TW201022122A - Device and method for winding filament threads capable of preventing occurrence of bunch on the innermost and outermost layers - Google Patents

Abstract

The present invention provides a device and method for winding filament threads capable of preventing occurrence of bunch on the innermost and outermost layers. The filament thread winding device includes: a rotary cylinder, a plurality of bobbin holders, a transversely-movable roller part, a friction roller part, a movement guide part, a transfer tail formation part, a swing guide part, and a slot groove. The bobbin holders can be installed on the upper part and lower part of rotary cylinder, and the end portions on one side of the bobbin holders are formed with a transfer tail groove. The transversely-movable roller part is installed on the upper part of rotary cylinder at a position where the filament thread can be wound on the spool for a specified transversal width. The friction roller part comes into contact with the spool on the upper part of rotary cylinder and produces a pressure on the filament thread. The movement guide part is installed on a lateral part of the transversely-movable roller part so that the path of filament thread departs from the transversal position. The transfer tail formation part is installed on the upper portion of friction roller part, and guides the filament thread to a transfer tail groove of the spool when the filament thread is moving and severed. The swing guide part is installed on a lateral part of the friction roller part, and guides the path of filament thread to a side of the transfer tail groove of the spool when the filament thread is moving and severed. The slot groove is a groove formed on one side of the transfer tail groove facing the inner side thereof for severing the filament thread in the groove.

Description

201022122 VI. Description of the Invention: TECHNICAL FIELD OF THE INVENTION The present invention relates to a method for preventing the innermost. , wire winding device and method thereof, especially outermost pleating wire winding device and [prior art] Please refer to FIG. 1A and FIG. 1B, a schematic diagram of the m 1A upper wire winding device, and the graphic heart=known art The silk β is a schematic view of a bobbin in the case of a cake-like condition having the innermost and outermost layers. As shown in Fig. 1A, the wire winding device 1A includes a rotatable traverse roller portion 12G and a friction roller portion 13A.旋 h ; = V:) 廿, 112 ' of the bobbin 〇 > 可 旋转, and the traverse roller portion 120, located on the rotating drum 110, = and placed on the line. On the bobbin of , , 112, the wire is wound with a predetermined width. The friction roller portion 13G comes into contact with the upper bobbin and generates a pressure on the yarn γ. The state in which the wire is wound on the bobbin is also referred to as the wire winding device 100' is formed on the upper bobbin (1), and an empty load line sleeve 114 is formed on the lower bobbin, and the negative rotating drum 110 is at a predetermined angle. Rotate so that the full load spool (1), and 々 are interchanged. That is, as shown in Fig. 1A, by the rotation of the rotary drum 110, the load carrying bobbin 114 is located above the drum 110' of the rotating decay 201022122, and the full load spool 113 is located at the rotating drum 11〇. Further, in this state, the yarn γ is moved to the rotary drum 11A, and the upper empty load spool 114 can be cut off. In order to achieve the cut-off traverse roller portion 120, and the friction roller portion 130' must be rotated from the rotary drum 11,

The upper part is raised by a height, and then the lower full load spool 113 is stopped. At this time, the upper empty load bobbin 114 continues to rotate, and the helix yarn Y is moved to the upper empty load bobbin 114, and at the same time, between the full load line shaft 113' and the empty load bobbin 114, the cut can be made. Broken wire. / 'But this prior art wire winding device and the wire moving and cutting method using the same have the problem that a weft image is formed in the outermost difficulty of the full negative axis when the wire is broken. As shown in Fig. 1A, the winding phenomenon of the wire is concentrated on the outermost side of the full load bobbin, and the outer pleating SB phenomenon of the outermost layer is generated. ... the problem is that when the wire is moved and cut, the (four) wire at the full load line = 3 and the empty load spool 114' is not moved and cut immediately, but the wire is moved to the moving position and the cut position, and the spool 113, and the empty load line (4) 4, after a number of rotations, the opening and closing operations of the 妒 line and the 糸 line are performed. In particular, the outer pleat SB of the outermost layer of the egg field c of the soil is formed at the full load line, and must be manually removed by the person in the finished product shipment. Therefore, the productivity of the wire winding is poor. In addition, the rushing wire winding device and the method thereof have the following problem: that is, when the wire is moved and cut, the horizontal portion (10) and the j roller portion (four) are raised from the rotating drum 11 〇, and a new height is generated. Winding: 201022122 Therefore, the pleats are concentrated in the innermost layer of the empty load bobbin 114. That is, as shown in Fig. 1B, the wire winding occurs in the center of the cake-like c formed by the empty load bobbin 114, and the mb' middle bunch phenomenon occurs in the innermost layer. When the thread is moved and cut, the traverse portion 12 and the friction roller portion 130 are raised from the rotating drum 11A by a height. That is, the distance from the empty load bobbin 114 to the traverse roller portion 12A is relatively f, so that at the start of winding, the wire is concentratedly wound around the center portion of the bobbin. When the center crease phenomenon occurs in the inner shaft, the yarn is twisted when the yarn is unwound for the production of various blanks, and problems occur in subsequent processes such as dyeing, and the yarn is generated in the case where the influence is large. Cut off the problem. SUMMARY OF THE INVENTION In view of the above-mentioned problems of the prior art, one of the objects of the present invention is to provide a wire winding device capable of preventing the innermost and outermost layers from being pleated, and a second method 'when the wire is moved and cut, Through the relationship between the path and the line of the wire, the wire is moved and cut off quickly and correctly. == The completed full load spool can prevent the outermost layer from occurring. According to the other aspect of the present invention, the present invention proposes A wire winding device that prevents the innermost and outermost layers from being __ . ^ . The rubbing roller does not rise from the lower roller portion and is broken, thus preventing the start _, two

Gn>〇Ve). The swing guiding portion is provided at a side portion of the rubbing roller portion, and guides the path of the wire to the transfer tail groove side of the bobbin when the wire is moved and cut. The slot groove is one side of the transfer tail groove toward the inner side groove, and the wire can be cut in the groove. Further, the present invention further proposes a wire winding device which can prevent the innermost and outermost layers from being pleated, wherein the slit is pleated toward the inner side of the bobbin and the width is gradually increased from 201022122. The outer layer & the re-purpose, the purpose - to prevent the innermost and most spools; 1 dip:, coil: winding device and its method, through the wire path and (d. B ' system for wire cutting operation, Regardless of the wire tension or Danny characteristics, or the state of the transfer tail groove of the bobbin, the wire can be cut evenly. ^To achieve the above object, the present invention proposes a wire winding device capable of preventing the innermost and most 2 = Including - a rotating drum, a plurality of bobbin holders, a traversing roller portion, a friction roller portion, a moving guide portion, a transfer tail forming portion, a rib (five), and a guide groove. The bobbin holders are respectively rotatably disposed on the upper portion of the rotary drum = portion 'and the end portions on the bobbin side have a transfer tail groove. The moving roller portion is located at an upper portion of the rotating drum, and the traverse portion is disposed at a line where the upper 2 shaft is wound by a predetermined lateral width. The friction roller portion comes into contact with the upper bobbin of the rotary drum and generates a pressure on the wire. The moving guiding portion is disposed at a side portion of the horizontal pure portion, and the path of the wire is separated from the lateral position. The transfer tail forming portion is disposed at an upper portion of the frictional light portion, and guides the transfer tail groove of the wire to the bobbin when the wire is moved and cut ( Transfertaii 201022122 The smaller triangle. The word (4) is proposed to prevent the innermost and outermost pleating winding device, wherein the slot is a triangle with different lengths on both sides. In addition, the present invention further proposes Inner, most = T = f, wherein the moving guiding portion is disposed at a side of the rolling roller portion facing the rubbing roller, and is moved above the guiding portion"

The heart rotates the lower end of the moving guide portion clockwise at the two corners when the wire is moved and cut, so that the wire can be detached from a lateral position. Further, the present invention further proposes a wire winding device capable of preventing (4), the outermost layer, wherein the tail forming portion, the first roller, the first roller, the second roller, and the second cover; . The cover plate covers the friction roller portion. The first roller sets the cover plate in a horizontal direction, and the first guiding portion guides the wire from the lateral position to a transfer tail groove of the shaft, and the cover plate is slidably disposed while the first roller is mounted In a horizontal direction. In addition, the second roller is disposed in a vertical direction of the first guiding portion, and the second guiding portion returns the wire from the transfer tail groove of the bobbin to the original lateral position, and makes the first guiding while installing the second roller The portion is slidably disposed in a vertical direction. Further, the present invention further provides a wire winding device capable of preventing the innermost and outermost layers from being pleated, wherein the first guiding portion includes a guide plate and a plurality of guiding bars. The guide bar is located at the lower end of the guide plate and extends in the direction of the lower portion of the guide plate to guide the wire from a lateral position to the 201022122 transfer tail groove of the spool. Further, the present invention further provides a wire winding device which can prevent the innermost and outermost layers from being pleated, wherein the second guiding portion includes a guide plate and a plurality of guiding bars. A plurality of guide bars are located at the lower end of the guide plate and extend a length in the lower direction to return the wire from the transfer tail groove of the spool to a lateral position. Further, the present invention further provides a wire winding device which can prevent the innermost and outermost layers from being pleated, wherein the swing guiding portion includes a roller and a swing guiding member. The oscillating guiding member is mounted on the drum, rotates at an angle centering on the rotating shaft of the drum, and is placed at an empty load on the upper portion of the drum, and the lower end of the shaft is guided by the oscillating guiding member to guide the wire in the path in which it travels. And horizontal projections and horizontal grooves are formed in the horizontal direction on the side of the transfer tail groove. To guide the thread

'·—This 〇 至 原来 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 2010 The outermost layer does not have concentrated pleating.

(2) The wire can be cut while moving the wire without the traverse roller portion and the friction roller portion rising, so that the spool can be prevented from being concentrated at the innermost layer of the carrier shaft when starting the new winding. The case of pleating. (3) Further, the present invention cuts the yarn by the relationship between the thread path and the bobbin, and the yarn can be uniformly cut regardless of the characteristics of the thread tension or Danny or the state of the bobbin shifting the tail groove. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the invention is not limited to these embodiments. Referring to Fig. 2A, which is a schematic view of a wire cutting method of the wire winding device of the present invention, Fig. 2B is a schematic view of a cake shape in which the innermost layer and the outermost layer do not undergo concentrated pleating in the present invention. As shown in FIG. 2A, in the wire cutting method of the wire winding device 1 of the present invention, substantially no lifting from the upper empty load bobbin 114 to the traverse roller portion 120 and the friction roller portion 13 is as follows. The relationship between the path of the wire γ and the slot formed on the bobbin moves and cuts the wire Υ. As shown in Fig. 2β, the cake shape 201022122 formed on the empty load bobbin 114 does not cause a concentrated 彳f phenomenon in the center of the innermost inner layer. In addition, even if the outermost layer of the cake-like c formed on the full load bobbin does not concentrate, 2 = like, that is, the conventional technique generates separately at the outermost layer of the empty load bobbin 114 / the outermost layer of the load bobbin 113. The pleating phenomenon is concentrated, but the present invention does not cause pleating. Referring to Figure 3, there is shown a view of the wire winding device of the present invention. *, Φ, as shown in Fig. 3, the wire winding device 1 includes a rotatable rotating roller, 110, a traversing roller portion 120, a friction roller portion 130, a moving guide 邛14〇, and a transfer tail portion. A portion 15A and a swing guide portion 160. The rotary drum 11A is rotatably provided with the bobbins 111, 112 at the upper and lower portions thereof, respectively, and the traverse roller portion 12 is located above the rotary drum 11A, and the yarn γ having a predetermined lateral width is wound around the upper bobbin. The wiper 4130 is brought into contact with the upper bobbin of the rotary drum 11〇, and generates a pressure to the wire loop. The moving guide (10) guides the path of the wire turns away from the lateral position. The transfer tail forming portion 15() guides the wire into the transfer tail groove of the spool. The swing guide 16 turns the wire Y path to the transfer tail groove side of the spool. The rotary drum 110 is disposed on the frame 1〇1 of the wire winding device 1〇〇 and is spouted to the drive shaft of the motor (not shown) so as to be rotatable in a prescribed direction. That is, the rotating drum 110 can change the full load bobbin 113 and the empty load bobbin 114 by rotating about 18 degrees or 270 degrees when the bobbin inserted into the bobbins ni, m forms the full bobbin 113. position. Referring to _ 3, it can be seen that the full load spool 113 201022122 is at the lower portion and the empty load spool 114 is at the upper portion. The bobbin holders 111 and 112 have a certain length in the upper portion and the nip portion of the rotary drum 11A, and are engaged with the drive shafts of the respective motors (not shown in the drawings), so that they can be rotated in a predetermined direction. That is, by rotating the bobbins 111, 112 at a predetermined speed, the wires are wound around the bobbin mounted on the holder. Of course, a plurality of bobbins may be provided at intervals on such bobbin holders 111, 112.

The buy-out parent 120 is disposed on the upper portion of the rotary drum 110, and functions as the traverse roller 121 traverses the yarn to a predetermined width and supplies it to the spool. The rubbing roller portion 130 is disposed directly above the rotary drum 11A and has a rubbing roller 131. The friction roller portion 130 functions such that the friction roller i3j is in direct contact with the upper bobbin to supply a certain pressure to the yarn Y, thereby winding the yarn γ on the upper bobbin. The adjacent guide portion 140 is disposed on the traverse roller 2 facing the frictional light portion 130, and the upper end of the movement guide portion 140 is rotatably mounted at an angle of the traverse roller portion. The function is to remove the lower end from the lateral position by a sound operation 2 =: thread 丫 when the yarn Y is moved and cut. That is, the bobbin at the top of the 110 110 110 forms a full load bobbin 113 胄, : 2, turn: 180 degrees, so that the upper full load spool 113 is on the lower and the lower empty load spool 114 is on the upload The full load spool 113 of the line = 4 turns to the upper empty load spool U4, which will be the full load spool 113 and the empty load line.

Ο 201022122 System cut. In order to achieve the effect of the movement and cutting of the wire 2:: 5 = r two or a component such as a motor, the purpose of the f U wire γ is separated from the original lateral position. This == portion forming portion 150 and the urging guide portion (10) can collectively operate for the purpose of moving and cutting the wire γ. The transfer tail forming portion 15 is provided on the upper portion of the friction roller portion 130. However, the present invention does not have any limitation on the position at which the transfer tail forming portion 150 is disposed. The transfer tail forming portion 15(), by moving the guiding portion just moving the detached yarn Y from the lateral position to the transfer tail groove of the bobbin, can move the wire γ onto the upper empty load bobbin 114 to cut off the full load bobbin 113 and The wire γ between the empty load spools 114. The swing guiding portion 160 is provided on one side of the rubbing roller portion 13A. However, the invention does not impose any limitation on the position at which the swing guiding portion 16A is disposed. The swing guiding portion 160 functions to guide the path of the wire γ between the full load spool 113 and the empty load spool 114 to the transfer tail groove side of the empty load spool 114. The swing guiding portion 16A includes a drum 161, a rotating shaft 162, and a swing guiding member 163. The drum 161 is disposed on the frame 1〇1 of the wire winding device 100. The swing guiding member 163 is disposed on the drum 161 and rotated at an angle centering on the rotating shaft 162, and located at the lower end of the empty load bobbin 114, and guides the path of the yarn γ. Referring to Fig. 4', it is a front view of the transfer tail forming portion of the wire winding device of the present invention. 12 201022122 Referring to FIG. 4, the transfer tail forming portion 150 includes a cover plate 151, a first roller 152, a first guide portion 153, a second roller 155, and a second guide portion 156. The cover plate 151 has a shape that substantially covers the upper portion of the friction roller portion 130 in the wire winding device 1A. It is to be noted that the cover sheet 151 can also form other shapes unrelated to the rubbing roller portion 13A. The first roll 4 152 is disposed in the horizontal direction (longitudinal direction) of the cover sheet 151. The first roller 152 may be any one selected from the air cylinder, the oil cylinder, or the member having similar functions, and the kind thereof is not limited in the present invention. The first guide portion 153 is mounted on the first roller 152 while being slidably placed in the horizontal direction of the cover plate 151. For example, it may be provided as a rail structure in which a guide rail (not shown) is disposed in the horizontal direction of the cover panel 151. The first guide portion 153 is slidable on the guide rail. The first roller 152 is operable to slide the first guide portion 153 in the horizontal direction. The guide plate 154 is mounted on the first guide portion 153 and slidable to the horizontal guide rail. A plurality of guide bars 154a are located at the lower end of the guide plate 154 and extend a length in the lower direction of the guide plate 154 to guide the wire γ from the lateral position into the transfer tail groove of the spool. The second roller 155 is disposed in the vertical direction (width direction) of the first guiding portion ία. The first roller 155 is any one selected from the air cylinder, the oil cylinder, or a member having similar functions, and is not limited in its kind in the present invention. The second guiding portion 156 is mounted on the second roller 155 while being slidably disposed in the vertical direction of the first guiding portion 153. For example, 13 201022122 can be set as a long hole structure, and the fixing protrusion 158a can be formed at a predetermined distance on the first guiding portion 153, and the long hole 158b can be formed in the second guiding portion 156, and the long hole 158b can be embedded in the fixing protrusion 158a, and Guided in the vertical direction, the protrusion 158a is fixed. Further, the second guiding portion 156 is slidable in the vertical direction by the second roller 155, but is also slidable in the horizontal direction by the horizontal movement of the first guiding portion 153.

The guide plate 157 can be mounted on the long hole 158b of the second guide portion 156 by the fixing protrusion 158a. A plurality of guiding bars 157 & are located at the lower end of the guiding plate 157 and extend a length in the lower direction of the guiding plate 157 to return the wire Y from the transfer tail groove forming the bobbin to the lateral position

In the present invention, the first guide portion 152 has been described as an example of a guide rail structure. The long guide structure of the second guide portion 156 has been described as an example. However, the present invention is not limited to such a configuration. H is a long hole structure, and the second guiding portion 156 may also be 4. In addition, the n-conducting portion 152 and the second material portion 156 are also known in the prior art to have a configuration that enables movement in a horizontal and vertical direction. Please refer to Fig. 5 for the swinging of the winding device, which is a side view of the guiding portion in the present invention. The swinging guide 1 includes a barrel 161, a drop and a pleat plate 166. The drum 161 is provided. On the motor =!, but the present invention has such a setting position 4: = there are two exceptions: the roller 161 can be a member from the empty cylinder, _= von, which has similar functions, without any limitation on its kind. , arbitrary-species, in the present invention 201022122

One side of the swing guiding member 163 is mounted on the drum ι61, and the other side is mounted on the rotating shaft 162. When the drum 161 is operated, the rotating shaft 162 can be rotated at an angle. The swing guiding member 163 is rotated at an angle centered on the rotating shaft ι62 so that the empty load spool U4 located at the upper portion is switched to the position at the lower end to guide the path of the yarn γ. Next, a horizontal horizontal groove 165 is formed at the lower portion of the swing guiding member 163 to guide the wire γ at one end in the horizontal direction. That is, a horizontal projection 164 is formed at the lower portion of the swing guiding member 163 to guide the yarn γ to the maximum of the transfer tail groove near the bobbin. The horizontal projection 164 has a curved shape in the spool direction. A pleat plate 166 is attached to the oscillating guide member 163 to maintain a certain wire tension while guiding the wire path. The pleating plate '166 forms a vertical groove 168 in the vertical direction to guide the wire γ to one end in the straight direction of f. That is, a vertical 167' is formed in the lower portion of the pleated plate 160 to guide the wire to the maximum (four) to the transfer end groove of the #near axis. The well-defined protrusion has a curved shape in the direction of the bobbin. Please refer to the plan view of the figure. 6. It is the bobbin of the wire winding device of the present invention as shown in FIG. 6; "In the present embodiment, the empty load bobbin m is taken as an example, and the yarn Y is moved at one end of the four ends, so that the loop transfer tail can be cut. Further, in the transfer tail groove 114a, that is, the slit (10) is a groove toward the thin side of the line. :==: The width of the inner side toward the inner side of the bobbin gradually becomes smaller. For example, the lengths on both sides of the slot stroke are not the same triangles of 201022122 and are inclined downwards. Please refer to FIG. 7A to FIG. 7C, which are the movement and disconnection state of the wire on the bobbin in the wire winding device of the present invention. Fig. 7A depicts the empty load bobbin η 4 before winding. The wire γ is guided to the side of the transfer tail groove 114a of the empty load bobbin 114 by the moving guide 140, the transfer tail groove 150, and the swing guide 16〇. Next, the side of the slit 114b is formed. Next, in Fig. 7B, the state in which the wire is moved and cut on the empty load bobbin 114 is depicted, and Fig. 7C depicts the normal winding state of the wire γ. As shown in Fig. 7A, the wire γ is formed by moving the guiding portion 14 and transferring the tail portion Swing guide portion 150 and the like 16〇 operation, is guided to the empty bobbin minus $ 114 transfer tail groove 114 "is. Thereafter, the wire γ is automatically broken in the slot (10) while moving in the tail groove 114a. Therefore 'not the braking force through the empty load spool' 14

: From Cl? The slot (10) formed on the carrier wire (4) 4 cuts the wire = cut. Therefore, the tension of the yarn Y or the characteristics of the Danny is irrelevant, and the thread Υ can be cut at the position of the rule. Finally, as shown in FIG. 7C; the wire movement with a lateral width can be normally wound on the empty load bobbin. FIG. 8 is a wire of the wire winding device of the present invention, as shown in FIG. The wire winding device m includes a wire winding step S1, a rotating wire cutting step S3, and a wire returning step s =: turning to step S5. And wire winding step 201022122 Figs. 9A to 9E are views showing, in order, a method of moving a wire using the wire winding device of the present invention. At the same time, please refer to Figure 3 to Figure 8. Here, the center of the godet roller in Figs. 9A to 9E is indicated by GC, the first guiding portion is indicated by G1, the second guiding portion is indicated by G2, the moving bow guide is indicated by SG, and the center of the traverse roller is indicated by TC. The center of the friction roller portion is indicated by FC, and the relative position of the swing guide portion is indicated by SW, the transfer tail groove 113a of the full load spool 113, and the transfer tail groove 114a of the empty load spool 114. Further, ❹ indicated by the thicker lines in Figs. 9A to 9E are constituent elements in the current operation, and thinner lines indicate non-constituting elements in the current operation. Λ ' As shown in Fig. 9A, in the wire winding step S1, the wire 丫 is wound in a predetermined lateral width until it is mounted on the upper wire yoke (1)

The guide portion I56, the swing guide portion 160, and the friction roller portion 130 are actuated. The first guiding portion 153 and the second 160 of the 5150 are stopped to operate. Only the traverse roller portion 120 is as shown in Fig. 9B.

In the empty load spool S3, 17 201022122 2 γ between the swing load carrying shafts 114 can be maximally guided to the transfer tail ^#114& side near the empty load spool 114. Further, the upper portion of the empty load bobbin 114 can be moved by the & guide portion 14G and the transfer tail forming portion 15G so that the upper portion of the load bobbin 114 is disengaged from the lateral position, and the transfer tail groove of the wire loader bobbin 114 is moved. At ii4a. Here, the transfer portion 150 can be moved through the first guide portion 153 and the second guide portion groove 114a. The wire loop is guided to the transfer tail of the empty load spool U4. The wire Y is guided to the transfer tail of the empty load spool 114. The wire is cut: and the wire is taken from the slot U4b of the empty load spool 114. That is, in the present invention, unlike the conventional technique, the operation is stopped by the full 狨, '114, and the wire γ is cut by the braking force, and the wire is made (10) by the /114b. Noteable Ξ friction:: When the thread γ is moved and cut, the traversing roller unit 120 participates in the same technique f:: two' so that 邛140 is not generated in the innermost layer, and the tail can be transmitted through the tail Forming department

γ= and the second guiding portion 156 return to the original position U and "" 56:1 to the original lateral position. And it can be returned to the lateral position through the transfer tail groove 耵筇 green γ in the carrier shaft 114 in the second index. In the wire winding step S5, the wire γ having a predetermined lateral width is wound around the vacant load line. Therefore, in the 18 201022122 wire=winding step, the moving guide portion 14A, the first guiding portion i5, and the swinging guiding portion 16 can be returned to the original position. As described above, in the state where the wire material and the = portion are not raised, the simultaneous movement of the wire is = line: this does not occur in the prior art when the wire is moved and cut off < new start at the empty load spool A concentrated image is produced in the innermost layer at the time of winding. Further, the present invention is independent of the characteristics of the thread tension or Danny by the slit _::line of the slot of the present invention. This results in the most pleating of the outermost layer of the full load spool or the empty load spool. π王果甲 The above description is for illustrative purposes only and is not a limitation. Any changes or modifications that are made without departing from the spirit and scope of the invention are intended to be included in the scope of the appended claims. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1A is a schematic view of a wire winding device of the prior art; FIG. 1B is a schematic view of a spool having a pleated cake shape at the innermost and outermost layers; The present invention is a schematic view of a wire cutting method of the wire winding device of the present invention; FIG. 2B is a schematic view of a cake shape in which the innermost layer and the outermost layer are not concentrated and pleated in the present invention; A schematic view of a wire winding device; 201022122 is a front view of a transfer tail forming portion of the wire winding device of the present invention; and FIG. 5 is a side view of the swing guiding portion of the wire winding device of the present invention, 6 is a plan view of a bobbin of the wire winding device of the present invention; FIGS. 7A to 7C are plan views sequentially showing movement and cutting of the wire on the bobbin in the wire winding device of the present invention, 8th The figure is a flowchart of the method of moving the wire of the wire winding device of the present invention; and Figs. 9A to 9E are schematic views sequentially showing the method of moving the wire using the wire winding device of the present invention. [Description of main component symbols] 100, 100': wire winding device; 101: frame; 110, 110': rotating drum; 111, 111', 112, 112': bobbin; 113, 113': full load bobbin; 113a: transfer tail groove; 113b: slot; 114, 114': empty load spool; 114a: transfer tail groove; 114b: slot; 20 201022122 120, 120': traverse roller; 121: traverse roller; 130': friction roller portion; 131: friction roller; 140: moving guide portion; 150: transfer tail forming portion; 151: cover plate; 152: first roller; 153, G1: first guide portion; 154: guide plate 154a: guiding rod; 155: second roller; 156, G2: second guiding portion; 157: guiding plate; 157a: guiding rod; 158a: fixing protrusion; 158b: long hole; 160: swinging guide portion; 162: rotating shaft; 163: swing guiding member; 164: horizontal protrusion; 165 · horizontal groove; 166: pleating plate; 167: vertical protrusion; 21 201022122 168: vertical groove; BH: bobbin; C: cake Shape; FC: center of friction roller; * GC: center of godet; MB: Part pleating; 51: wire winding step; 52: rotating step of rotating drum; _S3: thread cutting step; 54: thread returning step; 55: thread winding step; SB: outer pleating; SG: moving guide Department; SW: relative position of the swinging guide; TC: center of the traverse roller; and Y: thread. twenty two

Claims (1)

201022122 VII. Patent application scope: L kinds of wire winding device which can prevent the innermost and outermost pleating, 1 includes: 〃 a rotating drum; complex, bobbin bobbin 'set on the upper part of the rotating drum and part I And the end of one side of the bobbin has a transfer tail 僧; two traversing (four)' is located at an upper portion of the rotating drum, and the traverse sigh is placed at a thread of the upper bobbin winding a predetermined lateral width; The two friction roller portions are in contact with the upper bobbin of the rotary drum, and generate a pressure on the wire; the movable guiding portion is disposed on a side portion of the traverse roller portion to disengage the path of the ridge line a lateral position; the 形成 portion forming portion is disposed at an upper portion of the friction roller portion, and when the movement and the cutting are performed, a wire that guides the wire to the spool is disposed at a side of the friction roller portion, and the transfer tail portion 2 Leading to the bobbin by the road (4) of the dip:: the side of the trough is facing inward, 2. The innermost and outermost layers 23 can be prevented as described in item i of the patent application. 201022122 The slot is oriented toward the bobbin Inside 3. If Shen The innermost and outermost layer = wire: winding device can be prevented as described in the first item of the patent scope, wherein the slot is a double-sided shape having mutually different lengths on both sides. 4. ^ Affirmation of Patent Fanyuan! The wire winding device capable of preventing the innermost, outermost layer, pleats, wherein the moving material portion is disposed at a side of the traverse roller portion of the friction roller portion, and the moving end portion is For a center, the lower end of the moving guide is rotated clockwise at an angle of 2 when moving and cutting, so that the thread can be detached from a lateral position. 5. The wire winding device of claim 1, wherein the transfer tail forming portion comprises: a cover plate covering the friction roller portion; a roller, the cover plate is disposed in a horizontal direction; a first guiding portion guides the wire from a lateral position to a transfer tail groove of a spool, and the cover plate is Slidably disposed in a horizontal direction; a second roller disposed in a vertical direction of the first guiding portion; and a second guiding portion for returning the wire from the transfer tail groove of the spool to an original lateral position And when the second roller is mounted with the same 24 201022122, the first material portion is slidably disposed in the vertical direction. = Patent Application _ Item 5 for preventing the innermost and outermost layer of the wire winding I, wherein the first material portion comprises: a guiding plate; and a plurality of guiding bars are located on the guiding plate The lower end extends a length in the lower direction of the guide plate to guide the wire from a lateral position to the transfer tail groove of the spool. 7. The wire winding device capable of preventing innermost and outermost pleating as described in claim 5, wherein the second guiding portion comprises a guide plate; and a plurality of guiding bars are located at the guiding The lower end of the plate extends a length in the lower direction to return the wire from the transfer tail groove of the spool to a lateral position. 8. The wire winding device capable of preventing innermost and outermost pleating according to claim 1, wherein the swing guiding portion comprises: a roller; and a swing guiding member mounted on the roller to The % of the shaft of the drum rotates at an angle centered on the lower end of one of the upper load spools of the drum, and the swing guiding member guides the wire on the path in which it travels. And in the horizontal direction on the side of the transfer tail groove, horizontal projections and horizontal recesses are formed in the manner of guiding the wires. 9, a method for preventing the inner and outermost pleating of the wire winding, package 25 201022122 includes the following step lines ί turn ff - the upper and lower parts of the tube are respectively set - (d) ϋ / line for winding until the setting name / load a state of the bobbin; when the bobbin of the line having the upper portion of the slot is formed as a full load bobbin, the /loading bobbin is moved to the lower portion, and the lower empty load bobbin is moved to the upper portion; Disengaging the wire between the lower full load bobbin and the upper empty load bobbin from the lateral position and guiding to the transfer tail groove of the empty load bobbin, the wire moving and cutting operation is performed by the slot And returning the wire above the empty load spool to the original lateral position. 26