JP4742015B2 - Tensioning device for wire reeling equipment - Google Patents

Description

  BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tensioning device for wire reeling equipment for pre-aligning and winding a wire wound on a run winding coil on a winding reel when installing a suspension bridge cable by an air spinning method. It is.

  Conventionally, when installing a suspension bridge cable by the air spinning method, first, the wire for suspension bridge cable (wire of galvanized steel wire) is wound in a run-wound state in a factory or at the construction site. Wire reeling is performed in which the wire is unwound and re-wound so as to be aligned with the winding reel and to be in the required squeezed state. The run-wound coil is formed in a cylindrical shape by hanging around a vertical center guide so as to circulate a wire from the upper part and laminating from the lower part upward. Since the run coil is wound in a rough state as described above, even if the wire is unwound from the run coil and an attempt is made to construct the suspension bridge cable by the air spinning method, the unwinding of the wire is not stable, Since problems such as catching occur, wire reeling is performed to rewind the winding reel.

  5 and 6 show an example of a conventional wire reeling facility provided at a suspension bridge erection site. As described above, the run-wound coil 2 wound in the run-wound state can be obtained by using a crane or a wrecker. Set against undriven uncoiler 3 of wire reeling equipment. The uncoiler 3 has a guide 3b in the upper center of a turntable 3a that can freely rotate about a vertical axis, and the cylindrical run-wound coil 2 has a central opening fitted into the guide 3b. Set. Next, the wire 1 is unwound from the run winding coil 2 set on the uncoiler 3, and one of the winding reels 6 a and 6 b provided in the winding / unwinding device 5 via the tension applying device 4 (in FIG. The tip of the wire 1 is set on the winding reel 6a), and the winding reel 6a of the winding / unwinding device 5 is driven by the winding drive device 15 to rotate the uncoiler 3 via the tension applying device 4. The wire 1 drawn out from the side portion of the run-wound coil 2 is taken up in a necessary amount aligned state by one of the winding reels 6a.

  When the suspension bridge cable is installed by the air spinning method, the wire 1 drawn out from the other winding reel 6b that has already finished the aligned winding of the wire 1 by the wire reeling equipment is used as the strand tension tower in FIG. 7, the wire sheave 8, the strand guide roller 9, the spinning wheel 10, and the strand shoe 12 attached to the strand adjusting device 11 are sequentially hooked to temporarily fix the tip of the wire 1 to the anchor 13. By applying a braking operation to the rotation of the winding reel 6b of the winding / unwinding device 5 while observing the vertical movement, the winding / unwinding is performed at the driving speed of the rope driving device 14, that is, the construction speed of the spinning wheel 10. Unwinding is performed by following the feeding speed of the winding reel 6b in the apparatus 5, and then the winding of the wires 1 is completed during this time. And configured to perform the Ang ring work by one of Seimaki reel 6a, it had to unwind Seimaki reel 6a, 6b of alternately.

In addition, as a conventional apparatus of the above-mentioned wire reeling equipment, there exists a thing as shown, for example in patent document 1. FIG.
Japanese Patent Laid-Open No. 51-52636

  However, the conventional wire reeling equipment as disclosed in Patent Document 1 has the following various problems.

  That is, the run-wound coil 2 is obtained by winding the wire 1 so as to drop from the upper side to the lower side, and is set on the uncoiler 3 so that its axis is vertical. When unwinding 2, the wire 1 is unwound from the side of the uncoiler 3 in a tangential direction, that is, in a substantially horizontal direction. In some cases, the wire 1 is caught by being drawn and drawn, and the wire 1 is caught. This causes a problem that the wire 1 cannot be unwound. When the unwinding of the wire 1 becomes impossible in this way, it is necessary to stop the winding / unwinding device 5 and to loosen the wire 1 that is caught by the run winding coil 2 so that it can be wound again. However, there was a problem that the recovery work for this was very difficult and time consuming. Moreover, when the wire 1 is forcibly pulled and squeezed, there is a possibility that the coating such as zinc plating on the surface may be peeled off.

  In addition, when the wire 1 is being taken up by one winding reel 6a of the winding / unwinding device 5, if the driving of the winding reel 6a is suddenly stopped, it rotates following. Since the run-wound coil 2 is heavy and continues to rotate due to inertia, the wire 1 is undesirably unwound from the run-wound coil 2, and even in this case, the restoration work is very difficult and takes time. Had.

  In order to prevent the occurrence of the trouble described above, the actual winding speed by the conventional wire reeling equipment has been limited to about 200 to 250 m / min.

  On the other hand, when the suspension bridge cable is erected by the air spinning method, the erection is generally performed by extending the wire 1 so as to maintain the erection speed of about 150 to 200 m / min, and the tension acting on the wire 1 at this erection is 70 to It is about 100 kgf (≈70 × 9.8 to 100 × 9.8 N). Therefore, in the conventional wire reeling equipment, the wire is maintained so as to maintain a tension of about 70 to 100 kgf (≈70 × 9.8 to 100 × 9.8 N), which is substantially equivalent to that of the suspension bridge cable. 1 is being wound.

  And according to the said conventional wire reeling equipment, the wire 1 is wound up by the winding speed of about 200-250 m / min with one winding reel 6a with which two winding / unwinding apparatuses 5 were equipped. Sometimes the wire 1 is fed out by the other winding reel 6b, so that the wire 1 is continuously fed out corresponding to the construction speed of the suspension bridge cable constructed at around 150 to 200 m / min. Can be supplied.

  However, in recent years, it has been studied to increase the erection speed of the suspension bridge cable to around 400 m / min. If the erection speed is increased in this way, the wire reeling equipment that cannot increase the winding speed as in the past. Then, winding is not in time, and it is necessary to install a plurality of wire reeling equipments for this reason, and there is a problem that equipment costs increase.

  Further, in the tension applying device 4 provided in the conventional wire reeling equipment, the tension of the wire 1 taken up by the winding reels 6a and 6b is not stable, and the wire 1 is kept in an arbitrary tension. It was not possible to wind up stably.

  In view of such circumstances, the present invention can stably and reliably adjust the tension of the wire wound by the winding reel of the winding / unwinding device, can perform smooth operation continuously, and It is an object of the present invention to provide a tensioning device for wire reeling equipment that can meet the demand for higher speeds.

The present invention relates to a wirey device in which a wire is unwound from a run winding coil set in an uncoiler, and the wire is aligned and wound on a winding reel of a winding / unwinding device while applying tension to the wire. A tensioning device for a ring facility,
On the entry side of the winding / unwinding device, the winding sheaves are arranged to rotate in synchronization with each other around a shaft arranged in parallel in the wire feeding direction with a predetermined interval, and between the winding sheaves A frictional force increasing means for increasing the frictional force by winding a wire around
Tension adjusting means for adjusting the tension of the wire wound on the winding reel of the winding / unwinding device by braking the rotation of the winding sheave of the frictional force increasing means ;
A tension meter provided between the frictional force increasing means and the winding / unwinding device and detecting the tension of the wire wound around the winding / unwinding device;
A tension control device for controlling the tension adjusting means so that the tension detected by the tensiometer becomes a tension set value;
With
On the entrance side of the winding sheave of the frictional force increasing means, a pair of small and narrow vertical guide rollers for introducing a wire below the winding sheave, and a horizontal guide roller having a larger diameter than the vertical guide roller A small-diameter, narrow, transversely-shaped device that is disposed so as to be rotatable, and that leads to the winding / unwinding device of the wire finally wound around the winding sheave on the exit side of the winding sheave of the frictional force increasing means. A plurality of guide rollers and a pair of vertical guide rollers are rotatably arranged in the wire feed direction,
A plurality of vertical guide rollers arranged on the exit side of the winding sheave of the frictional force increasing means are arranged so that the wire is led out in the width direction with respect to the winding reel of the winding / unwinding device. The present invention relates to a tension applying device for a wire reeling facility in which the distance between the wires arranged in the downstream direction in the feed direction is increased .

  According to the above means, the following operation can be obtained.

  The frictional force of the wire against the winding sheave is increased by the frictional force increasing means, and in this state, when the rotation of the winding sheave of the frictional force increasing means is braked by the tension adjusting means, the winding / unwinding device winding It is possible to reliably adjust the tension of the wire wound around the reel.

The wire in the tensioning device of the reeling equipment, tensiometer for detecting the tension of the wire and wound on the winding-unwinding device is provided between the friction increasing means and the winding-unwinding device When,
Since the detected tension of the tension meter and a tension control device for controlling said tension adjusting means such that the tension setting value, the tension of the wire being wound into Seimaki reel of the winding-unwinding device Detected by a tension meter, and the detected tension is input to a tension control device, and the tension control device controls tension adjusting means so that the detected tension becomes a tension setting value, whereby the winding / unwinding device The tension of the wire wound on the winding reel is maintained at an arbitrarily high tension setting value so as to correspond to the increase in tension when the suspension bridge cable is installed by the air spinning method, and is run around the run winding coil. It is possible to perform a stable winding operation on the winding reel of the wire winding / unwinding device at high speed . In addition, a pair of small and narrow vertical guide rollers for introducing a wire below the winding sheave on the entrance side of the winding sheave of the frictional force increasing means, and a horizontal guide roller having a larger diameter than the vertical guide roller With a small diameter for leading the wire wound around the winding sheave to the winding / unwinding device on the exit side of the winding sheave of the frictional force increasing means. A plurality of long and narrow horizontal guide rollers and a pair of vertical guide rollers are rotatably arranged in the wire feed direction.
A plurality of vertical guide rollers arranged on the exit side of the winding sheave of the frictional force increasing means are arranged so that the wire is led out in the width direction with respect to the winding reel of the winding / unwinding device. Since the distance between the wires arranged in the downstream of the wire feeding direction is increased, the wire is guided by the vertical guide roller and the horizontal guide roller arranged on the entrance side of the winding sheave of the frictional force increasing means. It becomes possible to stably introduce the lower part of the winding sheave at a high speed, and finally, the lateral guide roller and the vertical guide roller arranged on the exit side of the winding sheave of the friction force increasing means finally It is possible to stably lead out the wire wound around the winding sheave to the winding reel of the winding / unwinding device at high speed.

Further, in the tension applying device of the wire reeling equipment, a brake disk that rotates integrally with the winding sheave,
A brake shoe for braking the rotation of the brake disc by a pressing force;
The tension adjusting means can be composed of a braking actuator that drives the brake shoe.

  According to the tension applying device of the wire reeling equipment of the present invention, the tension of the wire wound by the winding reel of the winding / unwinding device can be stably and surely adjusted, and smooth operation is continuously performed. It is possible to achieve an excellent effect of being able to respond to the demand for high-speed driving.

  Embodiments of the present invention will be described below with reference to the accompanying drawings.

  1 to 4 show an example of an embodiment for carrying out the present invention. As shown in FIGS. 1 and 2, the wire reeling equipment is equipped with a run-wound coil 2 around which a wire 1 is wound and the wire 1 is installed. An uncoiler 16 that performs unwinding, an accumulator device 17 that guides the wire 1 from the uncoiler 16 to unwind upward, and absorbs fluctuations in the length of the wire 1, and the accumulator device The wire 1 from 17 is wound around one of the two winding reels 6a and 6b and wound into an aligned state by driving of the winding driving device 15, and at the same time, the other winding reel 6b. A winding / unwinding device 18 configured to wind the wire 1 wound around the wire 1 for the construction of a suspension bridge cable, and a winding reel of the winding / unwinding device 18 6 And a tensioning device 19 for adding tension to the wire 1 to be wound in 6b. In the figure, reference numeral 20 denotes a wire 1 wound around the winding reels 6a and 6b of the winding / unwinding device 18 and slides in the width direction of the winding reels 6a and 6b, thereby winding in an aligned state. It is a guide device for performing.

  The uncoiler 16 includes a horizontal rotating unit 21 that horizontally rotates while holding the run-wound coil 2 so that the axis of the run-wound coil 2 is vertical, and an unwinding drive device 22 that rotationally drives the horizontal rotating unit 21. It is configured. Further, a guide 21 a for guiding the wire 1 drawn upward from the run-wound coil 2 so as to be wound in the outer circumferential direction of the run-wound coil 2 is detachable on the axial center part of the horizontal rotating part 21. Is provided. The uncoiler 16 drives the unwinding drive device 22 to unwind the wire 1 from the run winding coil 2, and drives the winding drive device 15 to adjust the winding reels 6a of the winding / unwinding device 18. The operation of winding the wire 1 by 6b is performed simultaneously.

  A tension applying device 19 for applying tension to the wire 1 wound around the winding reels 6a and 6b of the winding / unwinding device 18 includes a plurality of guide grooves 23a and 24a as shown in FIGS. Frictional force increasing means 25 for increasing the frictional force by winding the wire 1 a plurality of times (five times in the examples of FIGS. 3 and 4) between the winding sheaves 23 and 24 spaced apart to rotate, Tension adjusting means 28 for adjusting the tension of the wire 1 wound around the winding reels 6a and 6b by braking the rotation of the brake disk 26 provided in the winding sheave 24 by the pressing force of the brake shoe 27 operated by the braking actuator 27a. It consists of and.

  The winding sheaves 23 and 24 of the frictional force increasing means 25 are arranged so as to be rotatable around shafts 50 and 51 arranged in parallel in the feed direction of the wire 1 with a predetermined interval. Synchronous sprockets 52 and 53 are fitted, and a chain 54 is looped endlessly between the synchronous sprockets 52 and 53 so that the winding sheaves 23 and 24 rotate synchronously. A small-diameter support sprocket 55 is disposed between the synchronous sprockets 52 and 53 to prevent the chain 54 from loosening.

  Further, on the entrance side of the winding sheave 23 of the frictional force increasing means 25, a pair of small and narrow vertical guide rollers 56 for introducing the wire 1 from the accumulator device 17 below the winding sheave 23, 56 and a horizontal guide roller 57 having a diameter larger than that of the vertical guide rollers 56 and 56 are rotatably arranged, and finally, the winding side is wound on the exit side of the winding sheave 24 of the frictional force increasing means 25. A small-diameter and long horizontal guide roller 58 and a pair of vertical guide rollers 59 and 59 for leading the wire 1 wound around the sheave 23 to the winding / unwinding device 18 are rotatable and in the feeding direction of the wire 1. A plurality of sets (four sets in the example of FIGS. 3 and 4) are arranged. The vertical guide rollers 59 and 59 are arranged so that the wire 1 is led out so as to swing in the width direction with respect to the winding reels 6 a and 6 b of the winding / unwinding device 18. As shown in FIG. 4, the distance between the downstream side and the downstream side is increased.

  Further, the accumulator device 17 provided between the uncoiler 16 and the tension applying device 19 is provided with a tower main body 29 having a required height as shown in FIGS. The gantry 30 extending to the upper part of the uncoiler 16 is provided, and a conduit 32 provided at the upper end of a bowl-shaped guide cone 31 having a conical shape is fixed to the lower surface of the tip of the gantry 30. Further, a turning sheave 33 is provided above the tip of the pedestal 30, and a fixed sheave 34 that rotates with a plurality of guide grooves 34 a is fixed to the top of the tower body 29. The tip of the wire 1 unwound upward from the run coil 2 of the uncoiler 16 is guided from the conduit 32 to the turning sheave 33 through the inside of the guide cone 31, and then guided to the fixed sheave 34. The moving sheave 35 is suspended in the space 36 of the tower body 29 so as to be movable up and down by hanging around the stationary sheave 34 and the moving sheave 35 provided with a plurality of guide grooves 35a in the same manner as the fixed sheave 34. I try to lower it. At this time, a weight 37 is attached to the moving sheave 35 as necessary, and the tension of the wire 1 on the upstream side of the tension applying device 19 is adjusted by the weight of the weight 37 and the moving sheave 35. It is also possible to adjust the tension of the wire 1 upstream of the tension applying device 19 with the weight of only the moving sheave 35 without providing the weight 37.

  Thereby, the accumulator device 17 is connected to the uncoiler 16 according to the difference between the unwinding speed of the wire 1 unwound from the uncoiler 16 and the unwinding speed of the wire 1 wound around the winding / unwinding device 18. Variations in the length of the wire 1 occurring between the tension applying device 19 and the moving sheave 35 are absorbed.

  The tip of the wire 1 led out from the fixed sheave 34 of the accumulator device 17 is wound around the winding sheaves 23, 24 of the tension applying device 19 a plurality of times (five times in the example of FIGS. 3 and 4), The winding / unwinding device 18 is wound around one of the regular winding reels 6a and 6b.

  On the other hand, in the wire reeling equipment described above, as shown in FIG. 1, the pressure roller 39 is pressed against the wire 1 between the tension applying device 19 and the winding / unwinding device 18 and the reaction force is measured. Thus, a tension meter 40 is provided so as to detect the tension of the wire 1 wound by the winding / unwinding device 18, and the tension applying device so that the detected tension 41 by the tension meter 40 becomes the tension set value 42. 19 is provided with a tension control device 43 for controlling the brake actuator 27a of the tension adjusting means 28.

  Further, the accumulator device 17 is provided with a position detection sensor for detecting the upper limit position A and the lower limit position B of the moving sheave 35. That is, an upper limit switch 45a that operates when the striker 44 provided on the moving sheave 35 moves to an upper portion of a predetermined height, and a lower limit switch 45b that operates when the striker 44 provided on the moving sheave 35 moves to a lower portion of a predetermined height. Are attached to the tower main body 29 to constitute the position detection sensor 45. Furthermore, in the state where the wire 1 is being wound at a constant winding speed by the winding / unwinding device 18, the height position of the moving sheave 35 detected by the position detection sensor 45 is the upper limit position A and the lower limit position. A wire length control device 46 for controlling the driving of the unwinding drive device 22 of the uncoiler 16 is provided so as to be always located between the wire B and the wire B. That is, when the upper limit switch 45a is actuated by moving the moving sheave 35 up and down, the uncoiler 16 is insufficient to unwind the wire 1, so that the unwinding speed of the unwinding drive device 22 is controlled to be increased. When the lower limit switch 45b is actuated by moving the moving sheave 35 up and down, the uncoiler 16 unwinds the wire 1 so that the unwinding speed by the unwinding drive device 22 is controlled to be reduced. I am doing so.

  The wire length control device 46 unwinds the wire 1 by the uncoiler 16 as an emergency state when the position of the moving sheave 35 of the accumulator device 17 does not return beyond the range of the upper limit position A or the lower limit position B. And the control which stops winding of the wire 1 by the winding / unwinding device 18 is performed. At this time, an emergency detection switch may be provided above the upper limit switch 45a and below the lower limit switch 45b to detect an emergency.

  Next, the operation of the illustrated example will be described.

  A tubular run coil 2 is formed by winding a wire 1 for a suspension bridge cable (a galvanized steel wire) in a run winding state at a factory or a construction site. The axis is set vertically to the horizontal rotating part 21 of the uncoiler 16 of the wire reeling equipment installed at the construction site of the suspension bridge by a tow truck or the like, and the guide 21a is mounted on the upper part of the axial center part of the horizontal rotating part 21. .

  The wire 1 is unwound from the outer periphery of the run-wound coil 2, and the tip of the wire 1 is guided from the conduit 32 to the turning sheave 33 through the inside of the guide cone 31 provided in the accumulator device 17, and then to the fixed sheave 34. The moving sheave 35 is hung in the space 36 of the tower main body 29 by being guided between the fixed sheave 34 and the moving sheave 35 a plurality of times, and the tip of the wire 1 led out from the fixed sheave 34 is attached to the tension applying device 19. The frictional force increasing means 25 is wound between the winding sheaves 23, 24 a plurality of times (five times in the examples of FIGS. 3 and 4), that is, after winding around the winding sheave 24 by 180 °, The winding is repeated a plurality of times, the frictional force of the wire 1 against the winding sheaves 23, 24 is increased, and then one of the winding reels 6a, 6b of the winding / unwinding device 18 is illustrated. It wrapped around the Seimaki reel 6a. At this time, the position of the moving sheave 35 suspended from the fixed sheave 34 of the accumulator device 17 is adjusted so as to be positioned between the upper limit position A and the lower limit position B by the position detection sensor 45.

  From this state, the winding drive device 22 of the uncoiler 16 is driven to wind the wire 1 from the run winding coil 2, and the winding drive device 15 of the winding / unwinding device 18 is driven to adjust the winding reel. The winding operation of the wire 1 is started by simultaneously performing the operation of winding the wire 1 with 6a. At this time, the tension of the wire 1 wound around the winding reel 6a of the winding / unwinding device 18 is detected by the tension meter 40, and the detected tension 41 is input to the tension control device 43. Controls the tension adjusting means 28 of the tension applying device 19 so that the detected tension 41 becomes the tension set value 42. Thereby, the tension of the wire 1 wound around the winding reel 6a of the winding / unwinding device 18 is, for example, 130 kgf (≈130) so as to correspond to the increase in tension when the suspension bridge cable is installed by the air spinning method. × 9.8 N) or higher, or 150 kgf (≈150 × 9.8 N) or higher, which is held at an arbitrarily high tension set value 42, so that stable winding operation can be performed.

  As described above, the tension of the wire 1 wound up by the winding / unwinding device 18 is adjusted to 130 kgf (≈130 × 9.8 N) or more by the tension applying device 19 and the run coil 2 of the uncoiler 16 is unwound. Since the drive device 22 is rotationally driven to assist the unwinding of the wire 1, the tension of the wire 1 between the tension applying device 19 and the uncoiler 16 is, for example, 10 to 30 kgf (≈10 × 9.8 to It can be stably held at a low value of about 30 × 9.8 N). Thus, by reducing the tension acting on the wire 1 to be unwound from the run-wound coil 2 and unwinding the wire 1 from the run-wound coil 2, the run-wound coil 2 is wound and the wire 1 is It is possible to reliably prevent the occurrence of a problem such as being caught. Therefore, as the construction speed for constructing the suspension bridge cable by the air spinning method is increased, the winding speed of the wire 1 by the winding / unwinding device 18 is increased to 300 m. Even if it is performed at a high speed of not less than / min or 400 m / min or more, a stable winding operation can be performed without causing a problem that the wire 1 is caught. Further, in the above case, when the wire 1 is simply pulled upward from the horizontal run-wound coil 2 and unwound, the wire 1 is caught when the wire 1 is greatly distorted and bent due to twisting. However, since the unwinding drive device 22 drives the run coil 2 horizontally in the unwinding direction to assist unwinding of the wire 1, for example, a thick wire 1 such as 5 mm or more or 7 mm or more is used. Even so, it is possible to prevent the problem of being caught by twisting.

  On the other hand, the diameter of the run coil 2 and the diameter of the winding reel 6a change as the winding proceeds, and the winding speed of the wire 1 unwound from the uncoiler 16 is wound around the winding / unwinding device 18. When the winding speed of the wire 1 to be taken is slower, the moving sheave 35 of the accumulator device 17 is raised, and the winding speed of the wire 1 unwound from the uncoiler 16 is set to the winding / unwinding device 18. When the winding speed of the wire 1 being wound on the wire 1 is higher than the winding speed of the moving sheave 35 of the accumulator device 17, the moving sheave 35 of the accumulator device 17 moves up and down to move the wire 1 unwound from the uncoiler 16. Between the uncoiler 16 and the tension applying device 19 in accordance with the difference between the unwinding speed of the wire 1 and the winding speed of the wire 1 wound on the winding / unwinding device 18. Jill the variation in length of the wire 1 is absorbed, it is possible to prevent that, as the wire 1 in problems or reverse such caught by the wire 1 slackens is pulled forcibly.

  When the upper limit switch 45a is actuated by raising the moving sheave 35, the uncoiler 16 is insufficient to unwind the wire 1, and therefore control is performed to increase the unwinding speed by the unwinding drive device 22. On the other hand, when the lower limit switch 45b is actuated by lowering the moving sheave 35, the uncoiler 16 has excessively unwound the wire 1, so that the unwinding speed by the unwinding drive device 22 is controlled to be reduced. Is done.

  When the position of the moving sheave 35 of the accumulator device 17 exceeds the range of the upper limit position A or the lower limit position B, the wire length control device 46 unwinds the wire 1 by the uncoiler 16 and winds / unwinds. Since the winding of the wire 1 by the apparatus 18 is stopped, and the operation can be stopped without causing the wire 1 to be slack, the recovery operation can be easily performed.

  Furthermore, the tension of the wire 1 on the upstream side of the tension applying device 19 is maintained at a required value by adjusting the weight of the weight 37 and the moving sheave 35 or the weight of the moving sheave 35 alone.

  Thus, by using the tension applying device 19, the tension of the wire 1 taken up by the winding reels 6a and 6b of the winding / unwinding device 18 can be adjusted stably and reliably, and smooth operation can be continuously performed. It can be performed, and can meet the demand for high-speed driving.

  In addition, the tension | tensile_strength provision apparatus of the wire reeling installation of this invention is not limited only to the above-mentioned illustration example, Of course, it can add various changes within the range which does not deviate from the summary of this invention.

It is a whole side view which shows an example of the form which implements this invention. It is a whole top view showing an example of an embodiment which carries out the present invention. It is a detailed side view of the tension | tensile_strength provision apparatus in an example of embodiment which implements this invention. It is an IV-IV arrow equivalent view of FIG. It is a side view which shows an example of the conventional wire reeling installation. It is a top view which shows an example of the conventional wire reeling installation. It is a side view which shows the state which has performed the overhead wire by the air spinning method using an example of the conventional reeling equipment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Wire 2 Run winding coil 5 Winding / unwinding device 6a Conditioning reel 6b Conditioning reel 15 Winding drive device 16 Uncoiler 17 Accumulator device 18 Winding / unwinding device 19 Tension applying device 21 Horizontal rotation part 22 Unwinding drive Device 23 Winding sheave 23a Guide groove 24 Winding sheave 24a Guide groove 25 Friction force increasing means 26 Brake disc 27 Brake shoe 27a Brake actuator 28 Tension adjusting means
40 Tensile meter
43 Tension Control Device 50 Axis 51 Axis 52 Synchronous Sprocket 53 Synchronous Sprocket 54 Chain
56 Vertical guide roller
57 Lateral guide roller
58 Lateral guide roller
59 Vertical guide roller

Claims (2)

The tension of the wire reeling equipment in which the wire is unwound from the run winding coil set in the uncoiler, and the wire is aligned and wound on the winding reel of the winding / unwinding device while applying tension to the wire. A granting device,
On the entry side of the winding / unwinding device, the winding sheaves are arranged to rotate in synchronization with each other around a shaft arranged in parallel in the wire feeding direction with a predetermined interval, and between the winding sheaves A frictional force increasing means for increasing the frictional force by winding a wire around
Tension adjusting means for adjusting the tension of the wire wound on the winding reel of the winding / unwinding device by braking the rotation of the winding sheave of the frictional force increasing means ;
A tension meter provided between the frictional force increasing means and the winding / unwinding device and detecting the tension of the wire wound around the winding / unwinding device;
A tension control device for controlling the tension adjusting means so that the tension detected by the tensiometer becomes a tension set value;
With
On the entrance side of the winding sheave of the frictional force increasing means, a pair of small and narrow vertical guide rollers for introducing a wire below the winding sheave, and a horizontal guide roller having a larger diameter than the vertical guide roller A small-diameter, narrow, transversely-shaped device that is disposed so as to be rotatable, and that leads to the winding / unwinding device of the wire finally wound around the winding sheave on the exit side of the winding sheave of the frictional force increasing means. A plurality of guide rollers and a pair of vertical guide rollers are rotatably arranged in the wire feed direction,
A plurality of vertical guide rollers arranged on the exit side of the winding sheave of the frictional force increasing means are arranged so that the wire is led out in the width direction with respect to the winding reel of the winding / unwinding device. A tensioning device for wire reeling equipment, characterized in that the distance between the wires arranged in the downstream direction of the wire feeding direction is increased . A brake disc that rotates integrally with the wound sheave;
A brake shoe for braking the rotation of the brake disc by a pressing force;
The tension applying device for a wire reeling equipment according to claim 1 , wherein the tension adjusting means comprises a braking actuator that drives the brake shoe.

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