit is continuous as a single thin wire.

  The double torsional damper of the present invention is a double torsional damper comprising a deterrence line, a weight fixed to both ends of the deterrence line, and a wire gripping clamp fixed to the center part of the deterrence line. A core wire and a plurality of outer peripheral wires, and a thin wire having a higher fatigue limit than that of the core wire and the plurality of outer peripheral wires is wound around the core wire at a predetermined pitch. A plurality of outer peripheral wires are wound at a pitch smaller than a winding pitch at which the outer peripheral wires are twisted together.

  The double torsional damper of the present invention is a double torsional damper composed of a deterrence line and a weight fixed to both ends of the deterrence line and an electric wire gripping clamp fixed to the center part of the deterrence line. A plurality of outer peripheral lines are wound around a core line composed of an in-pipe insertion line inserted into the pipe.

  The double torsional damper of the present invention is a double torsional damper comprising a deterrence line, a weight fixed to both ends of the deterrence line, and an electric wire gripping clamp fixed to the center part of the deterrence line. A plurality of outer peripheral lines are wound around, and a thin line having a low fatigue limit is similarly wound around each gap formed by the plurality of outer peripheral lines.

  According to the present invention, since the deterrence wire of the double torsional damper has a mechanism for preventing the weight from falling, the weight of the deterrence wire is prevented from falling due to the breakage of the deterrence wire. A double torsional damper that can be discovered and exchanged can be provided.

The damper block diagram which shows the structure of a double torsional damper. The block diagram which shows the structure of the suppression line which shows 1st Example by this invention. The block diagram which shows the structure of the suppression line which shows the 2nd Example by this invention. The block diagram which shows the structure of the suppression line which shows the 3rd Example by this invention. The block diagram which shows the structure of the suppression line which shows the 4th Example by this invention. The block diagram which shows the structure of the suppression line which shows the 5th Example by this invention. The block diagram which shows the structure of the suppression line which shows the 6th Example by this invention. The block diagram which shows the structure of the suppression line which shows the 7th Example by this invention. The 1st detection figure which shows the fracture | rupture detection example of the suppression line by this invention. The 2nd detection figure which shows the fracture | rupture detection example of the suppression line by this invention. Sectional structure figure which shows the structure of the conventional suppression line.

  Embodiments of the present invention will be described with reference to the drawings. FIG. 2 is a block diagram showing the configuration of the inhibition line according to the first embodiment of the present invention. In FIG. 2 a-1, the restraining wire 10-1 is composed of a core wire 11 having the same outer diameter, one outer peripheral wire 12 ′, and five outer peripheral wires 11, and one outer periphery around the core wire 11. The wire 12 'and the five outer peripheral wires 11 are twisted together. In addition, this one outer peripheral line 12 ′ has a higher fatigue limit than the core wire 11 and the other five outer peripheral lines 11. FIG. 2 a-2 is a view in the longitudinal direction of the suppression line 10-1.

  In FIG. 2 b-1, the restraining wire 10-2 is composed of a core wire 12 having the same outer diameter and six outer peripheral wires 11, and six outer peripheral wires 11 are twisted around the core wire 12. ing. Further, the core wire 12 has a higher fatigue limit than the six outer peripheral wires 11. FIG. 2 b-2 is a view in the longitudinal direction of the suppression line 10-2.

  The case where these inhibition lines 10-1 and 10-2 are used for the inhibition lines 10 in FIG. 1 will be described. As in the case of the conventional deterrence line 50, when new vibrations that act to cancel vibrations due to Karman vortices are repeatedly generated in the deterrence lines 10-1 and 10-2 over a long period, The -2 core wire and the plurality of outer peripheral wires cause fatigue deterioration by friction with each other. However, one outer peripheral line 12 ′ in FIG. 2 a-1 has a higher fatigue limit than the core wire 11 and the other five outer peripheral lines 11, and the core wire 12 in FIG. This has a higher fatigue limit than the outer peripheral line 11.

  For this reason, repeated stress is generated over a long period of time, and even if the core wire 11 and the other five outer peripheral lines 11 in FIG. 2a-1 break, one outer peripheral line 12 'does not break, and FIG. Even if the six outer peripheral wires 11 in 1 are broken, the core wire 12 is not broken. For this reason, the accident that the weight 20 falls is prevented, and it can replace | exchange for the new double torsional damper 100 by discovering abnormality of a suppression line at the time of a periodic inspection.

  FIG. 3 is a block diagram showing the configuration of the inhibition line according to the second embodiment of the present invention. In FIG. 3 a, the restraining wire 10-3 is composed of a core wire 13 having the same outer diameter and six outer peripheral wires 11, and six outer peripheral wires 11 are twisted around the core wire 13. Yes. The core wire 13 is composed of a composite stranded wire. Moreover, in FIG. 3a ', the core wire 13 is comprised so that the magnitude | size of a shape change can be adjusted by changing the amount of slack of a composite twisted wire. In FIG. 3 b, the restraining wire 10-4 is composed of a core wire 11 having the same outer diameter, one outer peripheral wire 13 ′, and five outer peripheral wires 11, and one outer peripheral wire 13 around the core wire 11. 'And five outer peripheral wires 11 are twisted together. The one outer peripheral wire 13 'is composed of a composite stranded wire. Further, in FIG. 3 b ′, one outer peripheral line 13 ′ is configured to change the slack amount of the composite stranded wire with respect to the other outer peripheral line 11.

  In this case, even if the stress is repeatedly generated over a long period of time and the six outer peripheral wires 11 in FIG. 3a are broken, the core wire 13 is not broken because it is a composite twisted wire, and the core in FIG. Even if the wire 11 and the other five outer peripheral wires 11 are broken, one outer peripheral wire 13 'is not broken because it is similarly a composite twisted wire. For this reason, the accident that the weight 20 falls is prevented, and it can replace | exchange for the new double torsional damper 100 by discovering abnormality of a suppression line at the time of a periodic inspection. Further, by providing the slack as shown in FIGS. 3a ′ and 3b ′, the amount of bending of the deterrence line 10-3 at the time of breakage is increased, and the abnormality of the deterrence line 10-3 can be easily found.

  FIG. 4 is a block diagram showing the configuration of the inhibition line according to the third embodiment of the present invention. In FIG. 4, the restraining wire 10-6 has a core wire 11 and an outer peripheral wire 11 in each space formed by the core wire 11 having the same outer diameter, the six outer peripheral wires 11, and the core wire and the outer peripheral wire. The six fine wires 14 having a higher fatigue limit than the wire 11 are formed, and the six outer peripheral wires 11 and the six fine wires 14 are twisted around the core wire 11.

  In this case, repeated stress is generated over a long period of time, and even if the six outer peripheral wires 11 and one core wire 11 in FIG. 4 are broken, the six fine wires 14 are fine and have a high fatigue limit. Will not break. For this reason, the accident that the weight 20 falls is prevented, and it can replace | exchange for the new double torsional damper 100 by discovering abnormality of a suppression line at the time of a periodic inspection.

  FIG. 5 is a block diagram showing the configuration of the inhibition line according to the fourth embodiment of the present invention. In FIG. 5, the suppression line 10-6 has the same configuration as that of FIG. 4, but the thin line 15 is continuous as one thin line. Thereby, the possibility that the six fine wires 14 in FIG. 4 fall off as the six outer peripheral wires 11 and the core wire 11 break can be prevented.

  FIG. 6 is a block diagram showing the configuration of the inhibition line according to the fifth embodiment of the present invention. 6a and 6b, the deterrence wire 10-7 is wound around the core wire 11 around the core wire 11 and a thin wire 16 having a higher fatigue limit than the six outer peripheral wires 11 at a predetermined pitch. Six outer peripheral wires 11 are twisted together. The fine wires 16 are wound at a pitch smaller than the winding pitch at which the six outer peripheral wires 11 are twisted together.

  In this case, repeated stress is generated over a long period of time, and even if the six outer peripheral wires 11 and the one core wire 11 in FIG. 6 break, the thin wire 16 does not break because the fatigue limit is high. Further, since the winding pitch of the fine wires 16 is denser, the entire length of the fine wires 16 is longer than that of the outer peripheral wires 11, so that the inhibition wires 10 when the six outer peripheral wires 11 and the core wires 11 break. It becomes possible to further increase the bending angle of −7, and it becomes easy to find the abnormality of the deterrence line during the periodic inspection.

  FIG. 7 is a block diagram showing the configuration of the inhibition line according to the sixth embodiment of the present invention. In FIG. 7, the restraining wire 10-8 is configured by winding six outer peripheral wires 11 around a core wire constituted by a pipe 17 and an in-pipe insertion line 18 inserted into the pipe 17. The In this case, even if stress is repeatedly generated over a long period of time, the pipe 17 does not break before the outer peripheral line 11, and even if it breaks at the same timing as the outer peripheral line 11, The accident that the weight 20 falls can be prevented, and the abnormality of the deterrence line can be found at the time of regular inspection, so that the new double torsional damper 100 can be replaced.

  FIG. 8 is a block diagram showing the configuration of the inhibition line according to the seventh embodiment of the present invention. In FIG. 8 a, the restraining wire 10-9 is configured by winding the six outer peripheral wires 11 and the six thin wires 19 having a low fatigue limit around the core wire 11. In this case, in FIG. 8b, when a stress is repeatedly generated over a long period of time, the thin wire 19 with a low fatigue limit wound between the outer peripheral wires 11 is first broken and jumps up to the state shown in the figure, and this shape change occurs. Can be replaced with a new double torsional damper 100 by discovering at the time of periodic inspection.

  FIG. 9 is a first detection diagram showing an example of detection of breakage of the inhibition line according to the present invention. In FIG. 9a, the restraining wire 10 of FIG. 1 is replaced with any of the restraining wires 10-1 to 7 of the present invention, and is installed on the overhead electric wire 40 as a double torsional damper 100. In this case, the left weight 20 is in the forward direction with respect to the deterrence wires 10-1 to 7 that are parallel to the lower side of the overhead electric wire 40, and the right weight 20 is deterrence wires 10-1 to 7-7. It is fixed in the rearward direction.

  FIG. 9b shows a case where when the break occurs on the right side of the restraining lines 10-1 to 7, the restraining line is twisted and the weight 20 is rotated downward. By finding an abnormality in the setting direction of the weight 20 at the time of periodic inspection, it can be replaced with a new double torsional damper 100.

  FIG. 10 is a second detection diagram showing an example of detection of the breakage of the suppression line according to the present invention, and FIG. 10a is installed in the same manner as FIG. 10a. In FIG. 10b, when a breakage occurs on the right side of the restraining lines 10-1 to 7, the restraining line is bent, but the weight 20 is in a state of hanging downward without falling. In this case, if the deterrence line 10-7 in FIG. 6 is used, the bending angle α can be further increased, and the abnormality of the weight 20 can be easily found at the time of periodic inspection. It can be replaced with a new double torsional damper 100. FIG. 10c is an enlarged view in which a bent portion is enlarged.

  As described above, according to the present invention, since the deterrence wire of the double torsional damper has a mechanism for preventing the weight from falling, the weight is prevented from falling due to the breakage of the deterrence wire, and at the time of periodic inspection, It is possible to provide a double torsional damper that can easily detect an abnormality in a deterrence line and replace it.

DESCRIPTION OF SYMBOLS 10 Inhibition line 10-1-7 Inhibition line by this invention 11 Outer circumference line 12 Core wire which has a high fatigue limit 12 'Outer circumference line which has a high fatigue limit 13 Core wire which consists of composite twisted wires 13' 14 Thin wire with high fatigue limit 15 Continuous thin wire with high fatigue limit 16 Thin wire with high fatigue limit wound at a predetermined pitch 17 Pipe 18 Insertion line in pipe 19 Thin wire with low fatigue limit 20 Weight 25 Fixed portion 30 Electric wire Grasping clamp 35 Clamp portion 37 Deterrence wire compression hole 40 Overhead electric wire 50 Conventional deterrence wire 51 Core wire 52 Peripheral wire 100 Double torsional damper according to the present invention 110 Double torsional damper
α Bending angle

Claims (8)

In a double torsional damper comprising a restraining wire, a weight secured to both ends of the restraining wire, and an electric wire gripping clamp secured to a central portion of the restraining wire,
The inhibition wire is composed of a core wire having the same outer diameter and a plurality of outer peripheral lines, and is configured by twisting the plurality of outer peripheral lines around the core wire,
A double torsional damper characterized in that one of the core wire or the plurality of outer peripheral wires has a higher fatigue limit than the other wires.   The double torsional damper according to claim 1, wherein one of the core wire or the plurality of outer peripheral wires is composed of a composite stranded wire.   The composite stranded wire forming the core wire has slack in the core wire portion with respect to the plurality of outer peripheral wires, and the composite stranded wire that is one of the plurality of outer peripheral wires is the other plurality of outer peripheral wires. The double torsional damper according to claim 1, wherein the double torsional damper has a slack with respect to the line. In a double torsional damper comprising a restraining wire, a weight secured to both ends of the restraining wire, and an electric wire gripping clamp secured to a central portion of the restraining wire,
The restraining wire includes a core wire having the same outer diameter and a plurality of outer peripheral lines, and each space formed by the core wire and the plurality of outer peripheral lines around the core wire includes the core A thin wire having a higher fatigue limit than the wire and the plurality of outer peripheral wires,
A double torsional damper comprising a plurality of outer peripheral lines and a plurality of fine lines twisted around the core wire.   The double torsional damper according to claim 3, wherein the thin wire having a high fatigue limit is continuous as a single thin wire. In a double torsional damper comprising a restraining wire, a weight secured to both ends of the restraining wire, and an electric wire gripping clamp secured to a central portion of the restraining wire,
The restraining wire has a core wire having the same outer diameter and a plurality of outer peripheral wires, and the core wire is wound with a predetermined pitch with a thin wire having a higher fatigue limit than the core wire and the plurality of outer peripheral wires. ,
The double torsional damper is characterized in that the predetermined pitch is wound at a pitch smaller than a winding pitch in which the plurality of outer peripheral wires are twisted around the core wire. In a double torsional damper comprising a restraining wire, a weight secured to both ends of the restraining wire, and an electric wire gripping clamp secured to a central portion of the restraining wire,
The torsional damper is characterized in that a plurality of outer peripheral lines are wound around a core wire composed of a pipe 17 and an in-pipe insertion line inserted into the pipe. . In a double torsional damper comprising a restraining wire, a weight secured to both ends of the restraining wire, and an electric wire gripping clamp secured to a central portion of the restraining wire,
The deterrence line is formed by winding a plurality of outer peripheral lines around a core wire, and similarly winding a thin wire having a low fatigue limit in each gap formed by the plurality of outer peripheral lines. Double torsional damper.

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