JP2011140386A - Linear body carrying device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make treating condition uniform when subjecting a linear body running through a thread passage from yarn supplying to winding to a variety of treatments such as a surface treatment, drying treatment and the like. <P>SOLUTION: In order to subject the linear body running through the thread passage from yarn supplying to winding to the variety of treatments, a linear body carrying device 1 carries the linear body supplied while temporarily winding it to a drum 20 formed to a cylindrical shape and rotatively driven around a main shaft 21. More specifically, the drum 20 has a structure arranging a plurality of bar like members 24 of a bar shape in the outer periphery in an attitude parallel with the main shaft 21 of the drum 20, and is configured to carry the linear body engaged to a groove 24g of the bar-like member 24 from the starting end wound to the drum 20 toward the finishing end at a constant speed by rotation of the bar-like member 24 accompanying rotation of the drum 20. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a technique for homogenizing a processing state when a linear body traveling on a yarn path from yarn feeding to winding is subjected to various treatments such as surface treatment and drying treatment.

  Conventionally, a continuous manufacturing apparatus capable of continuously manufacturing various linear bodies has been known. For example, in an apparatus for continuously producing a monofilament-shaped resin-coated silk fishing line described in Patent Document 1, resin penetration, adhesion, and stretching are performed on the yarn path from the yarn feeding to the winding device, and the silk fishing line. The excess liquid resin on the top is removed, the liquid resin on the silk fishing line is cured, and the silk fishing line after the liquid resin is cured is made to have a uniform thickness and the surface is polished smoothly. It is designed to be manufactured continuously.

  Here, the process relating to the resin penetration and adhesion will be described in more detail. That is, the continuous manufacturing apparatus as described above includes a chamber having a resin tank for storing a resin liquid and a drying chamber at the top of the resin tank, and a silk fishing line that is hidden in the resin liquid in the resin tank. By drying in a drying chamber, the resin penetration and adhesion as described above is performed. In addition, a yarn storage rotating frame for heating the silk fishing line is provided at the upper portion of the chamber. This yarn storage rotating frame is provided with a plurality of thread guide bars between two disks rotatably supported by a shaft, and the thread guide bars rotate in the same direction along with the rotation of the disks. When rotationally driven, the silk fishing line wound around the thread guide bar is sent toward the tip of the storage rotary frame.

  Patent Documents 2 to 5 disclose techniques related to a dryer corresponding to the above-described yarn storage rotating frame. Specifically, in this dryer, two disks are supported so as to be rotatable with respect to a vertical axis, and a plurality of thread guide rods that are supported by both disks and are vertically directed between both disks are vertically arranged. It is provided around the shaft. And in this dryer, as a device for efficiently sending the thread to be dried in the tip direction, the upper end of the yarn guide bar is supported at equal intervals on the circumference equidistant from the center of the upper disk, and the yarn guide bar Is supported at equal intervals on a circumference equidistant from the center of the lower disk, but the support radius of the thread guide bar in the lower disk is smaller than the support radius of the thread guide bar in the upper disk. Yes. That is, the rotary body of the dryer composed of two disks and a plurality of yarn guide rods is configured such that the diameter dimension becomes smaller toward the tip. Further, the thread guide rod is supported so as to revolve around the vertical axis by the rotation of the disk, and the linear body wound around the thread guide rod is successively lowered along the thread guide rod by the rotation of both disks. To move to.

JP 06-315336 A (page 3, FIG. 4) JP-A-60-052606 (pages 2 and 3, FIG. 1) Japanese Patent Laid-Open No. 60-052607 (pages 2 and 3, FIG. 1) JP 60-059110 A (page 3, FIG. 1) JP-A-61-83303 (pages 2 and 3, FIG. 1)

  However, in the technique disclosed in Patent Document 1, a silk fishing line wound around a cocoon-shaped yarn storage rotating frame that is driven to rotate by a motor is not uniformly wound but is densely wound and roughly wound. When drying in the drying chamber at the top of the chamber, there is a risk that drying will be insufficient at the portion where the silk fishing line is tightly wound. Note that the same problems occur in the techniques disclosed in Patent Documents 2 to 5.

  In addition, in the techniques disclosed in Patent Documents 2 to 5, since the rotary body of the dryer composed of two disks and a plurality of thread guide bars as described above is configured so that the diameter dimension decreases as it goes to the tip, There is a possibility that the thread to be dried wound around the rotating body of the dryer is displaced and rubbed on the surface of the rotating body in the direction of the rotation axis of the rotating body.

  Such a problem is not limited to the case where the silk fishing line or the to-be-dried thread is wound around the rod-shaped yarn storage rotating frame or the rotating body of the dryer and dried as described above. For example, it may occur in the same manner when another type of linear body is wound around a basket-like yarn storage rotary frame or a rotary body of a dryer and dried. Moreover, it can occur in the same manner when various processes such as surface treatment other than drying are performed by winding a linear body around a cage-shaped yarn storage rotating frame or a rotating body of a dryer.

  The present invention has been made in view of such problems, and the object of the present invention is to perform various treatments such as surface treatment and drying treatment on a linear body traveling on a yarn path from yarn feeding to winding. It is to homogenize the processing state.

  The linear body conveying device according to claim 1, which has been made to solve the above-mentioned problems, performs various processing on the linear body that travels on the yarn path from the yarn feeding to the winding, so that the fed linear A linear body transport device that transports a body while being temporarily wound around a cylindrical member that is formed in a cylindrical shape and is driven to rotate about a central axis, the cylindrical member having a plurality of rod-shaped rod shapes The member has a structure in which the member is arranged on the outer periphery in a posture parallel to the central axis of the cylindrical member, and the linear body is wound from the start end to the end of the tubular member according to the rotation of the cylindrical member. It is configured to convey at a speed.

  According to the linear body conveyance device of the present invention configured as described above, the linear body is configured to be conveyed at a constant speed from the starting end wound around the cylindrical member toward the terminal end according to the rotation of the cylindrical member. Thus, the following effects (1) to (6) are obtained.

  (1) First, the linear body is wound around the cylindrical member at an equal pitch. At this time, various processes such as drying are performed on the linear body transported from the start end to the end, but the linear body is wound around the cylindrical member at an equal pitch and the transport from the start end to the end is performed. Since the process is performed at a speed, the processing state becomes homogeneous. Therefore, when performing various treatments such as surface treatment and drying treatment on the linear body traveling on the yarn path from yarn feeding to winding, it is possible to make the treatment state uniform.

(2) Further, rubbing between the conveyed linear body and the outer peripheral surface of the cylindrical member is reduced, and deterioration of the linear body due to rubbing during processing can be reduced as much as possible.
(3) Moreover, it becomes easy to set beforehand the time which winds a linear body around a cylindrical member. Moreover, the processing time of various processes with respect to the linear body wound around a cylindrical member can be made constant.

(4) Moreover, since the linear body wound around the cylindrical member is forcibly conveyed from the start end to the end of the cylindrical member, excessive tension acts on the linear body wound around the cylindrical member. Hard to break.
(5) Moreover, since various processes can be performed in a state where the linear body is wound around the cylindrical member, the yarn path between the yarn feeding and the winding device as in the technique described in Patent Document 1 is used. Compared with the case where the silk fishing line is processed, the portion of the yarn path to be processed can be made compact, and the apparatus can be downsized accordingly.

  (6) Moreover, even when a linear body is immersed in a liquid for processing, the tubular member in a state where the linear body is wound can be immersed in a liquid tank storing a processing liquid. Compared with the case where the silk fishing line is processed by the yarn path from the yarn feeding to the winding device as in the technique described in (1), the configuration in which the linear body is immersed in the liquid can be made compact.

  Moreover, the linear body conveyance apparatus which concerns on Claim 2 made | formed in order to solve the said subject WHEREIN: The linear body conveyance apparatus of Claim 1 WHEREIN: The said rod-shaped member is parallel to the central axis of the said cylindrical member. A spiral groove that can lock the linear body is formed in the direction opposite to the rotation direction of the rod-shaped member from the start end to the end. And a transmission mechanism that transmits the rotation of the cylindrical member and rotates the plurality of rod-shaped members in the same direction as the cylindrical member.

According to the linear body conveyance device of the present invention configured as described above, the linear body can be reliably locked to the outer periphery of the rod-shaped member by the spiral groove formed on the outer periphery of the rod-shaped member.
Moreover, the linear body conveyance apparatus which concerns on Claim 3 made | formed in order to solve the said subject WHEREIN: The linear body conveyance apparatus of Claim 2 WHEREIN: The said transmission mechanism is the said with respect to the rotation speed of the said cylindrical member. The rod member is rotated in the same direction as the cylindrical member by transmitting the rotation of the cylindrical member at a rate at which the rotation number of the rod member is an integral multiple.

  According to the linear body conveyance device of the present invention configured as described above, the linear body is fed over the rod-shaped member by the integral number of times of the groove portion every time the cylindrical member rotates once. It is conveyed while being locked to the groove at a rate of once per winding. That is, the number of linear bodies corresponding to the ratio of the number of rotations of the rod-shaped member to the number of rotations of the cylindrical member can be simultaneously wound around the cylindrical member and conveyed from the start end to the end of the cylindrical member. A linear body can be processed simultaneously.

  Moreover, the linear body conveying apparatus which concerns on Claim 4 made | formed in order to solve the said subject WHEREIN: The linear body conveying apparatus of any one of Claim 2 or Claim 3 WHEREIN: The said transmission mechanism is as follows. Switchable between a transmission state in which the rotation of the cylindrical member is transmitted to each of the plurality of rod-shaped members and a non-transmission state in which the rotation of the cylindrical member is not transmitted to each of the plurality of rod-shaped members. When the linear member is supported on the side of the cylindrical member, and the transmission mechanism is in the non-transmitting state, the linear member is supported at a position where the linear member is rotated once. A guide mechanism for moving the cylindrical member by an integral multiple of the pitch width of the groove portion of the rod-shaped member from the terminal end to the starting end is provided.

  According to the linear body conveyance device of the present invention configured as described above, the transmission mechanism is switched to a non-transmission state in which the rotation of the cylindrical member is not transmitted to each of the plurality of rod-shaped members, and the guide mechanism is When in a non-transmission state, the tip of the supplied linear body is fixed to the terminal end side of the cylindrical member, and the cylindrical member is rotated while the cylindrical member rotates once at a position where the linear body is supported. By moving by an integral multiple of the pitch width of the groove portion of the rod-shaped member from the end of the member toward the start end, the linear body can be wound at an equal pitch from the end of the tubular member toward the start end. Therefore, the workability of the work of winding the supplied linear body around the cylindrical member first can be improved.

  Moreover, the linear body conveying apparatus which concerns on Claim 5 made | formed in order to solve the said subject is a linear body conveying apparatus in any one of Claims 1-4, The linear member conveying apparatus of any one of Claims 1-4. At least one of the central shaft and the rod-shaped member is formed in a hollow shape in which both end portions are closed.

  According to the linear body conveyance device of the present invention configured as described above, the central axis of the cylindrical member is immersed in the liquid tank in which the liquid for processing is stored together with the cylindrical member around which the linear body is wound. The amount of liquid stored in the liquid tank can be reduced by the amount of the hollow rod member.

Plan view of linear body conveyance device 1 Side view of linear body conveyance device 1 AA arrow view of FIG. Explanatory drawing which shows the operation | movement (each axis rotation) of the linear body conveyance apparatus 1. Explanatory drawing which shows operation | movement (whole rotation) of the linear body conveying apparatus 1.

Embodiments of the present invention will be described below with reference to the drawings. In addition, this invention is not limited to the said embodiment, It is possible to implement in various aspects.
[Embodiment]
The linear body conveyance device 1 according to the present embodiment shown in FIG. 1 performs various processing on the linear body that travels on the yarn path from the yarn feeding to the winding, so that the fed linear body is formed into a cylindrical shape. It is an apparatus that conveys while being temporarily wound around a cylindrical member that is formed and is rotationally driven about a central axis.

[1. Description of configuration of linear body conveyance device 1]
Next, the specific structure of the linear body conveyance apparatus 1 is demonstrated, referring drawings.
As shown in FIG. 1, the linear body conveyance device 1 includes an installation table 10, a drum 20 as a cylindrical member, a drive mechanism 30, and a guide mechanism 40. This will be described in order below.

[1.1. Description of Configuration of Installation Table 10]
The installation table 10 includes an installation table main body 11, six legs 12, a drum support unit 13, and a motor support unit 14.

  As shown in FIGS. 1 and 2, the installation base body 11 is adjacent to two pairs of aluminum-like rod-like frame members (frame member 11a and frame member 11b, frame member 11c and frame member 11d) that are parallel to each other. The ends are connected so as to have a quadrilateral frame shape, and a square, for example, transparent acrylic resin plate 11e is attached to one end. In addition, between the frame member 11a and the frame member 11b, the aluminum frame member 11f is similarly arranged in parallel between the frame member 11c and the frame member 11d. Both end portions of the frame member 11f are coupled to the frame member 11a and the frame member 11b, respectively, and have a role of reinforcing the installation base main body 11.

  Further, leg portions 12 capable of adjusting their own height dimensions are respectively attached to a total of six locations including four locations near the four corners of the back surface of the installation base body 11 and two locations in the central portion. By appropriately adjusting the height dimension of the leg portion 12, the installation base body 11 can be brought into a horizontal posture.

  Further, a drum support portion 13 for rotatably supporting a drum 20 described later and a motor support portion 14 for supporting a drive mechanism 30 described later are fixed to the surface of the installation table main body 11.

  The drum support portion 13 is composed of two plate-like plate members 13a and 13b, and these plate members 13a and 13b are fixed with screws so as to stand upright with respect to the plate member 11e of the installation base body 11 in a posture parallel to each other. ing. Further, circular insertion holes 13c and 13d for inserting the cylindrical main shaft are formed in the plate material 13a and the plate material 13b, respectively.

The insertion hole 13c formed in the plate material 13a of the drum support 13 and the insertion hole 13d formed in the plate material 13b are set to be located on the same center line.
The motor support portion 14 is a plate member having an L-shaped cross section, and one plate member 14 a abuts on the plate member 11 e of the installation base body 11 and the plate member 14 b stands on the other side with respect to the plate member 11 e of the installation base body 11. It is fixed with screws to install. A circular insertion hole 14 c for inserting the output shaft 31 a of the motor 31 of the drive mechanism 30 is formed in the plate material 14 b.

  The insertion hole 14c formed in the plate material 14b of the motor support portion 14 is located on the same center line as the insertion hole 13c and the insertion hole 13d formed in the plate material 13a and the plate material 13b of the drum support portion 13 described above. Is set.

  In addition, about the installation stand 10, there can exist various structures and materials according to the form which installs the said linear body conveying apparatus 1 to an installation place. For example, the drum support part 13 and the motor support part 14 are directly fixed so as to stand upright at the installation place without using the installation table main body 11.

[1.2. Description of Drum 20 Configuration]
The drum 20 is used to temporarily wind the supplied linear body in order to perform various processes on the linear body running on the yarn path from the yarn supply to winding. Therefore, the drum 20 is formed in a cylindrical shape, and is configured to be rotatable around a main shaft (center axis) 21 that penetrates the center in the longitudinal direction.

More specifically, as shown in FIGS. 1 to 3, the drum 20 includes a main shaft 21 as a central axis, two rotating members 22 and 23, and six rod-shaped members 24. .
The main shaft 21 is formed in a rod shape and has a hollow shape with both ends closed. Further, the main shaft 21 is rotatably supported by the plate material 13 a and the plate material 13 b of the drum support portion 13. Specifically, the main shaft 21 has one end 21a inserted into an insertion hole 13c formed in the plate 13a of the drum support 13 via a bearing 13e, and a portion 21c inside the other end 21b. It is inserted via a bearing 13f into an insertion hole 13d formed in the plate 13b of the drum support portion 13. The other end 21b of the main shaft 21 is in a state of projecting from the plate material 13b of the drum support 13 to the motor support 14 side. A locking groove 21e for locking the output shaft 31a of the motor 31 is formed at the tip 21d of the other end 21b of the main shaft 21.

  The rotating member 22 and the rotating member 23 are formed in a regular hexagonal plate shape, and are attached to the central portion of the main shaft 21 so as to be rotatable in parallel with each other. Specifically, a circular insertion hole 22a is formed at the center of one rotating member 22, and the rotating member 22 has a portion 21f inside the one end 21a of the main shaft 21 as an insertion hole 22a. It is rotatably attached to the main shaft 21 by being inserted through the bearing 22b. A circular insertion hole 23a is formed at the center of the other rotation member 23, and the rotation member 23 passes through the portion 21g further inside the portion 21c supported by the plate member 13b of the main shaft 21 through the insertion hole 23a. It is rotatably attached to the main shaft 21 by being inserted through the bearing 23b. The rotating member 22 and the rotating member 23 are connected by two rod-like connecting rods 25.

  Further, six insertion holes 22c for inserting one end portions 24a of the six rod-shaped members 24 are formed in the rotating member 22 at equal intervals on a circumference equidistant from the center of the insertion hole 22a. Has been. On the other hand, the rotation member 23 has six insertion holes 23c through which the portions 24c on the inner side of the other end 24b of the six rod-shaped members 24 are respectively inserted, and the circumference is equidistant from the center of the insertion hole 23a. It is formed at equal intervals on the top. The six insertion holes 22c of the rotating member 22 and the six insertion holes 23c of the rotating member 23 are set to face each other at the same time. Further, two positioning pins 22d extend outward from the rotating member 22.

  An annular set collar 26 is disposed outside the portion 21f to which the rotating member 22 of the main shaft 21 is attached, and the two positioning pins 22d of the rotating member 22 are inserted into the two insertion holes 26a of the set collar 26. It is fixed. Thus, the main shaft 21, the rotating member 22, and the rotating member 23 are integrated, and the rotating member 22 and the rotating member 23 rotate with the rotation of the main shaft 21.

  Each rod-shaped member 24 is formed in a rod shape and has a hollow shape in which both ends are closed. Each rod-like member 24 is rotatably attached to the two rotating members 22 and 23. Specifically, one end 24a of each rod-shaped member 24 is attached to the insertion hole 22c of the rotating member 22 via a bearing 24d, and a portion 24c inside the other end 24b is inserted through the rotating member 23. It is attached to the hole 23c via a bearing 24e. Further, a gear 24 f is attached to the end 24 b of each rod-like member 24. Furthermore, each rod-shaped member 24 has a spiral groove 24g formed on the side surface of the central portion. The groove 24g is formed counterclockwise (left-handed) from the start end (end 24a) to the end (end 24b) of the rod-like member 24.

  Further, a gear 27 is attached via two bearings 28 to a portion 21 h outside the portion 21 g to which the rotating member 23 of the main shaft 21 is attached. The gear 27 meshes with the gear 24f of each rod-like member 24. In the present embodiment, the gear ratio between the gear 27 of the main shaft 21 and the gear 24f of the rod-shaped member 24 is set to 1: 1.

  In addition, a positioning pin 27a extends outward from the gear 27. The positioning pin 27a is used when the rod-shaped member 24 is rotated. Specifically, when the positioning pin 27 a of the gear 27 and the plate member 13 b of the drum support portion 13 are fixed by the stopper 29, the rod-shaped member 24 revolves with respect to the main shaft 21 as the rotating member 22 and the rotating member 23 rotate. At this time, the gear 27 stops rotating, and the gear 24f meshing with the gear 27 rotates as the rod-shaped member 24 revolves, and the rod-shaped member 24 rotates (see the transmission state, see FIG. 4). On the other hand, when the stopper 29 is not used, the gear 27 rotates together with the rotating member 23 when the rod-shaped member 24 revolves with respect to the main shaft 21 as the rotating member 22 and the rotating member 23 rotate. The meshing gear 24f does not rotate, and the rod-shaped member 24 does not rotate (non-transmission state, see FIG. 5).

The gear 24f of the rod-shaped member 24, the gear 27, the plate member 13b of the drum support portion 13, and the stopper 29 correspond to the transmission mechanism in the claims.
[1.3. Description of Configuration of Drive Mechanism 30]
As shown in FIGS. 1 and 2, the drive mechanism 30 includes a motor 31 that can rotationally drive the drum 20. Specifically, the end portion 21b of the main shaft 21 is connected to the output shaft 31a of the motor 31 via a coupling 32, and the drive mechanism 30 receives power supply from an external power supply unit (not shown). In addition, the drum 20 is driven to rotate counterclockwise (counterclockwise) by the driving force of the motor 31.

[1.4. Description of Configuration of Guide Mechanism 40]
As shown in FIG. 1, the guide mechanism 40 includes a support portion 41 that supports the supplied linear body on the side of the drum 20, and receives power from an external power supply (not shown). The support portion 41 is moved from the end of the drum 20 toward the start end in accordance with a guide portion 42 disposed along the main shaft 21.

  Further, the guide mechanism 40 moves the position of the support portion 41 (the position where the linear body is supported) from the terminal end of the drum 20 to the start end while the drum 20 rotates once, and the pitch width of the groove portion 24g of the rod-shaped member 24. It can be set to move by an integral multiple of. In the present embodiment, the position of the support portion 41 (the position where the linear body is supported) is set so that the pitch width of the groove portion 24g of the rod-shaped member 24 extends from the end of the drum 20 to the start end while the drum 20 rotates once. It is set to move by minutes.

[2. Description of operation of linear body conveyance device 1]
Next, the operation of the linear body conveyance device 1 will be described with reference to the drawings.
(1) First, the supplied linear body is wound around the drum 20. Specifically, without using the stopper 29 described above, the gear 27 rotates together with the rotating member 23 when the rod-shaped member 24 revolves with respect to the main shaft 21 as the rotating member 22 and the rotating member 23 rotate. The gear 24f meshing with the rod member 24 does not rotate, and the rod-like member 24 does not rotate (non-transmission state, see FIG. 5).

Subsequently, the leading end of the fed linear body is fixed to the end side of the drum 20.
Subsequently, the drum 20 is rotated. Specifically, power supply to the drive mechanism 30 is started from the external power supply unit, and the drum 20 is rotated counterclockwise (counterclockwise) by the driving force of the motor 31.

  Subsequently, power supply from the external power supply unit to the guide mechanism 40 is started, and the position of the support unit 41 (position where the linear body is supported) is changed from the end of the drum 20 to the start while the drum 20 rotates once. Then, the rod-shaped member 24 is moved by the pitch width of the groove 24g. Then, the linear body is wound at an equal pitch from the start end to the end end of the drum 20.

  (2) Next, when various processes such as drying and surface treatment are performed on the fed linear body, the following is performed. That is, power supply from the external power supply unit to the drive mechanism 30 and the guide mechanism 40 is temporarily stopped, the positioning pin 27a of the gear 27 and the plate member 13b of the drum support unit 13 are fixed by the stopper 29, and the guide mechanism 40 The linear body is removed from the support portion 41. Then, power supply from the external power supply unit to the drive mechanism 30 is resumed. Then, the drum 20 is rotated counterclockwise (counterclockwise) by the driving force of the motor 31. At this time, the gear 27 does not rotate when the rod-shaped member 24 revolves with respect to the main shaft 21 as the rotating member 22 and the rotating member 23 rotate, and the gear 24f that meshes with the gear 27 accompanies the revolution of the rod-shaped member 24. The rod-shaped member 24 rotates as it rotates (transmission state, see FIG. 4). Then, as the drum 20 rotates, the linear body that is locked in the groove 24g by the rotation of the rod-shaped member 24 is conveyed at a constant speed from the start end to the end.

[3. Effects of the embodiment]
(1) As described above, according to the linear body conveyance device 1 of the present embodiment, the linear body that is locked to the groove portion 24g by the rotation of the rod-shaped member 24 is rotated from the start end to the end as the drum 20 rotates. By being transported at a speed, the following effects (1-1) to (1-6) are obtained.

  (1-1) First, the linear body is wound around the drum 20 at an equal pitch. At this time, various processes such as drying are performed on the linear body transported from the start end to the end, and the linear body is wound around the drum 20 at an equal pitch and the transport from the start end to the end is performed at a constant speed. Since the process is performed in this manner, the processing state becomes uniform. Therefore, when performing various treatments such as surface treatment and drying treatment on the linear body traveling on the yarn path from the yarn feeding to the winding, the processing state can be homogenized.

(1-2) Further, the friction between the conveyed linear body and the outer peripheral surface of the drum 20 (the outer surface of the rod-shaped member 24) can be reduced, and the deterioration of the linear body due to the friction during processing can be reduced as much as possible. it can.
(1-3) Moreover, it becomes easy to preset the time for winding the linear body around the drum 20. Moreover, the processing time of various processes with respect to the linear body wound around the drum 20 can be made constant.

  (1-4) Moreover, since the linear body wound around the drum 20 is forcibly conveyed from the start end to the end of the drum 20, excessive tension does not act on the linear body wound around the drum 20. It is hard to cut.

  (1-5) Moreover, since various processes can be performed in a state where the linear body is wound around the drum 20, the yarn path between the yarn feeding and the winding device as in the technique described in Patent Document 1 is used. As compared with the case where the silk fishing line is processed, the portion of the yarn path to be processed can be made compact, and the apparatus can be downsized accordingly.

  (1-6) Further, even when the linear body is immersed in the liquid to perform the processing, the processing liquid is stored for each drum 20 (or for each linear body transport device 1) in a state where the linear body is wound. Compared with the case where the silk fishing line is treated with a yarn path between the yarn feeding and the winding device as in the technique described in Patent Document 1, the linear body is made into a liquid. The immersion configuration can be made compact.

  (2) Moreover, according to the linear body conveyance apparatus 1 of the present embodiment, the linear body is reliably locked to the outer periphery of the rod-shaped member 24 by the spiral groove portion 24 g formed on the outer periphery of the rod-shaped member 24. Can do.

  (3) Moreover, according to the linear body conveyance device 1 of the present embodiment, the linear body is fed over the rod-shaped member 24 by an integral number of times of the groove 24g every time the drum 20 rotates once. It is conveyed while being locked to the groove portion 24g at a rate of once per the number of windings. That is, the number of linear bodies corresponding to the ratio of the rotational speed of the rod-shaped member 24 to the rotational speed of the drum 20 can be simultaneously wound around the drum 20 and conveyed from the start end to the end of the drum 20. The body can be treated simultaneously.

  (4) Moreover, according to the linear body conveyance apparatus 1 of this embodiment, in the non-transmission state, the guide mechanism 40 is the position of the support part 41 (position where a linear body is supported), and the drum 20 is 1 Since the drum 20 is moved by the pitch width of the groove 24g of the rod-shaped member 24 from the terminal end of the drum 20 to the starting end during the rotation, the linear body can be wound at an equal pitch from the starting end of the drum 20 to the terminal end. Therefore, the workability of the work of winding the supplied linear body around the drum 20 first can be improved.

  (5) Moreover, according to the linear body conveyance apparatus 1 of this embodiment, since the main shaft 21 and the rod-shaped member 24 of the drum 20 are formed in the hollow with both ends closed, the linear body is wound. When the drum 20 in the state (or the linear body conveying device 1) is immersed in the liquid tank storing the processing liquid, the main shaft 21 and the rod-shaped member 24 of the drum 20 are stored in the liquid tank which is hollow. Less liquid is needed.

DESCRIPTION OF SYMBOLS 1 ... Linear body conveying apparatus, 10 ... Installation stand, 11 ... Installation stand main body, 11a, 11b, 11c, 11d, 11f ... Frame member, 11e ... Plate material, 12 ... Leg part, 13 ... Drum support part, 13a, 13b ... Plate material, 13c, 13d ... Insertion hole, 13e, 13f ... Bearing, 14 ... Motor support, 14a, 14b ... Plate material, 14c ... Insertion hole, 20 ... Drum, 21 ... Main shaft, 22, 23 ... Rotating member, 22a, 22c, 23a, 23c ... insertion hole, 22b, 23b ... bearing, 22d, 23d ... positioning pin, 24 ... rod-shaped member, 24d, 24e ... bearing, 24f ... gear, 24g ... groove, 25 ... connecting rod, 26 ... set collar , 26a ... insertion hole, 27 ... gear, 27a ... positioning pin, 28 ... bearing, 29 ... stopper, 30 ... drive mechanism, 31 ... motor, 31a ... output shaft, 32 ... coupling, 4 ... guide mechanism, 41 ... support portion, 42 ... guide portion

Claims (5)

In order to perform various processes on the linear body running on the yarn path from the yarn feeding to the winding, the linear body fed is formed into a cylindrical shape and is driven to rotate around the central axis A linear body transport device that transports while temporarily winding around a member,
The cylindrical member has a structure in which a plurality of rod-shaped rod-shaped members are arranged on the outer periphery in a posture parallel to the central axis of the cylindrical member, and the linear body is formed into the cylindrical shape according to the rotation of the cylindrical member. A linear body transporting device configured to transport at a constant speed from a starting end wound around a member toward a terminal end. In the linear body conveyance device according to claim 1,
The rod-shaped member is rotatable about a central axis parallel to the central axis of the cylindrical member, and a spiral groove that can lock the linear body is provided on the outer periphery from the start end to the end. Formed in the direction opposite to the rotation direction of the rod-shaped member,
Furthermore, the linear body conveyance apparatus characterized by including the transmission mechanism which transmits rotation of the said cylindrical member, and rotates each of these rod-shaped members in the same direction as the said cylindrical member. In the linear body conveyance device according to claim 2,
The transmission mechanism transmits the rotation of the cylindrical member at a rate at which the rotation speed of the rod-shaped member is an integral multiple of the rotation speed of the cylindrical member to rotate the rod-shaped member in the same direction as the cylindrical member. The linear body conveying apparatus characterized by the above-mentioned. In the linear body conveyance apparatus of any one of Claim 2 or Claim 3,
The transmission mechanism can be switched between a transmission state in which the rotation of the cylindrical member is transmitted to each of the plurality of rod-shaped members and a non-transmission state in which the rotation of the cylindrical member is not transmitted to each of the plurality of rod-shaped members,
When the supplied linear body is supported by the side of the cylindrical member and the transmission mechanism is in the non-transmitting state, the cylindrical member is positioned at a position where the linear body is supported. A linear body transporting apparatus comprising a guide mechanism that moves by an integral multiple of the pitch width of the groove portion of the rod-shaped member from the terminal end to the starting end of the cylindrical member while rotating. In the linear body conveyance apparatus of any one of Claims 1-4,
At least one of the central shaft and the rod-shaped member of the tubular member is formed in a hollow shape with both ends closed, and the linear body transporting device is characterized in that

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